Abstract:
The present invention relates to endosseous implants and in particular, to screw form dental implants for implanting within bone. The bone implant is configured to be a self-drilling bone implant that is adept at condensing, collecting and distributing bone along all of the implant&#39;s surface and within the implantation site, to significantly increase the bone implant contact surface. The implant is configured to have a coronal portion and a body portion that are continuous with one another. The coronal portion is configured to have a smaller overall diameter than the overall diameter of said body portion. The body portion is fit with threading that facilitates the self-drilling and bone collection properties when the implant is rotates in both the clockwise and counterclockwise directions.

Description:
FIELD OF THE INVENTION 
       [0001]    The present invention relates to endosseous implants and in particular, to screw form dental implants for implanting within bone. 
       BACKGROUND OF THE INVENTION 
       [0002]    A dental implants are provided to replace lost teeth in the oral cavity. Dental implant include various parts that come together to form a structure that replaces a tooth providing both esthetic and functional purposes. 
         [0003]    The dental implant generally includes a crown to replace the crown portion of the lost tooth, an implant in place of lost tooth root, where the crown and implant are coupled with one another with an implant abutment. All three parts function together to bring about a successful implant procedure. The implant provides the primary base and support structure of the implant and is therefore a central element to the success of the dental implant. 
         [0004]    The dental implant is generally provided as a screw-form device that generally includes a head portion and body portion. The head portion defines the coronal segment of the implant that is provided for facilitating tooling and coupling with other implant structures such as an abutment and crown. The body portion defined the apical segment of the implant that is provided for integrating with the bone allowing for osseointegration. 
         [0005]    The implant body portion has various designs that are designed according to many parameters including the bone type to be implanted, the location in which the implantation is to occur, (implantation site). The body portion includes threading along its length that are used to securely introduce the implant into the bone and allow for the implant to integration with the bone. 
         [0006]    Despite the advancement in implant design there is a continuing need to improve a dental implant&#39;s ability to osseointegrate that in turn will lead to improved implant stability and longevity. 
       SUMMARY OF THE INVENTION 
       [0007]    The present invention relates to endosseous implants and in particular, to screw form dental implants for implanting within bone. 
         [0008]    Embodiments of the present invention provide a self-drilling dental implant that is configured to facilitate insertion and osseointegration by condensing, collecting, and distributing bone along all surfaces of the implant. Preferably collection and distribution is provided when the implant is rotated in either the clockwise or counterclockwise directions. Aspects of the present invention may be implemented so as to allow reconfiguration of the implant on all forms of a dental implant in any region of the maxilla and mandible. 
         [0009]    Optionally the dental implant of the present invention may be configured to be a molar dental implant replacing teeth in the molar region of the maxilla and/or mandible. 
         [0010]    The dental implant according to embodiments of the present invention is a self-drilling, self-tapping, self-collection bone and bone condensing. The implant according to embodiments of the present invention may be utilized at a heal site following bone growth or it may be utilized at an extraction site. 
         [0011]    Most preferably an implant according to the present invention is configured to collect and/or distribute bone along all of its surfaces therein increasing the bone implant contact (‘BIC’) improving the process of osseointegration. 
         [0012]    Preferably embodiments of the present invention provides for cutting, mixing, and directing bone within an implantation site. 
         [0013]    Preferably the implant according to the present invention may be utilized as a self-drilling implant to facilitate implantation within an extraction site socket and/or a cavity within bone structure, or a heal side extraction site. 
         [0014]    Optionally and preferably introducing the implant into an extraction site socket allows a practitioner to optimally maintain the Laminal Dura at the extraction site while simultaneously allowing the implant to engage and/or integrate with at least apportion of the Laminar Dura. Such optimal maintenance of the Laminar Dura significantly improves the overall healing period. 
         [0015]    Preferably the implant according to optional embodiments of the present invention provides an implant that functions as an instrument for distributing bone in all directions first by accumulating bone along the implant&#39;s surface. Similarly bone matter may be directed into different locations within an implantation site by way of maneuvering the implant in the clockwise and/or counterclockwise direction. Such implant maneuvering provides for direction bone in the upper (coronal) or lower (apical) portions of the implant. 
         [0016]    Embodiments of the present invention further provide for introducing bone matter and/or graft materials through the coronal opening of the flutes into the implantation site, either before and/or after integrating the implant within the mandible or maxilla. 
         [0017]    Embodiments of the present invention provide a dental implant that facilitates collecting any bone the implantation site from at least one of the extraction site septum, bone graft materials. 
         [0018]    Embodiments of the present invention provide an implant that is self-drilling therein capable of expanding the bone at the implantation site optionally to create more space for receiving bone in and around the implant, therein improving the osseointegration and the formation of an initial matrix created for bone osseointegration. 
         [0019]    Embodiments of the present invention provide a coronal portion having a smaller overall diameter that facilitates receiving more bone in and around the coronal portion. 
         [0020]    Preferably the configuration of the coronal portion having a smaller overall diameter than the body portion provide for pressure equalization, wherein the pressure on the implant may be evenly distributed along the length of the implant at the implantation site. This is a function of the fact that the coronal portion associates with cortical compact and/or dense bone while the body portion of the implant associate with less dense spongious bone. Accordingly having a smaller coronal portion and a wider body portion according to optional embodiment of the present invention provides for balancing the pressure along the length of the implant after implantation. Such pressure equalization delay, reduced and/or may prevent bone resorption due to imbalanced pressure distribution on the implant. The pressure equalization allows the implant to control and/or adjust the fixation torque as a function of the implant thread that is configured to facilitate cutting, tapping and collect bone when maneuvered in both the clockwise and counterclockwise directions. Optional embodiments allow both the body portion threads and coronal portion threads to be cutting thread allows for controlling the pressure along the length of the implant and bone material may be maneuvered around any portion of the implant. 
         [0021]    Embodiments of the present invention provide a coronal portion that comprises a plurality of at least three or four dental implant prosthetic connection platforms. 
         [0022]    Embodiments of the present invention provide a self-drilling implant that may facilitate change direction of the implantation during implantation. Such directional control of the implant as a result of the self-drilling threads provides a practitioner with the freedom to maneuver the implant within the bone as is called for according to the clinical situation at hand. Specifically a practitioner may utilize the implant according to the present invention to expand the bone in the buccal direction and therefore may position the implant in a clinically ideal position. Such directional control provides for controlling the implant&#39;s insertion angle and/or direction. 
         [0023]    Embodiments of the present invention and in particular control maneuvering and movement of bone within an implantation site by virtue of the ability of the implant to cut and distribute bone during rotation in both clockwise and counterclockwise direction, further allows a clinician to facilitate a sinus lifting procedure. Preferably maneuvering (rotating) the implant as needed so as to distribute and condense bone toward the apical end allows to facilitate bone growth in and around the implant apex. 
         [0024]    Optionally the implant according to optional embodiments may be utilized to break the sinus floor to allow for bone introducing bone into the apex to facilitate sinus lifting bone formation. 
         [0025]    Embodiment of the present invention provides a dental implant comprising a coronal portion and a body portion, where the overall diameter of the coronal portion is smaller than the overall diameter of the body portion. The implant is characterized in that the coronal portion provides the implant with at least three connection platforms. Most preferably the coronal portion may be composed from three substantially cylindrical segments and/or circular-cylindrical segments that are continuous with one another. 
         [0026]    Optionally at least one coronal portion segment may comprise a trapezoidal cross-sectional profile. Optionally and preferably each of three segments comprises a trapezoidal cross sectional profile. 
         [0027]    Optionally at least one coronal portion segment may comprise a circular cylindrical cross-sectional profile. 
         [0028]    Embodiments of the present invention provide a dental implant comprising a coronal portion and a body portion, where the overall diameter of the coronal portion is smaller than the overall diameter of the body portion, wherein the implant is characterized in that the coronal portion may be configured to be facilitate removable and/or excised from the implant body. 
         [0029]    Optionally the coronal section may be configured to be removable following implant placement. Optionally the coronal section may be configured to be removable following implant placement following bone resorption. 
         [0030]    Optionally the coronal section may be configured along at least a distal portion thereof to facilitate removal of the coronal segment. 
         [0031]    Embodiments of the present invention provide a dedicated tool provided for filing and or removing a coronal segment of a dental implant, the device featuring: 
         [0032]    a dental tooling connection interface for coupling with a dental hand piece tool; 
         [0033]    a discoid tooling surface having at least one surface and/or edge that may be coated with a corrosive medium that is provided for cutting and/or filing at least a portion of the coronal segment of a dental implant; 
         [0034]    an implant interface portion provided for inserting into a dental implant&#39;s central borehole, the interface portion including: a central body portion for fitting within an implant&#39;s central borehole recess; a ring portion provided for allowing said tool to freely rotate while associated with said implant borehole; a distal end cap for securely associating the tool with at least a portion of borehole portion and for sealing said implant borehole. 
         [0035]    Embodiments of the present invention provide a dedicated tool provided for filing and/or facilitating the removal of a coronal segment of an implanted dental implant, the device featuring: 
         [0036]    a dental tooling connection interface for coupling with a dental hand piece tool; 
         [0037]    a cylindrical tooling body functionally coupled with the dental tooling interface and configured to rotate when activated with said dental hand piece tool; said cylindrical tooling body having at least one tooling surface and/or edge that is coated with a medium provided for cutting and/or filing at least a portion of the coronal portion of a dental implant; and 
         [0038]    a tooling stopping interface portion provided for limiting the progressing of the cylindrical body along the coronal segment of the implant. 
         [0039]    Embodiments of the present invention provide a method for treating bone resorption of an implanted dental implant following dental implantation the method comprising: exposing, cleaning and isolating an implanted implant&#39;s coronal segment; associating a coronal removal tool according to optional embodiments of the preset invention; filing the coronal segment of implant to desired level relative to the bone surface; and coupling a new implant abutment with the dental implant. 
         [0040]    Optionally the new implant abutment may be coupled to the implant with a fixation screw. 
         [0041]    Embodiments of the present invention provide a method for treating bone resorption following dental implantation the method including: exposing, cleaning and isolating the an implanted implant&#39;s coronal segment along the coronal segment&#39;s external surface, wherein the external surface is configured and/or primed to be coupled with an abutment. 
         [0042]    Optionally the coronal segment&#39;s external surface is threaded to match threading disposed along a surface of an abutment. Optionally is the abutment may be configured to be placed over and/or coupled along the coronal segment having external threading, wherein the abutment is configured to have threading corresponding to the coronal segment&#39;s threading. 
         [0043]    Optionally the abutment may be associated with the external surface of the coronal segment wherein the abutment is coupled with the implant utilizing a fixation screw. 
         [0044]    Optionally following exposure of the coronal portion the coronal portion may undergo a treatment to facilitate coupling between an abutment and the treated coronal portion. 
         [0045]    Optionally the coronal portion may undergo rethreading the external surface of the coronal section. 
         [0046]    Optionally the external surface of the coronal portion may be resurfaced with a dedicated tool to facilitate receiving and/or coupling with an abutment. 
         [0047]    Embodiments of the present invention provide a bone implant anchor comprising a coronal portion and a body portion that are continuous with one another, the coronal portion defining the proximal end of the implant anchor and the body portion defining the distal end of the implant anchor, the body portion having an inner core fit with threading extending therefrom along its length; the inner core defining an internal diameter of the body portion and said threading defining the external diameter of the body portion, the coronal portion characterized in that it features at least one or more recessed grooves along its external surface. Preferably the recessed grooves are provided for facilitating bone integration. 
         [0048]    Optionally the external segment of the coronal portion may be feature threading configured for engaging and/or coupling with an abutment. 
         [0049]    Embodiments of the present invention provide a bone implant anchor comprising a coronal portion and a body portion that are continuous with one another, the coronal portion defining the proximal end of the implant anchor and the body portion defining the distal end of the implant anchor, the body portion having an inner core fit with threading extending therefrom along its length; the inner core defining an internal diameter of the body portion and the threading defining the external diameter of the body portion, the coronal portion characterized in that it features functional cutting threads disposed along the coronal portion&#39;s external surface that is provided for cutting into cortical bone. Optionally coronal portion threading is configured for cutting, condensing, collecting, distributing bone along the external surface of the coronal portion. 
         [0050]    Optionally the control portion threading may be configured to cut, condense, collecting, distribute bone along the external surface of the coronal portion, wherein the implant is rotated in at least one of the clockwise and/or counter clockwise directions. Optionally the implant coronal segment may be configured to cut, condense, collect, distribute bone when rotated in both the clockwise and counterclockwise directions. 
         [0051]    Embodiment of the present invention provides a dental implant comprising a coronal portion and a body portion, where the overall diameter of the coronal portion is smaller than the overall diameter of the body portion. The implant characterized in that the body portion comprises a core having threading extended therefrom, the threading defining the external diameter of the body portion and the core defining the internal diameter of the body portion. Most preferably the core comprises at least two or more substantially cylindrical segments and/or circular cylindrical segments that are fluid with one another. 
         [0052]    Optionally the core may comprise a plurality of substantially cylindrical sub-segments that are fluid with one another. 
         [0053]    Optionally individual sub-segments defining the implant core may assume a cylindrical profiles or a trapezoidal profile. 
         [0054]    Optionally the core may comprise a plurality of substantially circular cylindrical sub-segments that are fluid with one another. 
         [0055]    Embodiment of the present invention provides a dental implant comprising a coronal portion and a body portion, where the overall diameter of the coronal portion is smaller than the overall diameter of the body portion. The implant characterized in that the body portion comprises threading along its length and at least two flutes spanning the full length of the body portion. 
         [0056]    Optionally and preferably the flutes are configured to have a proximal opening that is adjacent to the coronal portion of the implant. Most preferably the flutes may be disposed along the length of the threading extending from the core of the body portion. The flutes therefore divide the thread into at least thread sub-segments having a blade and/or wing like configuration. 
         [0057]    Preferably the flutes comprise an ovoid configuration adjacent the body core and a neck adjacent the threading lateral edge and/or thread face. Optionally and preferably the ovoid configuration provides collecting bone fragments while the neck portion provides at least two cutting beveled edges. Preferably the flutes are configured so as to allow collecting and cutting of bone when the implant is rotated in either the clockwise or counterclockwise directions. 
         [0058]    Optionally and preferably the flutes of the present invention may provide and facilitate osseointegration as the flutes provide for at least one or more selected from the group consisting of collecting bone, compacting bone, introducing bone, removing excess bone, the like or any combination thereof. 
         [0059]    Most preferably the flutes and threading combine to facilitate implant insertion and integration by way of cutting, collecting, condensing and distributing bone along the implant&#39;s surface, for example including but not limited to within the flute recess, along the threading, between threading, or the like. Most preferably the flutes provide for increasing stability of the implant at the implantation site by increasing the Bone Implant Contact (‘BIC’) and therein providing a matrix that facilitates osseointegration. 
         [0060]    Embodiment of the present invention provide an implant abutment having: a proximal end for interfacing with a restorative structure; a distal end for interfacing with an implant; and a medial portion disposed there between; wherein the medial portion includes at least one connection platform coupling surface that is adapted for interfacing with at least one connection platform of an implant&#39;s coronal segment. The connection platform surface selected from the group for example including but not limited to: a surface having an angle of about 3 degrees and up to about 50 degrees; 
         [0000]    a surface having an angle up to about 70 degrees relative to a surface extending substantially perpendicular to the central axis of the abutment core; a surface that is substantially perpendicular to the central axis of the abutment core;
 
a surface that is fit with threading so as to allow coupling with the coronal segment by way of threading that corresponds to threading disposed along the external surface of an implant&#39;s coronal segment; and any combination thereof.
 
         [0061]    Embodiment of the present invention provide a bone implant anchor comprising a coronal portion and a body portion that are continuous with one another, the coronal portion defining the proximal end of the implant anchor and the body portion defining the distal end of the implant anchor, the body portion having an inner core fit with at least one threading extending therefrom along its length; the inner core defining an internal diameter of the body portion and the at least one threading defining the external diameter of the body portion; the threading defining a defined along the horizontal plane of the implant, the threading horizontal plane having a first axis along medial-lateral axis between along the length of thread and a second axis along the anterior posterior axis that extends around the implant core, the thread comprising: an apical side, a coronal side, and a lateral edge connecting the apical side and the coronal side, a base connecting the thread to the core, a thread depth defined between the lateral edge and the base along the (along the medial-lateral axis); wherein adjacent threads defined between adjacent thread base are connected over the external surface of the implant core defining an inter-thread face; the at least one or more threading characterized in that at least one of the thread apical side surface, the thread coronal side surface or lateral edge is fit with at least one contour modification along the horizontal plane therein defining at least two sub-segments along the horizontal plane along at least one of the medial-lateral axis or the anterior-posterior axis. 
         [0062]    Optionally the thread may further comprise at least one or more contour modifications simultaneously along both axis of the horizontal plane. 
         [0063]    Optionally the contour modifications may be symmetric about the horizontal plane. 
         [0064]    Optionally the contour modifications may be asymmetric about the horizontal plane. 
         [0065]    Optionally the threading may be fit with a plurality of recessed grooves. Optionally the threading may be fit with a plurality of extension. 
         [0066]    Embodiments of the present invention provide a dental implant having an internal connection platform borehole that is configured to receive a universal implant abutment. The internal connection platform is a borehole that extends from the proximal end of the implant borehole into the medial portion of the implant body. The internal connection platform is preferably centered along the implant diameter core. The implant connection platform comprises a distal portion, a medial portion and a proximal portion that are fluid and continuous with one another, wherein the connection platform is characterized in that the proximal portion comprises a universal conical profile. 
         [0067]    Most preferably connection platform is further characterized in that it comprises at least two anti-rotational interfaces a first anti-rotational interface disposed along the medial portion and a second anti-rotational interface disposed along the proximal portion adjacent to the implant&#39;s proximal end. 
         [0068]    Preferably the distal portion is a substantially cylindrical borehole featuring threading that is provided for coupling with a fixation screw as is known in the art. 
         [0069]    Preferably the medial portion defines an anti-rotation interface in the form of an anti-rotation tooling interface that is provided for manipulating the implant with tools. Optionally medial portion anti-rotation connection interface may be provided in any anti-rotation tooling interface as is known in the art for example including but not limited to at least one or more selected from the group consisting of internal six receptor sockets, scalloped, internal dodecagon, external dodecagon, internal hex internal, external hex, external octagon, internal octagon, external spline, internal spline, Morse taper, internal Morse taper, one piece, internal six lobe, external six lobe, internal tri lobe, external tri-lobe, internal six spline, external six-spline, internal thread, internal pentagon, external pentagon, external thread, internal square, external square, internal five lobe, internal four lobe, internal three spline, external triangle, internal eight spline, external six lobe, internal eight lobe, internal tube to tube plug in, triangular, polygonal of n sides where n&gt;=3 or more, the like as is known in the art or any combination thereof. 
         [0070]    Most preferably the proximal portion is provided in the form of a substantially conical borehole having a its small diameter at its distal end bordering the medial portion and a large diameter at the proximal end defined at the implants proximal end. 
         [0071]    Optionally and preferably the conical borehole defines a wall that is provided with a uniform angle and/or slope along the length of the proximal portion from the distal end to the proximal end. 
         [0072]    Optionally the conical borehole may define a wall that is provided with at least two angles and/or slopes along the length of the proximal portion from the distal end to the proximal end, therein defining two proximal portion conical sub-segments that are continuous and fluid with one another. Preferably the first sub-segment is provided with a first angle and/or slope and the second sub-segment is provided with a second angle and/or slope characterized in that the second angle and/slope is bigger than the first angle and/or slope relative to a common midline plane. 
         [0073]    Most preferably the proximal portion is fit with a second anti-rotation interface adjacent to the proximal end of proximal portion. Most preferably the second anti-rotation interface is provided along the conical borehole surface and/or wall. Preferably the second anti-rotation interface maintains the overall conical surface of the proximal portion. Most preferably the second anti-rotation interface is provided in the form of a plurality of recesses dispersed along proximal portion wall adjacent to the proximal end. Optionally the recess may be configured to be horizontal or longitudinal along conical surface wall. Optionally and preferably the second anti-rotation interface may be provided in the form of a plurality of interdigitating recesses dispersed along the conical borehole surface and/or wall. 
         [0074]    Optionally the second anti-rotation interface may be provided with at least two or more inter-digitation recesses, 
         [0075]    Optionally the internal connection platform borehole may further feature a circumferential recess and/or groove along at least one of the medial portion and/or the proximal portion. 
         [0076]    Optionally proximal portion may be fit with a circumferential recess and/or groove along distal end that is adjacent to and/or bordering with the distal portion. Optionally the circumferential recess may be configured to receive an O-ring for facilitating sealing and/or secure coupling with optional dental structures for example including but not limited to abutments, healing caps, impression coping abutment, measuring abutments, tools or the like. 
         [0077]    Optionally medial portion may be fit with a circumferential recess and/or groove along its distal end that is adjacent to and/or bordering with the distal portion. Optionally the circumferential recess may be configured to receive an O-ring for facilitating sealing and/or secure coupling with optional dental structures for example including but not limited to abutments, healing caps, impression coping abutment, measuring abutments, tools or the like. 
         [0078]    Optionally medial portion may be fit with at least one or more recess and/or groove along its distal end that is adjacent to and/or bordering with the distal portion. 
         [0079]    Embodiments of the present invention provide a dental implant abutment having an implant interface segment and a crown interface segment. The abutment characterized in that the implant interface segment is configured to be a universal abutment interface capable of fitting a plurality of dental implant of various diameters and/or sizes. The abutment is further characterized in the implant interface segment comprises at least one anti-rotational connections a first anti-rotational connection disposed along the distal part of the implant interface segment. 
         [0080]    The abutment&#39;s implant interface segment includes a distal portion and a proximal portion, the distal portion provided in the form of an anti-rotational interface provided for matching the implant&#39;s anti-rotational interface. 
         [0081]    Optionally the abutment may comprise at least two anti-rotational connection platforms a first anti-rotational connection platform disposed along the distal portion of the implant interface segment and a second anti-rotational connection platform disposed along the proximal portion of the implant interface segment. Optionally at least one of the two anti-rotational connection platforms may be provided in the form of inter-digitation connectors. Optionally both of the two anti-rotational connection platforms may be provided in the form of inter-digitation connectors. 
         [0082]    Optionally the distal portion&#39;s anti-rotational interface may be fit with a snap fit male connector for example including but not limited to a cog and/or flange and/or extension, the like or any combination thereof. Most preferably the snap fit male connector is provided to fit and securely couple with a corresponding female connector and/or recess disposed along an implant connection platform. 
         [0083]    The abutment characterized in that the proximal portion of the abutment&#39;s implant interface segment features an external surface having conical profile that is widest at its proximal end adjacent and/or bordering with the abutment&#39;s crown interface segment, and configured to be narrowest adjacent to and/or bordering with the distal portion of the abutment&#39;s implant interface segment. 
         [0084]    Optionally and preferably the proximal portion&#39;s conical external surface defines a wall that is provided with a uniform angle and/or slope along the length of the abutment&#39;s implant interface segment&#39;s proximal portion. 
         [0085]    Optionally proximal portion&#39;s conical external surface defines a wall that is provided with at least two angles and/or slopes along the length of the proximal portion, therein defining two proximal portion sub-segments that are conical and continuous with one another. Preferably the first sub-segment is provided with a first angle and/or slope and the second segment is provided with a second angle and/or slope characterized in that the second angle and/slope is bigger than the first angle and/or slope relative to a common midline plane. 
         [0086]    Optionally the abutment comprises a central borehole configured to receive a fixation screw, as is known in the art. 
         [0087]    Optionally the abutment may feature an integrated fixation screw portion disposed distal to the implant interface segment. Preferably the integrated fixation screw portion is provided for coupling with an implant along its threaded borehole. 
         [0088]    Embodiments of the present invention provide a dedicated dental tool for associated with and manipulating and/or tooling and/or maneuvering a dental implant according to embodiments of the present, the device featuring: a dental tooling connection interface for coupling with a dental hand piece tool that may be utilized to rotate a dental implant associated with the tool; a tooling body comprising a proximal portion, medial portion and a distal portion, the proximal portion is disposed distal to and is continuous with the tooling connection, the proximal portion defines a conical body having a proximal end and a distal end the proximal end configured to be wider than the distal end; the medial portion is disposed distal to the proximal portion and is fluid therewith, the medial portion is provided in the form of an anti-rotation interface for example including but not limited to a hexagon profile; the distal portion is disposed distal to the medial portion and is fluid therewith, preferably the distal portion is configured to have a body configured to have a smaller diameter than that of the medial portion so as to allow for entering into the dental implant borehole. 
         [0089]    Optionally the medial portion is substantially cylindrical. 
         [0090]    Optionally the dental implant insertion tool may be configured to have a hollow flow channel along its length so as to facilitate fluid flow therethrough for example for conducting a flowing fluid such as a fluid and/or gas. For example, the hollow flow channel may be utilized to couple with a suction port to facilitate creating of suction at the distal end. For example the hollow flow channel may be utilized for introducing a flowing fluid such as water and/or saline and/or gas and/or air through the distal end. 
         [0091]    The conical body featuring a plurality of inter-digitation male connects disposed adjacent to the proximal end. Most preferably the conical body comprises at least two inter-digitation male connectors extending form the external surface that are provided for associating with corresponding female inter-digitation connectors disposed on an implant internal connection interface as previously described. Preferably the plurality of male inter-digitation connectors may be distributed evenly along the external surface of the conical body. Optionally the proximal portion comprises from two and up to about six inter-digitation male connectors. 
         [0092]    Optionally the proximal portion may be provided from at least two or more conical sub-segments that are continuous and fluid with one another. Preferably each conical sub-segment forming the proximal portion are arranged such that the proximal portion maintains a substantially conical profile arrangement that is increasing diameter in the proximal direction, therein the distal sub-segment is the narrowest while the proximal sub-segment is the widest. Preferably a first (distal) sub-segment is provided with a first angle and/or slope and the second (proximal) sub-segment is provided with a second angle and/or slope characterized in that the second angle and/slope is larger than the first angle and/or slope relative to a common midline plane. 
         [0093]    Optionally medial portion may be configured to have any anti-rotational configuration to match that distal anti-rotational platform of a dental implant for example including but not limited to at least one or more selected from the group consisting of internal six receptor sockets, scalloped, internal dodecagon, external dodecagon, internal hex internal, external hex, external octagon, internal octagon, external spline, internal spline, Morse taper, internal Morse taper, one piece, internal six lobe, external six lobe, internal tri lobe, external tri-lobe, internal six spline, external six-spline, internal thread, internal pentagon, external pentagon, external thread, internal square, external square, internal five lobe, internal four lobe, internal three spline, external triangle, internal eight spline, external six lobe, internal eight lobe, internal tube to tube plug in, triangular, polygonal of n sides where n&gt;=3 or more, the like as is known in the art or any combination thereof. 
         [0094]    Within the context of this application the term thread, threading or “threading portion” refers to a portion of an implant comprising threading and utilized for integrating and/or interfacing and/or securely coupling the implant structure within the bone facilitating implantation within the bone. 
         [0095]    Within the context of this application the term “flute” may be interchangeable with any of the terms including but not limited to vents, grooves, recess or the like terms according to the art to refer to a portion of an implant provided with a cutting edge for tapping function, gathering function or the like. 
         [0096]    Within the context of this application the term “proximal” generally refers to the side or end of an elongated medical device such as an implant that is intended to be closer to the performing medical personnel and/or practitioner. The term “proximal” may be interchangeable with the term “coronal” when referring to the coronal side of an implant. 
         [0097]    Within the context of this application the term “distal” generally refers to the side or end of an elongated medical device such as an implant that is opposite the “proximal end”, and is farther from the performing medical personnel and/or practitioner. The term “distal” may be interchangeable with the term “apical” when referring to the apical side of an implant. 
         [0098]    Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The materials, methods, and examples provided herein are illustrative only and not intended to be limiting. 
         [0000]    Implementation of the method and system of the present invention involves performing or completing certain selected tasks or steps manually, automatically, or a combination thereof. 
         [0099]    While the following description focuses on dental implants, however embodiments of the present invention are not limited to dental applications of a screw type endosseous dental implant, where embodiment of the present invention may be implemented in other skeletal bone implant applications for example orthopedics for other regions of the body. 
         [0100]    Although the foregoing description is provided with reference and examples toward dental implants, such description and examples are provided for illustrative non-limiting purposes only and are not intended to limit the scope or spirit of the present invention, solely to dental application(s). The endosseous dental implant of the present application may be adapted for use with a plurality of optional applications and/or bones for example orthopedic application 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0101]    The invention is herein described, by way of example only, with reference to the accompanying drawings. With specific reference now to the drawings in detail, it is stressed that the particulars shown are by way of example and for purposes of illustrative discussion of the preferred embodiments of the present invention only, and are presented in order to provide what is believed to be the most useful and readily understood description of the principles and conceptual aspects of the invention. In this regard, no attempt is made to show structural details of the invention in more detail than is necessary for a fundamental understanding of the invention, the description taken with the drawings making apparent to those skilled in the art how the several forms of the invention may be embodied in practice. 
           [0102]    In the drawings: 
           [0103]      FIG. 1A-B  show schematic block diagram of aspects of dental implants; 
           [0104]      FIG. 2A  is an illustrative schematic diagram of the dental implant according to an optional embodiment of the present invention; 
           [0105]      FIG. 2B-D  are illustrative schematic diagrams of the body framework of the dental implant according to an optional embodiment of the present invention; 
           [0106]      FIG. 2E  is an illustrative schematic diagrams showing a cross sectional view of the anchor showing the threading profile of the dental implant according to an optional embodiment of the present invention; 
           [0107]      FIG. 3A-D  are illustrative schematic diagrams showing optional perspective views of the dental implant according to an optional embodiment of the present invention; 
           [0108]      FIG. 4A-C  are illustrative schematic diagrams showing bottom views of the dental implant according to an optional embodiment of the present invention; 
           [0109]      FIG. 5A-C  are schematic illustrative diagrams showing threading and flute parameter configuration of the implant anchor according to an optional embodiment of the present invention; 
           [0110]      FIG. 6A-G  are illustrative schematic diagrams showing the views of the dental implant coupled with optional abutments, according to an optional embodiment of the present invention; 
           [0111]      FIG. 7A-F  are illustrative schematic diagrams showing the views of an abutment, according to an optional embodiment of the present invention; 
           [0112]      FIG. 8A-P  show schematic illustrative diagrams of exemplary dental implant threading according to optional embodiments of the present invention; 
           [0113]      FIG. 9A-C  show schematic illustrative diagrams of optional embodiments for a dental implant according to optional embodiments of the present invention; 
           [0114]      FIG. 10A-C  show schematic illustrative diagrams of optional embodiments of a dental tool for removal of an implant&#39;s coronal section, according to an optional embodiment of the present invention; 
           [0115]      FIG. 11A  shows schematic illustrative diagram depicting an optional method according to embodiments of the present invention; 
           [0116]      FIG. 11B  shows schematic illustrative diagram depicting an optional method according to embodiments of the present invention; 
           [0117]      FIG. 12A-B  show schematic illustrative diagrams depicting an optional method according to embodiments of the present invention; 
           [0118]      FIG. 13A-B  show schematic illustrative diagrams of optional embodiments for a dental implant according to optional embodiments of the present invention; 
           [0119]      FIG. 14A-B  show schematic illustrative diagrams of optional embodiments for a dental implant according to optional embodiments of the present invention; 
           [0120]      FIG. 15A-G  are illustrative schematic diagrams showing the views of an abutment having a universal connection platform, according to an optional embodiment of the present invention; and 
           [0121]      FIG. 16  shows a schematic illustrative diagram of optional embodiment of a dental tool for introducing and/or inserting an implant according to an optional embodiment of the present invention. 
       
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
       [0122]    The principles and operation of the present invention may be better understood with reference to the drawings and the accompanying description. The following figure reference labels are used throughout the description to refer to similarly functioning components are used throughout the specification hereinbelow. 
         [0000]    
       
         
               
               
               
             
           
               
                   
                   
               
             
             
               
                   
                  10 
                 abutment; 
               
               
                   
                  20 
                 abutment screw; 
               
               
                   
                  50 
                 interface cavity; 
               
               
                   
                  52, 54, 
                 connection platform; 
               
               
                   
                  30 
                 implant core threading; 
               
               
                   
                  32 
                 apical side; 
               
               
                   
                  34 
                 coronal side; 
               
               
                   
                  36 
                 lateral edge; 
               
               
                   
                  30b 
                 a base; 
               
               
                   
                  30d 
                 thread depth; 
               
               
                   
                  30a 
                 horizontal plane; 
               
               
                   
                  38 
                 inter-thread face; 
               
               
                   
                  100 
                 dental implant; 
               
               
                   
                  100p 
                 proximal end/coronal end; 
               
               
                   
                  100d 
                 distal end/apical end; 
               
               
                   
                  110 
                 coronal portion; 
               
               
                   
                  110a, b, c 
                 coronal segments; 
               
               
                   
                  110d 
                 coronal portion distal end; 
               
               
                   
                  110p 
                 coronal portion proximal end; 
               
               
                   
                  112 
                 coronal threading; 
               
               
                   
                  114 
                 external connecting platform; 
               
               
                   
                  115 
                 coronal portion recessed grooves; 
               
               
                   
                  115e 
                 coronal extending extension; 
               
               
                   
                  116 
                 surface connecting platform; 
               
               
                   
                  118 
                 internal connecting platform; 
               
               
                   
                  120 
                 body portion; 
               
               
                   
                  120a 
                 proximal segment; 
               
               
                   
                  120b 
                 distal segment 
               
               
                   
                  120c 
                 core; 
               
               
                   
                  120d 
                 distal end; 
               
               
                   
                  120e 
                 distal end dimension; 
               
               
                   
                  120f 
                 proximal end dimension; 
               
               
                   
                  120p 
                 proximal end; 
               
               
                   
                  121 
                 core segments 
               
               
                   
                  122 
                 flute; 
               
               
                   
                  122r 
                 flute recess; 
               
               
                   
                  122n 
                 flute neck; 
               
               
                   
                  122e 
                 flute bevel edge; 
               
               
                   
                  122i 
                 flute inner radius; 
               
               
                   
                  122q 
                 flute outer radius; 
               
               
                   
                  122o 
                 flute proximal opening; 
               
               
                   
                  122p 
                 flute bottleneck profile; 
               
               
                   
                  122s 
                 flute bottleneck shoulders 
               
               
                   
                  124 
                 thread; 
               
               
                   
                  124a 
                 thread apical side 
               
               
                   
                   
                 surface/angle; 
               
               
                   
                  124b 
                 thread base; 
               
               
                   
                  124c 
                 thread coronal side surface/angle; 
               
               
                   
                  124f 
                 thread face edge or width; 
               
               
                   
                  124i 
                 inter-thread surface; 
               
               
                   
                  124p 
                 thread pitch; 
               
               
                   
                  124L 
                 thread lead; 
               
               
                   
                  124o 
                 thread angle 
               
               
                   
                  124s 
                 thread sub-segment, wing, blade; 
               
               
                   
                  124w 
                 thread flute face surface; 
               
               
                   
                  125a 
                 blade apical end; 
               
               
                   
                  125c 
                 blade coronal end; 
               
               
                   
                  126 
                 apical end; 
               
               
                   
                  126e 
                 apical end edge; 
               
               
                   
                  130 
                 one piece implant 
               
               
                   
                  140 
                 horizontal plane contour 
               
               
                   
                   
                 modification; 
               
               
                   
                  140m 
                 medial-lateral contour 
               
               
                   
                   
                 modification; 
               
               
                   
                  140a 
                 anterior-posterior contour 
               
               
                   
                   
                 modification; 
               
               
                   
                  140c 
                 undercut 
               
               
                   
                  142, 144 
                 thread horizontal plane 
               
               
                   
                   
                 sub-segments; 
               
               
                   
                  150 
                 one recessed grooves; 
               
               
                   
                  152 
                 outwardly extending 
               
               
                   
                   
                 extension; 
               
               
                   
                  200, 230, 220 
                 Dedicated tool; 
               
               
                   
                  202 
                 tool connection interface; 
               
               
                   
                  204 
                 tooling surface; 
               
               
                   
                  210 
                 implant interface portion; 
               
               
                   
                  212 
                 central body portion; 
               
               
                   
                  214 
                 ring portion; 
               
               
                   
                  216 
                 distal end cap; 
               
               
                   
                  224, 234 
                 cylindrical tooling body; 
               
               
                   
                  236, 226a, 226b 
                 tooling surface 
               
               
                   
                   
                 or edge; 
               
               
                   
                  228, 238 
                 stopping interface portion; 
               
               
                   
                 1300 
                 conical connection platform 
               
               
                   
                   
                 dental implant; 
               
               
                   
                 1300a-c 
                 variable diameter 
               
               
                   
                   
                 implants; 
               
               
                   
                 1302 
                 internal conical connection 
               
               
                   
                   
                 platform; 
               
               
                   
                 1302d 
                 conical connection platform 
               
               
                   
                   
                 distal end; 
               
               
                   
                 1302p 
                 conical connection platform 
               
               
                   
                   
                 proximal end; 
               
               
                   
                 1304 
                 connection platform 
               
               
                   
                   
                 threading; 
               
               
                   
                 1305 
                 proximal portion; 
               
               
                   
                 1305d 
                 proximal portion distal end; 
               
               
                   
                 1305p 
                 proximal portion proximal 
               
               
                   
                   
                 end; 
               
               
                   
                 1306 
                 first conical sub-segment; 
               
               
                   
                 1308 
                 second conical sub-segment; 
               
               
                   
                   
                 1310 medial portion; 
               
               
                   
                 1311 
                 medial portion anti-rotation 
               
               
                   
                   
                 platform; 
               
               
                   
                 1312 
                 medial portion recess; 
               
               
                   
                 1314 
                 inter-digitation anti-rotational 
               
               
                   
                   
                 interface; 
               
               
                   
                 1316 
                 proximal portion recess; 
               
               
                   
                 1320, 1330 
                 abutment; 
               
               
                   
                 1322, 1332 
                 abutment crown 
               
               
                   
                   
                 portion; 
               
               
                   
                 1324, 1334 
                 abutment implant 
               
               
                   
                   
                 interface portion; 
               
               
                   
                 1326, 1336 
                 inter-digitation male 
               
               
                   
                   
                 connector; 
               
               
                   
                 1328 
                 snap fit male connector; 
               
               
                   
                 1338 
                 medial portion anti-rotational 
               
               
                   
                   
                 platform; 
               
               
                   
                   
               
             
          
         
       
     
         [0123]      FIG. 1A  shows a schematic block diagram representation of a dental implant showing the main aspects of dental implant. A dental implant  1  includes a coronal portion  2  and a body portion  4  that are continuous with one another. The coronal portion  2  defines the proximal end  1   p  of the bone implant and the body portion  4  defines the distal end of  1   d  the implant  1 . The body portion  4  comprises an inner core  4   i  that is fit with at least one threading  6  that extend horizontally along a horizontal plane  30   a  and progresses along the length of the implant body core  4 . The inner core  4  defines an internal diameter  4   i  of body portion  4  while the threading  6  defines the external diameter  4   e  of the body portion  4 . 
         [0124]    The shape and/or profile of body portion  4  may be highly variable and may assume a plurality of shapes and/or configurations and/or profiles for example including but not limited to straight, tapered, conical, cylindrical, linear, parallel, symmetric, asymmetric, trapezoidal, mixed conical, segmented, multi segmented and any combination thereof. 
         [0125]    Implant  1  may further comprise micro-threads  8  along either the coronal portion  2  and/or body portion  4 . Optionally body portion  4  may comprise both micro-threads  8  and threading  6 . 
         [0126]      FIG. 1B  shows a schematic block diagram representation of a dental implant threading  6  specifically showing aspects of dental implant thread.  FIG. 1B  shows different profiles of threading  6  that are known in the art having different characteristics. Thread  6  extends from the implant&#39;s core body portion  4  along a horizontal plane  30   a  represented by the dashed line. The horizontal plane  30   a  comprises two axes a first axis along the medial-lateral axis ‘M-L’, and a second axis, along the anterior-posterior axis ‘A-P’ extending around implant body  4 , for example as shown in  FIG. 8A   
         [0127]    The basic thread structure is an extension that has an apical side  32 , a coronal side  34 , and a lateral edge  36  that connects the apical side and the coronal side, a base  30   b  connecting the thread  6  to the implant core  4 , a thread depth  30   d  that is defined between the lateral edge  36  and the base  30   b.    
         [0128]    The thread may also be defined by a plurality of additional parameters that provided and/or determine the thread characteristics that depict how the thread behaves relative to the bone. Thread parameters may for example including but not limited to: the contour of the inter-thread-face  38 , the overall shape of the core body portion  4   i , how the threads progresses along the length of the implant body, the number of starts, number of flutes, thread pitch, thread dispersal along the implant body, the like or any combination thereof. 
         [0129]    Thread parameters and some known configurations are schematically shown in  FIG. 1B , where the thread may comprises a straight segments or curved edge that are defined along the coronal side  34  and/or the apical side  32  of the thread. The thread may be configured to be symmetric or asymmetric relative to the horizontal plane  30   a . The angulation of the thread, along any of its parts including the apical side  32 , coronal side  34 , lateral edge and inter-thread face  38  may be controlled. 
         [0130]    The below description refers to collectively to  FIG. 2-5  using the same reference labels for the same parts throughout the description. 
         [0131]      FIG. 2A  shows a schematic illustrative diagram of dental implant  100  according to an optional embodiment of the present invention. Anchor  100  comprises a proximal end  100   p  and a distal end  100   d , the distal end  100   d  also referred to as the apical end  126  of the implant. 
         [0132]    Implant  100  has a substantially cylindrical or conical or circular cylindrical form, including a coronal portion  110  and a body portion  120 . The body portion  120  comprising threading  124  that are fit with at least two or more flutes  122  disposed along the full length of implant  100 . 
         [0133]    The figures and description herewith depict an implant featuring coronal portion  110 , body portion  120 , threading  124  and at least two flutes  122 . However, the present invention is not limited in its scope to cover an implant having all of these features in a single body and/or embodiment. 
         [0134]    The present invention includes optional embodiments for an implant that may comprise at least one or more of the following features in any combination thereof, selected from the group consisting of: at least two flutes  122 , coronal segment  110 , and body core  120   c.    
         [0135]      FIG. 2A  shows coronal portion  110  described and shown is a non limiting example of an optional coronal portion  110  that may be provided with implant  100 . Coronal portion  110  is generally provided as an interfacing platform to facilitating coupling an implant with other dental implant components for example including but not limited to an abutment, a crown, a bridge, a dental prosthesis, an anatomical abutment, an angled abutment, a collar, a ball attachment, a healing cap, platform switching abutment, the like or any combination thereof. 
         [0136]    The coronal portion  110  may be provided with an internal interfacing platform  50 , for example as shown in  FIG. 2E , or an external interfacing platform (not shown). Optionally an external interfacing platform may for example include but is not limited to an external hex configuration as is known in the art. Optionally the interfacing platform  50  provide s for coupling the implant with other dental implant structures such as crowns, abutments, transfers or the like. Optionally the interfacing platform  50  may provide a tooling interface provided for maneuvering and/or tooling the implant  100 . 
         [0137]      FIG. 2D , shows the overall shape of the various parts and segments forming implant  100 . As shown coronal portion  110  and body portion  120  comprise substantially cylindrical body of varying diameter. Implant  100  is characterized in that the proximal end  120   p  of body portion  120  is configured to have a larger overall diameter than the distal segment  110   b  of coronal portion  110 . Most preferably this allows a practitioner to gain access to a proximal portion of body portion  120  from the coronal portion  110 , for example as will be described later with respect to flute  122 . 
         [0138]    Optionally, coronal portion  110  may comprise threading  112 ,  FIG. 2A , along at least a portion of the external surface. Optionally and preferably threading  112  may be provided to improve bone retention and osseointegration, for example in the form of micro-threads. Optionally coronal threading  112  may be configured to have a double lead, with a pitch of about 0.5 mm and thread angle of about 25 degrees to about 35 degrees. Optionally threading  112  may be configured according to the configuration of the body portion threading  124  and may be configured to facilitate integration within the bone. 
         [0139]    Optionally threading  112  may be configured according to at least one or more threading parameters as is known in the art, for example including but not limited to lead, pitch, thread angle, thickness, major diameter, minor diameter, taper angle, thread orientation, end position, start position, porosity, number of stops, number of starts, number of leads, number of cuts, lead in angle, the like or any combination thereof of threading variable and/or parameters. 
         [0140]    Optionally coronal portion  110  may be devoid of threading  112 . 
         [0141]    Coronal portion  110  preferably comprises at least three or more substantially cylindrical segments and/or circular cylindrical segments that are continuous with one another. More preferably coronal portion  110  comprises three substantially cylindrical segments and/or circular cylindrical segments,  110   a - c , for example as shown,  FIG. 2C . Optionally each segment comprises a trapezoidal cross sectional profile having two parallel bases, defining the proximal diameter and distal diameter respectively of each segment and two angulated legs defining the external surface of the respective segment. 
         [0142]    Optionally coronal segments  110   a - c  may be provided with an optional cross-sectional profile selected from circular, circular-cylindrical, cylindrical, conical, trapezoidal, the like or any combination thereof. 
         [0143]    A first segment  110   a  defines the proximal segment of coronal portion  110  including the proximal end  110   p  of implant  100 . 
         [0144]    A second segment  110   b  defines the distal segment of coronal portion  110  and is continuous and fluid with the proximal portion of body portion  120 . 
         [0145]    Optionally and preferably a third segment  110   c  defines the medial segment of coronal portion  110 . Most preferably medial segment  110   c  is disposed between proximal segment  110   a  and distal segment  110   b . Optionally, coronal portion  110  may be configured to include at least one or more medial segments  110   c.    
         [0146]    Optionally medial segment  110   c  may be configured to have a circular-cylindrical profile wherein the proximal diameter of medial segments  110   c  and distal diameter of medial segments  110   c  are substantially equivalent to one another. 
         [0147]    Optionally and preferably each of the coronal segments  110   a - c  have a proximal diameter and a distal diameter defined about the base of said trapezoidal profile. Preferably the diameter is sequentially increasing in the distal direction, such that the proximal diameter is smaller than the distal diameter of each of said segments. The individual coronal segments  110   a - c  preferably comprises an angled external surface corresponding to angle defined by the legs of the trapezoidal profile. 
         [0148]    Optionally at least one or more of the coronal portion  110  segments  110   a - c  may serve as an optional connection platform for implant  100 . 
         [0149]    Optionally proximal segments  110   a  may serve and provide at least two connection platforms including an external connection platform  114  and surface connection platform  116 . 
         [0150]    Optionally and preferably the distal segment  110   b  may be configured to be continuous with body portion  120  of implant  100 . Optionally and preferably the distal diameter the distal segment  100   b  is equal to the proximal diameter of body portion  120  and the proximal diameter of distal segment  110   b  is smaller than the proximal diameter of body portion  110 . 
         [0151]    Optionally, as shown in  FIGS. 2E and 3B , implant  100  may comprises a cavity disposed internally within implant  100  defined between the coronal portion  110  and at least partially within a proximal portion of body portion  120 . Preferably the cavity  50  forms an opening at the proximal end  100   p  of dental implant  100  and may be configured to be a connecting platform  118  provided for coupling and/or associating with at least one or more dental implant components for example including but not limited to an abutment, a crown, a bridge, abutment screw, fixation screw, a dental prosthesis, an anatomical abutment, an angled abutment, a collar, a ball attachment, a healing cap, the like or any combination thereof. 
         [0152]    Optionally cavity opening  50 ,  FIG. 2E , may provide a least one or more connecting platforms  114 ,  116 ,  118 , provided for connection optional dental implant components, for example an abutment  10  and abutment screw  20  as shown in  FIG. 6A-E . 
         [0153]    Optionally the cavity  50  may form at least two connecting platforms including at least one internal connecting platform  118  and at least one surface connecting platform  114 . 
         [0154]    Optionally the coronal portion  110  may further comprises an external structure configured to attach an abutment or the like dental implant components for example including but not limited to an abutment, a crown, a bridge, abutment screw, fixation screw, a dental prosthesis, an anatomical abutment, an angled abutment, a collar, a ball attachment, a healing cap, the like or any combination thereof. 
         [0155]    Optionally coronal portion  110  may be configured to be coupled, and/or associated and/or integrated with an abutment  10  utilizing an abutment screw  20 , as shown in  FIG. 6A-E . Optionally coronal portion  110  may be configured to be coupled and/or associated with optional dental implant components for example including but not limited to an abutment, a crown, a bridge, abutment screw, fixation screw, a dental prosthesis, an anatomical abutment, an angled abutment, a collar, a ball attachment, a healing cap, the like or any combination thereof. 
         [0156]    Coronal portion  110  extends distally (apically) toward the distal (apical) end  100   d , therein defining the body portion  120  of implant  100 . The proximal end  120   p  of body portion  120  is continuous with the distal end  110   d  of distal segment of  110   b  defining the overall largest diameter of implant  100 , for example as seen in  FIG. 2B, 2D . 
         [0157]    Preferably the overall diameter of implant  100  is defined over its two portions, namely body portion  120  and coronal portion  110 . Along the length of body portion  120  the overall implant diameter is apically decreasing from proximal end  120   p  to the apical end  100   d . Along the length of coronal portion  110  the overall implant diameter is apically increasing from proximal end  110   p  to distal end  110   d . Accordingly implant  100  is substantially cylindrical and/or circular cylindrical, having a barrel like shape along its outer diameter, for example as seen in  FIG. 2B, 2D . 
         [0158]    As best seed in  FIG. 2B, 2D  body portion  120  may comprise at least two sub-segments a proximal sub-segment  120   a  and a distal sub-segment  120   b . Optionally and preferably body portion  120  more preferably core  120   c  may further comprise a plurality of sub segments  121  of varying dimension and configuration. Optionally each core sub-segment  120   a ,  120   b ,  121  may comprise a substantially cylindrical body having a trapezoidal profile each with a distally decreasing diameter such that the proximal diameter is larger than the distal diameter. Optionally core sub-segments  121  may be provided with a circular-cylindrical and/or trapezoidal profile. 
         [0159]    Body portion  120  comprises a core  120   c  that spans along the length of body portion  120  from proximal end  120   p  to distal end  120   d . Core  120   c  comprises an overall trapezoidal profile,  FIG. 2E , where the distal end/apical end  120   d  defining the smallest diameter at the apical end  120   d  and the largest diameter defined at the proximal end  120   p . Most preferably core  120   c  is substantially flat at the apical end  120   d ,  126 . 
         [0160]    As shown in  FIG. 2B, 2D , optionally and preferably core  120   c  may be provided from a plurality of sub-segments  120   a ,  120   b ,  121  that may be configured to be cylindrical and/or trapezoidal. 
         [0000]    For example as shown in  FIG. 2B  the core  120   c  may be configured to have a plurality of sub-segments for example, where profile line  121   a  shows an optional core profile comprising six sub-segments including proximal sub-segment  120   a , distal sub-segment  120   b  that are intervened with four sub-segments  121 . As can be seen sub-segments  121  may be configured to be cylindrical and/or trapezoidal and/or circular cylindrical in any arrangement however the overall core  120   c  diameter is sequentially apically decreasing. 
         [0161]      FIG. 2B  shows another optional configuration for core  120   c , as shown profile line  121   b  comprises four core sub-segments including proximal sub-segment  120   a , distal sub-segment  120   b  that are intervened with two sub-segments  121 . As can be seen sub-segments  121  may be configured to be cylindrical and/or trapezoidal and/or circular-cylindrical in any arrangement however the overall core  120   c  diameter is sequentially apically decreasing. 
         [0162]    Most preferably, core  120   c  defines the inner diameter of body portion  120 , while the lateral face  124   f  of threading  124 , extending outwardly form core  120   c , defines the outer diameter of body portion  120 . 
         [0163]    As best seen in  FIG. 2A, 2E, 2-3  core  120   c  is fit with threading  124  comprising at least one and more preferably two or more threads that extend along the length of body portion  120  from distal end  100   d  to proximal end  120   p . Threading  124  comprises a base  124   b  connecting thread  124  to core  120   c . Thread base  124   b  comprises an apical side  124   a , a coronal side  124   c , and a lateral edge  124   f  (defining the thread width) connecting the apical side  124   a  and the coronal side  124   c . Thread base  124   b  having a thread depth defined between the lateral edge  124   f  and core  120   c . The lateral edge  124   f  of the thread may be configured to have a variable width that increases along said body segment in a coronal direction, configured so that the smallest width of the lateral edge  124   f  of the thread is adjacent the distal segment  120   b  and the largest width of the lateral edge of the thread is adjacent the coronal segment  110 . 
         [0164]    Optionally and preferably thread  124  may be provided with variable thread depth that generally increases along the length of body portion  120  in an apical direction, so that the smallest depth of the thread is adjacent the coronal portion and the largest depth of each thread is adjacent the apical end  120   d.    
         [0165]    Optionally thread  124  may be provided with variable thread depth that is generally increasing along the length of body proximal segment  120   a  in an apical direction, and is generally decreasing along the length of body distal portion  120   b  in an apical direction, so that the smallest depth of the thread is adjacent the coronal portion and the largest depth of each thread may be found between the distal body portion  120   b  and proximal body portion  120   a.    
         [0166]    Most preferably threading  124  is provided in the form of double thread having at least two starts. Optionally threading  124  may be provided with a single start. Optionally threading  124  may be provided with a plurality of starts. 
         [0167]    Most preferably the apical end  100   d ,  126 , best seen in  FIG. 3C-D , and  FIG. 4A-C , features at least two cutting leading edge  126   e  tips that extends from the core  120   c  preceding the starting thread of each of thread  124  respectively therein acting as a lead-in to thread  124 . Optionally and preferably leading cutting edge  126   e  may be configured to having a coronal side angle equal to the coronal angle of threading  124  so as to facilitate is start. Optionally and preferably leading edge  126   e  provides the initial bone drilling element contact therein stabilizing the implant  100 . 
         [0168]    Preferably threading  124  is provided with a thread angle from about 20 degrees to about 60 degrees. Optionally and preferably threading  124  is provided with a thread angle is provided from about 20 to about 40 degrees. Preferably threading  124  is provided with a thread angel of 35 degrees or 25 degrees. 
         [0169]    Optionally thread  124  may be configured to a be a double lead thread having a thread angle of 35 degrees, a pitch of about 2.1 mm. 
         [0170]    Optionally thread  124  may be configured to a be a double lead thread having a thread angle of 25 degrees, a pitch of about 1.1 mm to about 1.8 mm. 
         [0171]    Optionally thread  124  may be further configured according to at least one or more threading parameters as is known in the art, for example including but not limited to lead, pitch, thread angle, thickness, major diameter, minor diameter, taper angle, thread orientation, end position, start position, porosity, number of stops, number of starts, number of leads, number of cuts, lead in angle, the like or any combination thereof of threading variable and/or parameters. 
         [0172]    Implant  100  features at least two or more longitudinal channels  122  forming flutes that span the full length of body portion  120  along threading  124 . Optionally thread  124  may feature at least two longitudinal flute recessed channels  122 . Optionally and preferably may feature four longitudinally recessed channels  122 , for example as shown in the figures. 
         [0173]    Flutes  122  are preferably configured to mill bone, collect, condense and to disperse house bone when the dental implant  100  is rotated with a dental implant maneuvering tool, for example in the form of a dental hand-piece, both in the clockwise or counterclockwise direction. 
         [0174]    Most preferably flute  122  features a proximal opening  122   o  that is accessible from the coronal portion  110 . Optionally the proximal opening  122   o ,  FIG. 3A-D , to flutes  122  provides for gaining access to flute  122  from coronal portion  110  so as to allow a practitioner to introduce bone, bone grafting material, bone generating medium, bone grafting media, bone growing medicaments and/or enhances into flute  122  therein facilitating the bone growth process and improving osseointegration of implant  100  at the implantation site for example about any portion of the mandible or maxilla. Optionally proximal opening  122   o  may also provide a window to remove any excess bone compacted within the flute  122 . Optionally and preferably proximal opening  122   o  further provides for receiving and/or introducing bone in the occlusal most preferably for providing support of the gingiva. 
         [0175]    Optionally and preferably flutes  122  form a channel along the length of body portion  120  featuring a longitudinal axis selected from the group consisting of linear, curved, arcuate, arched, sigmoidal, spiral the like or any combination thereof. The perspective view of  FIG. 3C-D  and  FIG. 4B  show an example of curved longitudinal axis of flute  122  that is curved along the length of body portion  120 . 
         [0176]    Optionally the longitudinal axis of flute  122  may be defined according to the profile of the core portion  120   c , for example according to lines  121   a , 121   b.    
         [0177]    Optionally implant  100  comprising a plurality of flutes  122 , individual flutes and/or group of flutes  122  may be fit with an independent longitudinal axis. For example, an implant comprising four flutes may be configured such that each pair of opposing flutes may have a different longitudinal axis. For example, an implant comprising 3 flutes may be configured such that each flute may have a different longitudinal axis. 
         [0178]    Optionally and preferably an implant comprising a plurality of flutes may be configured to have the flutes distributed equally along the circumference of body portion  120 , therein diving threading  124  into equally spaced thread sub-segments. For example as shown, implant  100  comprising four equally spaced flutes divides threading  124  into four winged members. 
         [0179]    Optionally an implant comprising a plurality of flutes may be configured to have the flutes distributed unequally along the circumference of body portion  120 , therein dividing threading  124  into a plurality of unequally spaced and sized thread sub-segments. 
         [0180]    Preferably each flute  122  divides threading  124  into a number of smaller thread sub-segments equal to the number of flutes  122 . As shown, implant  100  provided with four flutes  122  forming four winged thread sub-segments  124   s.    
         [0181]    Most preferably flute  122  is configured to have a bottle neck profile across the base and depth of threading  124 . Therein flute  122  is formed between core  120   c  and threading lateral edge  124   f . Preferably the bottleneck profile assumes an ovoid flask shape, for example as shown  FIG. 5B-C . 
         [0182]    Preferably the bottleneck profile  122   p  may be formed from two sigmoid curved shoulders  122   s  and a neck portion  122   n , the shoulders  122   s  extending anteriorly from core  120   c  toward thread lateral edge  124   f  therein forming an ovoid shape recess  122   r  along the base to and forming a neck  122   n  across lateral surface  124   f . Most preferably the long axis of ovoid recess  122   r  is defined along core  120   c  and the short axis is formed across the thread  124  base between core  120   c  and lateral face  124   f.    
         [0183]    Most preferably the bottleneck shaped recess flute  122  formed along thread  124  forms a plurality of thread sub-segments  124   s , best seen in  FIG. 4C , therein each sub-segment  124   s  forms a wing-shaped thread having two beveled edges  122   e  along the thread lateral face  124   f  defined by the neck portion  122   n  of flute  122 . Most preferably this significantly increases the number of cutting edges provided along implant  100 . 
         [0184]    Most preferably flute  122  forms a plurality of sub-segments  124   s  and/or blades and/or wings, along threading  124 , as seen in  FIG. 4C , provides for significantly increasing the surface area of implant  100  therein facilitating osseointegration and ensuring a 360 degrees of implant support. 
         [0185]    Apical end surface  126  optionally and preferably facilitates sinus lifting while maintaining the Schneiderian membrane by virtue of surface  126  being flat and/or apical to that the threads  124   s  therefore surface  126  may serve as a protective barrier of the Schneiderian membrane from threads  124   s . Accordingly sinus lifting procedure may be facilitated by implant  100  in that bone may be directed apically, by rotation in both the clockwise and/or counterclockwise direction, allowing for bone growth while distal end surface  126  further facilitates maintaining the integrity of the Schneiderian membrane. 
         [0186]    Most preferably flute  122  is configured such that the length of shoulder  122   s  is gradually decreasing in a proximal direction along the length of implant  100 , such that shoulders  122   s  are longest at the proximal end  100   d  and shortest at adjacent to coronal segment  110 . 
         [0187]    Optionally shoulder  122   s  is a sigmoid configured to have an inner radius  122   i  of about 0.4 mm and an external radius  122   q  of about 0.3 mm; wherein the inner radius  122   i  defines the ovoid recess  122   r  and the external radius defines the neck  122   n , as best seen in  FIG. 5B-C   
         [0188]    Optionally the ovoid recess  122   r  at its widest part has a distance of about 1.6 mm while the neck  122   n  at its widest has a distance of about 1.0 mm, as best seen in  FIG. 5B . 
         [0189]    Optionally flute  122  may be configured to have pitch of 35 mm along the length of implant  100 . Optionally flute  122  may be configured to have a thread number of four. Optionally flute  122  may be configured to have a thread number equal to the number of flutes  122 . Optionally flute  122  may be configured according to and/or as a function of at least one or more parameter defining threading  124 . 
         [0190]    Optionally flute  122  may be configured to have the threading profile according to at least one or more threading parameters for example including but not limited to lead, pitch, thread angle, thickness, major diameter, minor diameter, taper angle, thread orientation, end position, start position, porosity, number of stops, number of starts, number of leads, number of cuts, lead in angle, the like or any combination thereof of threading variable and/or parameters 
         [0191]    Most preferably the thread  124  and flute  122  are configured so as to provide a cutting surface and collect bone when implant  100  is rotated both clockwise or counterclockwise. 
         [0192]      FIG. 5C  shows optional configuration and profiles for flute  122  according to the present invention.  FIG. 5C  shows optional configuration of flute  122  wherein the profile  122   p  may be configured according to the size of the neck  122   n , and the size of the ovoid recess  122   r , for example a shown. 
         [0193]      FIGS. 2B and 2D  show optional profiles of body portion  120 , showing optional configurations of the inner core  120   c . As shown in lines  121   a ,  121   b  showing that core  120   c  may be configured according to a plurality of sub-segments  120   a ,  120   b ,  121  in optional combinations of cylindrical and/or trapezoidal and/or circular-cylindrical sub-segments. 
         [0194]      FIG. 2C  shows an optional embodiment of the present invention therein showing coronal section  110  featuring three sub-segments  110   a - c , as previously described. Optionally coronal section  110  may be fit on any optional implant body, and is therefore not limited to the implant body  120  as described herein. 
         [0195]      FIG. 2E  shows a cross section of implant  100  therein revealing threading  124  configuration and the core configuration  120   c.    
         [0196]      FIG. 3A-D  show perspective views revealing an option internal interface cavity  50  that facilitates attachment to optional dental implant components, as previously described, for example including but not limited to an abutment, a crown, a bridge, abutment screw, fixation screw, a dental prosthesis, an anatomical abutment, an angled abutment, a collar, a ball attachment, a healing cap, the like or any combination thereof. 
         [0197]    The perspective view provided by  FIG. 3B  further shows the coronal access to flute  122  via opening  122   o.    
         [0198]      FIG. 3C-D  and  FIG. 4A-C  show an apical perspective view revealing apical end  126  including a cutting leading edge  126   e  and the onset of the double lead thread  124 , as previously described. 
         [0199]      FIG. 4C  shows the formation of a plurality of thread sub-segments  124   s  and or wing and/or blade that is equal to the number of flutes  122 . 
         [0000]    Apical end  126  is substantially flat and including at least one cutting leading edge tip  126   e  extending from the core  120   c  preceding the start of each of thread  124 . Optionally and preferably the cutting leading edge tip  126   e  preferably provides for stabilizing said implant within a bone, and allowing to allow for bone to grow around the implant  100 . Accordingly tips  126   e  may be utilized to implant  100  within a 1 mm of bone and introducing bone grafting and/or generating medium around the surface of implant.
 
Preferably the apical end  126 ,  100   d  further comprises a first thread sub-segment  124   s  (wing, blade) having two opposing lateral beveled ends  122   e  along the lateral surface including a first (apical) wing end  125   a  and a second (coronal) wing end  125   c . Optionally and preferably second (coronal) wing end  125   c  may further comprise an apical face  124   a  undercut therein elevating second (coronal) wing end  125   c  relative to said first (apical) wing end  125   a , provided to facilitate drilling.
 
         [0200]      FIG. 4C  further reveals the profile of flute  122  as a bottle neck formation  122   p  formed by two shoulders  122   s  forming a neck portion  122   n  and a recess  122   r  provided for collection and receiving bone as the drill is rotated in either clockwise or counterclockwise directions. Optionally and preferably the shape and/or profile  122   p  of flute recess  122   r  may be determined by controlling the size ratio of neck size  122   n  and recess  122   r.    
         [0201]      FIG. 5A  shows an optional configuration of threading  124  show the thread pitch  124   p , thread lead  124 L shown as two leads, and thread angle  124   o .  FIG. 5A  depicts and optional thread configuration where the number of thread leads  124 L is two, the thread angle  124   o  equal to about 35 degrees and the thread pitch  124   p  of about 2.1 mm. Further optional thread parameter may for example be thread lead  124 L of two, thread angle  124   o  equal to about 25 degrees, and thread pitch  124   p  of about 1.8 mm. 
         [0202]      FIG. 5B  shows an optional configuration of flute  122  showing the flute bottle neck profile  122   p  that is formed between two shoulders  122   s  having an internal radius  122   i  and an outer radius  122   q  to form a recess  122   r  and neck  122   n.    
         [0203]      FIG. 5C  shows optional configurations and profiles for flute  122  according to the present invention having an ovoid base  122   r  and a neck portion  122   n  that may be configured relative to one another and form an edge  122   e . The neck  122   n  preferably defines flute edge  122   e  on either side of the neck  122   n . Optionally flute edge  122   e  may be configured to be symmetric or asymmetric about the neck  122   n  therein forming different configurations of flute edge  122   e  on either side of neck  122   n  for example as shown in  FIG. 5C . 
         [0204]    Optionally the flute  122  may assume different profiles, for example as shown in  FIG. 5C , along its length. Optionally each flute  122  disposed with implant  100  may assume a different flute profile along its length. 
         [0205]      FIG. 6A-F  show optional abutments  10  that are associated with implant  100  with an abutment screw  20  each utilizing a different connecting platform provided with the implant  100 .  FIG. 6A  shows implant  100  utilizing external connection platform  114  to support an optional abutment  10  along coronal segment  110   c.    
         [0206]      FIG. 6B  shows a further optional abutment  10  supported on implant  100  utilizing external connection platform  114  without the use of surface connecting platform  116 . 
         [0207]      FIG. 6C-D  shows use of an internal connection platform  118  formed with interface cavity  50  where abutments  10  emerges from with cavity  50  without interfacing with the external surface of coronal segment  110 . 
         [0208]      FIG. 6E  shows an abutment  10  and locking screw  20  that utilize the surface connecting platform  116 . 
         [0209]      FIG. 6F  shows an optional embodiments for a one piece dental implant  130  wherein the implant  100  according to optional embodiments is integrated and uniform with and abutment  10 . 
         [0210]      FIG. 6G  shows an optional embodiment for a two piece dental abutment  10   c , for example similar to that shown in  FIG. 7F  and  FIG. 11A , that is configured to associate with the coronal portion  110 , along threading  112  disposed along the coronal portion outer surface. Optionally abutment  10   c  may be further configured to resting along and seal with at least one coronal portion segments  110   a - c , more preferably along distal segment  110   b . Optionally such an abutment  10   c  may be utilized as an abutment replacement following bone resorption as described in greater detail in  FIG. 11A . 
         [0211]    Now referring to  FIG. 7A-F  showing optional embodiments for an abutment  10  in accordance with optional embodiments of the present invention, the abutment  10  is configured to associated and/or otherwise couple with the implant  100  along coronal portion  110  and/or any portion thereof  110   a - c ,  112 ,  114 ,  116 ,  118 . 
         [0212]      FIG. 7A-B  show perspective view of optional abutments  10  according to an optional embodiment of the present invention. 
         [0213]      FIG. 7C-E  show a cross sectional views of the abutment depicted in  FIG. 7A-B  of optional configurations of abutment  10  showing the optional connection platforms utilized to associate and/or couple with implant  100 . 
         [0214]    Abutment  10  according to the present invention provides for coupling with implant  100  an therefore facilitates placement of the implant and abutment in optional configurations and emerging profile for example including but not limited to, bone level, tissue level, endosseous, or the like. 
         [0215]    Most preferably abutment  10  in combination with implant  100  provide for proper implant location and emerging profile based on the implantation site and the mesio-distal plane, and/or the buccal-palatal plane, and/or the buccal-lingual plane. 
         [0216]    Preferably abutment  10  comprises a mediating portion  16  that interfaces with the connecting profiles  116 ,  114 ,  118  of implant  100  to facilitate proper formation of the emerging profile at the implantation site relative to at least one plane selected from the group consisting of mesio-distal plane, and/or the buccal-palatal plane, and/or the buccal-lingual plane, or any combination thereof. 
         [0217]    Abutment  10  has a proximal end  12  and a distal end  14  and medial portion  16  disposed therebetween. Abutment  10  comprises a substantially cylindrical core spanning proximal  12  end and a distal end  14 , shown in dotted lines  10   c  ( FIG. 7D, 7C ) and defining an central axis  10   a  ( FIG. 7C-D ) of abutment  10  and an external surface that is contoured along the length of abutment  10  between distal end  14  and proximal end  12  to define the shape and configuration of abutment  10 . Optionally and preferably each portion of abutment  10 , namely distal  14 , medial  16 , proximal  12 , may be surfaced to provide optional forms and functionality, as is known in the art. Most preferably an optional embodiment of the present invention provides an abutment  10  wherein medial portion  16  is configured to couple and/or interface and/or otherwise associate with at least one connecting profiles  116 ,  114 ,  118  of implant  100 , previously described. 
         [0218]    Optionally medial portion  16  may provide for platform switching, for example as shown where a wider base is provided along proximal portion  12  to facilitate a wide coupling base for a crown (not shown) coupled onto proximal portion  12 . 
         [0219]    Most preferably proximal portion  12  may be provided in optional forms for coupling to an overdenture abutment, bridge, denture, crown or the like restorative structure or prosthetic members. Optionally proximal portion  12  may be provided in optional attachment platforms and forms as is known in the art for example including but not limited to ball attachment, overdenture attachment, casting, UCLA, threaded, gold, snaps, angled, straight, angled, internal cap attachment, the like or any combination thereof. 
         [0220]    Abutment  10  further comprises a prosthesis coupling portion  14   c  disposed along distal end  14 . Preferably coupling portion  14   c  is configured to couple with implant  100  and is provided in optional configuration most preferably to facilitate anti-rotational coupling with coronal portion  110 . Optionally and preferably coupling portion  14   c  comprises a coupling platform to mirror and couple with at least a portion of implant  100  preferably along coronal portion  110  such they fit in a one to one and/or male-female relationship, optionally and preferably about any portion or surface of coronal portion  110  for example including but not limited to  110   a ,  110   b ,  110   c ,  112 ,  114 ,  116 ,  118 , or the like. For example an external coupling platform disposed about coronal portion  110 , providing a male coupling member, may be coupled with a corresponding internal coupling platform  14   c  disposed on abutment distal end  14 , therein comprising a female coupling member. For example an internal coupling platform disposed about coronal portion  110 , providing a female coupling member, may be coupled with a corresponding external coupling platform  14   c  disposed on abutment distal end  14 , therein comprising a male coupling member. 
         [0221]    Coupling portion  14   c  is shown in a non-limiting optional external hex configuration, however it may be realized in a plurality of optional configurations. Optionally coupling portion  14   c  may be provided as an internal configuration, external configuration, or a combination thereof as is known in the art, that may for example be depicted according to the type of connection platform provided on implant  100  coronal portion  110 . Optionally abutment  10  may be provided in optional anti-rotation forms for example including but not limited to at least one or more selected from the group consisting of internal six receptor sockets, scalloped, internal dodecagon, external dodecagon, internal hex internal, external hex, external octagon, internal octagon, external spline, internal spline, Morse taper, internal Morse taper, one piece, internal six lobe, external six lobe, internal tri lobe, external tri-lobe, internal six spline, external six-spline, internal thread, internal pentagon, external pentagon, external thread, internal square, external square, internal five lobe, internal four lobe, internal three spline, external triangle, internal eight spline, external six lobe, internal eight lobe, internal tube to tube plug in, triangular, polygonal of n sides where n&gt;=3 or more, the like as is known in the art or any combination thereof. 
         [0222]    Abutment  10  comprises a central bore  18  extending through at least a portion from proximal end  12  to distal end  14 . Optionally and preferably central bore  18  is provided for receiving a fixation screw and/or an abutment screw  20 . Optionally and preferably abutment screw  20  provides for coupling abutment  10  to implant  100  as previously described and shown in  FIG. 5A-D . 
         [0223]    Abutment  10  comprises a mediating portion  16  defined between proximal end  12  and distal end  14 . Preferably mediating portion  16  defines the abutment&#39;s emerging profile as it emerges from implant  100  toward an implant crown (not shown). Most preferably mediating portion  16  provides for defining the abutment&#39;s connection platform utilized for coupling or otherwise associating with one of the three connection platforms  114 ,  116 ,  118  defined along implant  100 , as previously described. 
         [0224]    For example as shown in  FIG. 7C  shows mediating portion  16  comprising an abutment surface  16   a  provided for coupling and/or interfacing with internal connection platform  118  (as previously described). Optionally and preferably abutment surface  16   a  is a sloping surface gradually sloping from distal end  14  toward proximal end  12 , most preferably surface  16   a  may be configured to have an angle from about 3 degrees and up to about 50 degrees, more preferably from about 4 degrees to about 45 degrees. Most preferably the angle of surface  16   a  may be defined and/or configured according to the connection platform  118  of implant  100 . 
         [0225]    For example as shown in  FIG. 7D  shows mediating portion  16  comprising an abutment surface  16   c  and  16   d  provided for coupling and/or interfacing with external connection platform  114  (as previously described). Optionally and preferably abutment surface  16   c  is a sloping surface having an angle from of up to about 70 degrees. Most preferably the angle of surface  16   b  may be defined and/or configured according to the connection platform  114  of implant  100 . As shown, surface  16   c  extends from core formed by proximal portion  14  at the border with mediating portion  16 . Preferably surface  16   c  comprises an extension  16   d  extending from core proximal portion  14 . Surface  16   d  is substantially flat surface disposed substantially perpendicularly (about 90 degree angle) relative to the central axis of abutment  10  and/or abutment core. Surface  16   c  extends from surface  16   d  to form a down-sloping angle extending distally from surface  16   d  to form surface  16   c , characterized in that surface  16   c  is provided with an angle from of up to about 70 degrees formed relative to surface  16   d.    
         [0226]    Optionally the length and/or dimensions of surface  16   a ,  16   b ,  16   c  and  16   d  are configurable and may be adjusted relative to the size and dimensions of implant  100 , and/or at least one of connecting platforms  112 ,  114 ,  116 ,  118  and/or segment surface  110   a ,  110   b ,  110   c.    
         [0227]    For example as shown in  FIG. 7E  shows mediating portion  16  comprising an abutment surface  16   b  provided for coupling and/or interfacing with surface connection platform  116  (as previously described). Optionally and preferably abutment surface  16   b  is a substantially flat non-sloping surface that is substantially perpendicular (about 90 degrees) relative to the central axis of abutment  10  wherein surface  16   b  extends from the abutment core defined by distal portion  14  at the border defined between mediating portion  16 . Most preferably the contour and/or angle of surface  16   b  may be defined and/or configured according to the surface connection platform  116  of implant  100 . 
         [0228]      FIG. 7F  shows a cross sectional view of an optional abutment  10   c  that is configured to associate with the external surface of a coronal portion  110 , where the coronal portion is fit with threading  112  and for which abutment  10   c  comprises the corresponding threading  15   t  provided for coupling therewith. Preferably abutment threading  15   t  is disposed along an the internal surface of a coronal portion cavity  15   c , for example as shown. Optionally and preferably cavity  15   c  is configured to receive and couple with the coronal portion  110  of an implant  100  that features a coronal portion  110  having threading  112  disposed along at least a portion of its external surface. Optionally abutment  10   c  may further comprise a central bore  18  as previously described. 
         [0229]    Embodiments of the present invention provide a novel thread configuration for dental implant, for example as shown in  FIG. 8A-H . The thread and/or threading is configured to have at least one or more contour modification  140  relative to the horizontal axis  30   a  of the implant thread. The contour modifications may be disposed on at least one of the apical side  32  or coronal side  34  of the thread, relative to the thread&#39;s horizontal axis. The modifications  140  may be provided as a result of angulation that are defined along the horizontal axis  30   a.    
         [0230]      FIG. 8B-H  show schematic illustrative diagrams of exemplary dental implant threading  6  according to optional embodiments of the present invention.  FIG. 8B  shows an optional thread profile along the horizontal plane  30   a.    
         [0231]    As previously described with respect to  FIG. 1B  threading  6  includes an apical side  32 , a coronal side  34 , and a lateral edge  36  connecting the apical side and the coronal side, a base  30   b  connecting the thread to the core, a thread depth  30   d  defined between the lateral edge and the base. The thread depth  30   d  is defining along the medial-lateral axis (M-L) of the horizontal plane  30   a  of the thread; the adjacent threads defined between adjacent thread base  30   b  are connected over the external surface of an implant core  4  defining an inter-thread face  38 . 
         [0232]    The thread apical side  32  or thread coronal side  34  may be fit with at least one contour modification  140  along at least one axis of the horizontal plane  30   a , including the medial-lateral axis M-L axis as shown in  FIG. 8A  and/or the anterior-posterior axis A-P axis. Preferably contouring along at least one axis of the horizontal plane defines at least two sub-segments  142 , 144  along the horizontal plane  30   a , for example as shown in  FIG. 8B-H . 
         [0233]    As shown in  FIG. 8A  the contour modification may be realized along the M-L axis for example as shown in thread contour  140   m , or along the A-P axis as shown in thread contour  140   a.    
         [0234]    Optionally the thread may comprise at least one or more horizontal contour modifications  140 . Optionally there may be up to about five contour modifications  140  along the horizontal axis on either the apical side  32  or the coronal side  34  and along at least one axis of the horizontal plane. 
         [0235]    Optionally each contour modification may  140  assume a variable angle of up to about 180 degrees along each of the apical side  32  or coronal side  34 . 
         [0236]    Optionally the modification  140  may form a substantially symmetric thread surface along the thread, for example as shown in  FIGS. 8B and 8G . Optionally the thread surface may be configured to be substantially asymmetric for example as shown in  FIG. 8C-F . 
         [0237]    Optionally the horizontal plane modification  140  may be applied along at least one of apical side  32  or coronal side  34  and may be curved ( FIG. 8E-F ) and/or linear ( FIG. 8B-C ) or it may comprise a combination thereof for example as shown in  FIG. 8G . 
         [0238]    Optionally each additional contour modification  140  introduced along at least one axis of the horizontal plane increases the number individual sub-segment defined along the horizontal plane by at least one sub-segment  142 , 144 . 
         [0239]    Optionally at least one of the thread apical side  32  or the thread coronal side  34  may be individually fit with at least one and up to five contour modifications  140  along either the medial-lateral axis forming a modification  140   m  or along the anterior posterior axis  140   a.    
         [0240]    Optionally the implant  100  may be configured to include at least two threading  124 , wherein each may be individually configured to include at least one or more horizontal plane modification  140 . 
         [0241]    Optionally each of the plurality of threading  124  may be collectively and/or individually/independently configured along its horizontal plane  30   a  to include the at least one horizontal plane thread modification  140  in either the M-L axis or the A-P axis and along at least one of the thread apical side  32 , thread coronal side  34 , and/or thread lateral edge  36 . 
         [0242]    Optionally the contour modification  140  may define an angle of up to about 180 degrees relative to the horizontal plane  30   a.    
         [0243]    Optionally the thread may be configured to be symmetric about at least one axis of the horizontal plane  30   a.    
         [0244]    Optionally the thread may be configured to be asymmetric about at least one axis of the horizontal plane  30   a.    
         [0245]    Optionally at least one of: the thread apical side  32  or the thread coronal side  34  or the lateral edge  36 , may feature at least one recessed grooves  150 , for example as shown in  FIG. 8G . Optionally thread  124  may be fit with a plurality of recessed grooves  150 , for example as shown in  FIG. 8G . 
         [0246]    Optionally the recessed grooves  150  may assume any shape. 
         [0247]    Optionally at least one dimension of the recessed grooves ( 150 ) is configured to be from about 0.01 mm up to about 0.7 mm. 
         [0248]    Optionally the depth of thread  124  may be configured to be from about 0.1 mm up to about 2 mm. Optionally the inter-thread face  38  may be configured to assume any shape or angle. 
         [0249]    Optionally the inter-thread face  38  may for example include but is not limited to: contoured, curved, angled, linear, the like, or any combination thereof. 
         [0250]    Optionally the inter-thread face  38  may be substantially linear having an angle of up to about 60 degrees. 
         [0251]    Optionally the inter-thread face  38  may comprise a length of up to about 2 mm. 
         [0252]    Optionally at least one surface selected from: the thread apical side  32 , the thread coronal side  34 , the lateral edge  36 , the inter-thread face  38 , further comprise at least one outwardly extending extension  152 , for example as shown in  FIG. 8G . Optionally the threading may comprise a plurality of the outwardly extending extension ( 152 ). 
         [0253]    As shown in  FIG. 8A  the contour modification may be realized along at least one axis of the horizontal plane in at least one of M-L axis for example as shown in thread contour  140   m , or along the A-P axis as shown in thread contour  140   a.    
         [0254]      FIG. 8I  shows a horizontal plane contour modification  140   a ,  140   m  that is applied onto thread  124  forming an edge  122   e  that is pointed, for example as shown, provided for cutting, compacting and directing bone into flute  122 . Edge  122   e  is formed with two contour modifications  140   a ,  140   m  along the horizontal plane along the M-L axis and the A-P axis respectively, for example as shown. A first contour modification  140   a  is configured along the horizontal face  124   f  and a second contour modification  140   m  is configured along the coronal surface  124   c.    
         [0255]      FIG. 8J  shows a thread  124  similar to that shown in  FIG. 8I  where the thread coronal surface  124   c  is adjusted to introduce an undercut  140   c  to horizontal plane contour modification that is applied onto the M-L Axis. 
         [0256]      FIG. 8K  shows an optional thread  124  where a horizontal plane contour adjustment is effected along the A-P axis along the thread edge  124   f  wherein an undercut  140   c  is introduced along the thread face  124 , for example as shown. 
         [0257]      FIG. 8L-P  show optional horizontal plane thread modifications as previously described. 
         [0258]      FIG. 8L  shows an optional thread  124  having a flute edge  122   e.    
         [0259]      FIG. 8M  shows a similar thread  124  where edge  122   e , shown in  FIG. 8L  however further comprising a horizontal modification  140   m  to form a more pronounced angle at edge  122   e , wherein edge  122   e  forms an acute angle with respect to flute recess  122   r.    
         [0260]      FIG. 8N  shows a similar thread  124  where edge  122   e , as shown in  FIG. 8L-M  however further comprising a second horizontal modification in the form of modification  140   a  along edge  124   f  along the A-P axis. Optionally thread  124  may comprise a plurality of such contour modifications. 
         [0261]      FIG. 8O  shows a similar thread  124  where edge  122   e , shown in  FIG. 8M  however further comprising a horizontal modification along the M-L axis in the form of a curved undercut  140   c  producing a curved edge  122   e . Optionally such a curvature  140   c  may be provided for increased osseointegration. 
         [0262]      FIG. 8P  shows thread  124  having a further horizontal surface modification wherein edge  124   f  is provided with a dual curved surface therein forming a multipoint edge  122   e.    
         [0263]      FIG. 9A  show a schematic illustrative diagram of an optional dental implant  100  according to the present invention. Implant  100  comprises threading  130  that is configured to have horizontal contouring according to the present invention as previously described in  FIG. 8A-H .  FIG. 9A  further depicts an implant having a coronal section  110  having functional threads  114  for interfacing with cortical bone.  FIG. 9A  further shows coronal section  110  comprising recesses and/or grooves  115  along the surface of the thread  114 . 
         [0264]    Optionally implant  100  may be further customized with the coronal segment  110   b  to facilitate removal of coronal segment should it become necessary due to bone resorption. 
         [0265]      FIG. 9B  shows a schematic illustration of a cross sectional depiction of a coronal portion  110  according to the present invention, specifically showing the two connection interfaces and/or platforms  50 , 52  configured to receive an abutment  20  and optionally a retention screw as is necessary. 
         [0266]      FIG. 9C  shows an optional embodiment of the present invention for a dental implant having a coronal portion that are fit with at least one or more recessed grooves  115  along the coronal portion surface. Optionally this may be applied to any implant having a coronal segment. 
         [0267]    Optionally and preferably the coronal segment implant as previously described with respect to  FIG. 2-4 , featuring cortical cutting thread  124 , may be fit with the recessed grooves  115 . 
         [0268]    Optionally the coronal portion  110  may be fit with a plurality of recessed grooves  115 . Optionally recessed grooves  115  may be fit along coronal threading  112 . 
         [0269]    Optionally the recessed grooves  115  may assume any shape. 
         [0270]    Optionally the recessed grooves  115  are configured to have at least one dimension from about 0.01 to 0.5 mm. 
         [0271]    Optionally the shape of the recessed grooves may be selected from the group consisting of: oval, ovoid, ellipsoid, circular, quadrilateral, trapezoid, polygonal having n sides wherein n is at least three (n&gt;2), and any combination thereof or the like. 
         [0272]    Optionally the coronal portion ( 110 ) may feature at least one outwardly extending extension ( 115   e ). Optionally the coronal portion  110  may further comprise a plurality of the outwardly extending extension ( 115   e ). 
         [0273]      FIG. 10A-C  show schematic illustrative diagrams of optional embodiments of a dental tool according to an optional embodiment of the present invention. The tools are provided to facilitate removal of the coronal section of an implanted dental implant. 
         [0274]      FIG. 10A  shows an optional embodiment of a coronal portion removal tool  200 , the dedicated tool  200  provided for filing and or removing a coronal segment  110  of a dental implant  100 , the device featuring: a dental tooling connection interface  202  for coupling with a dental hand piece tool; a discoid tooling surface  204  having at least one surface or edge that may be coated with a medium provided for cutting and/or filing at least a portion of a dental implant  100 ; an implant interface portion  210  provided for inserting into a dental implant&#39;s borehole, the interface portion  210  including: a central body portion  212  for fitting within an implant&#39;s central borehole recess; a ring portion  214  for allowing the tool to freely rotate while associated with the implant borehole; and a distal end cap  216  for securely associating the tool with at least a portion of borehole portion and for sealing the implant borehole. 
         [0275]    Optionally the central body portion of device  200  may be configured to be vertically flexible or adjustable. Optionally the central body portion may be fit with a spring  212   s  to facilitate height adjustment. 
         [0276]    Optionally the central body portion may be configured to be telescopic. 
         [0277]    Optionally the central body portion may have an adjustable diameter. 
         [0278]    Optionally the central body portion comprises a core onto which a plurality of adapters may be fit so as to allow the central body portion to rotate freely within the dental implant central borehole. 
         [0279]    Optionally the ring portion  214  comprises ball bearings. 
         [0280]    Optionally the ring portion may comprises a friction reducing element to facilitate rotation. 
         [0281]    Optionally the distal end cap  216  may be provided from materials and/or coatings selected from the group consisting of: silicone, Teflon or the like. 
         [0282]      FIG. 10B-C  show an optional embodiment for a dental tool  220 , 230  provided for filing and/or facilitating the removal of a coronal segment  110  of an implanted dental implant  100 , the device featuring: a dental tooling connection interface  202  for coupling with a dental hand piece tool; a cylindrical tooling body  224 , 234  functionally coupled with the dental tooling interface  202  and configured to rotate when activated with the dental hand piece tool; the cylindrical tooling body  234 , 224  having at least one tooling surface or edge  236 ,  226   a ,  226   b  that may be coated with a medium provided for cutting and/or filing at least a portion of the coronal portion  110  of a dental implant  100 ; and a tooling stopping interface portion  238  provided for limiting the progressing of the cylindrical body  224 , 234  along the coronal segment of the implant. 
         [0283]    The tool depicted in  FIG. 10B  differs from the tool shown in  FIG. 10C  in the stopping interface utilized.  FIG. 10C  utilizes a borehole stopper  228  while  FIG. 10B  utilizes an implant body skirt stopper  238 . 
         [0284]    Optionally and more preferably the cylindrical tooling body  234 ,  224  may comprise an open lower surface configured to receive the coronal portion  110  of the implant  100 . 
         [0285]    Optionally the tooling surface or edge  236 ,  226   a ,  226   b  may be disposed along the inner surface of the cylindrical tooling body  234 , 224 . 
         [0286]    Optionally the tooling surface may be fit with an abrasive medium for milling and/or cutting the implant about the coronal portion. Optionally the medium may for example include but is not limited to mediums selected from: diamond dust, diamonds, diamond like carbon, the like or any combination thereof. 
         [0287]    Optionally the stopping interface portion  228  may be configured to associate with at least a portion of the coronal section  110  or the implant body  122 , 110   b , for example as depicted in  FIG. 10B . 
         [0288]    Optionally the stopping interface portion  228  may be provided in the form of a skirt that may be configured to fit an upper portion of an implant body  120 , wherein the skirt may be fit distally with the cylindrical tooling portion  234 , 224 . 
         [0289]    Optionally the stopping interface portion  238  may be provided in the form of an implant borehole adaptor provided to associated over an implant bore hole provided along the implant coronal segment  110 , for example as shown in  FIG. 10C . 
         [0290]      FIG. 11-12  show schematic illustrative diagram depicting an optional method according to embodiments of the present invention when a dental implant experiences bone resorption over the years following implantation, where portions of the implant are exposed over time due to bone loss around the implant and particularly the coronal segment of the implant. 
         [0291]      FIG. 11A  shows one optional method of treating such bone resorption by exposing and cleaning the coronal portion of the implant to the bone level and then coupling the exposed coronal segment with a new abutment  22  configured to associate therewith. 
         [0292]    Optionally the coronal portion  110  may be reconfigured and re-threaded with an optional dedicated tool for example as depicted in  FIG. 10B-C . 
         [0293]      FIG. 11B  shows an alternative approach in treating bone resorption as a results of a dental implant.  FIG. 11B  schematically shows the exposure of the coronal segment over, followed by exposure and preparing for the removal coronal segment  110 , while the implant remains is implanted within the bone. Optionally coronal portion  110  may be removed with any one of the optional tools depicted in  FIG. 10A-C . 
         [0294]    Similarly,  FIG. 12A-B  shows a schematic depiction of bone resorption over time at an implantation site. The coronal portion of the implant is first exposed and/or cleaned as is necessary and later the coronal portion is removed with a dedicated tool  220 ,  230 ,  200 .  FIG. 12B  shows additional abutment configuration  20  that may be coupled to the implant devoid of a conical portion for example as shown. 
         [0295]    Now referring to  FIG. 13-16  discussing optional embodiments of the present invention for a dental implant internal connection platform as shown in  FIG. 13-14 , a corresponding abutment as shown in  FIG. 14-15 , and a dedicate implant introducing tool as shown in  FIG. 16 . 
         [0296]      FIG. 13-16  show an dental implant, implant abutment and dedicated tool that are all interrelated by virtue of an internal conical interface platform that may be disposed on a dental implant and therefore requires a corresponding interface on any dental tool and/or structure that associates and/or interfaces with the implant. 
         [0297]      FIG. 13A-B  show optional embodiments of the present invention for an implant  1300  having an internal conical connection platform  1302 . Most preferably the dental implant  1300  has an internal conical connection platform  1302  along a borehole that is configured to receive a universal implant abutment  1320 ,  1330 . 
         [0000]    The internal connection platform  1302  is an internal borehole that extends distally from the proximal end of the implant  1300  at the coronal portion into the medial portion of the implant body. The internal connection platform  1302  is preferably centered along the implant body.
 
The implant connection platform  1302  preferably comprises a distal portion  1304 , a medial portion  1310  and a proximal portion  1305  that are fluid and continuous with one another.
 
         [0298]    Optionally and preferably the connection platform  1302  is characterized in that the proximal portion  1305  comprises a universal conical profile, therein allowing the connection platform  1302  to act as an interfacing and/or receiving platform for a universal abutment  1320  ( FIG. 14-15 ) for implants of various sizes and/or diameters. 
         [0299]    Most preferably connection platform  1302  comprises at least two anti-rotational interfaces, a first anti-rotational interface  1311  disposed along the medial portion  1310  and a second anti-rotational interface  1314  disposed along the proximal portion adjacent to the implant&#39;s proximal end  1302   p.    
         [0000]    Preferably the distal portion  1304  is a substantially cylindrical borehole featuring threading that is provided for coupling with a fixation screw as is known in the art. Preferably the medial portion  1310  defines an anti-rotation interface  1311  in the form of an anti-rotation tooling interface that is provided for manipulating the implant with tools, for example in the form of an internal hex as shown in  FIG. 13A-B . 
         [0300]    Optionally medial portion anti-rotation connection interface  1311  may be provided in any anti-rotational tooling interface as is known in the art for example including but not limited to at least one or more selected from the group consisting of internal six receptor sockets, scalloped, internal dodecagon, internal hex, internal octagon, internal spline, Morse taper, internal Morse taper, internal six lobe, internal tri lobe, internal six spline, internal thread, internal pentagon, internal square, internal five lobe, internal four lobe, internal three spline, internal eight spline, internal eight lobe, internal tube to tube plug in, triangular, polygonal of n sides where n&gt;=3 or more, the like as is known in the art or any combination thereof. 
         [0301]    Most preferably the proximal portion  1305  is provided in the form of a substantially conical borehole having a its small diameter at its distal end  1305   d  bordering the medial portion  1304  and a large diameter at the proximal end  1305   p  defined at the implants proximal end  1302   p.    
         [0000]    Optionally and preferably the conical borehole  1305  defines a wall that is provided with a uniform angle and/or slope along the length of the proximal portion  1305  from the distal end  1305   d  to the proximal end  1305   p , for example as shown in  FIG. 13B . 
         [0302]    Optionally the conical borehole  1305  may define a wall that is provided with at least two angles and/or slopes along the length of the proximal portion from the distal end to the proximal end, therein defining two proximal portion conical sub-segments  1306 ,  1308  that are continuous and fluid with one another, for example as shown in  FIG. 13A . Preferably the first segment  1306  is provided with a first angle and/or slope and the second segment  1308  is provided with a second angle and/or slope characterized in that the second angle and/slope is bigger than the first angle and/or slope relative to a common midline plane. 
         [0303]    Most preferably the proximal portion  1305  is fit with a second anti-rotation interface  1314  adjacent to the proximal end  1302   p . Most preferably, the second anti-rotation interface  1314  may be provided along the conical borehole surface and/or wall, for example as shown in  FIG. 13A . Preferably the second anti-rotation interface  1314  maintains the overall conical surface of the proximal portion  1305 . Most preferably the second anti-rotation interface  1314  is provided in the form of a plurality of inter-digitation recesses dispersed along proximal portion wall adjacent to the proximal end, for example as shown in  FIG. 13A-B . Optionally the recess  1314  may be configured to be horizontal or longitudinal along conical surface wall. Optionally and preferably the second anti-rotation interface  1314  may be provided in the form of a plurality of inter-digitation recesses dispersed along the conical borehole surface and/or wall. 
         [0304]    Optionally the second anti-rotation interface  1314  may be provided with at least two or more inter-digitation recesses, 
         [0305]    Optionally the internal connection platform borehole  1302  may further feature a circumferential recess  1316 ,  1312  and/or groove along at least one of the medial portion  1310  ( FIG. 13A ) and/or along the proximal portion  1305 . 
         [0306]    Optionally proximal portion  1305  may be fit with a circumferential recess  1316 , for example as shown in  FIG. 13B . Optionally the circumferential recess  1316  may be configured to receive an O-ring for facilitating sealing and/or secure coupling with optional dental implant structures for example including but not limited to abutments, healing caps, impression coping abutment, measuring abutments, tools or the like. 
         [0307]    Optionally medial portion  1304  may be fit with a circumferential recess  1312  and/or groove along its distal end that is adjacent to and/or bordering with the distal portion  1304 . 
         [0308]    Optionally the circumferential recesses  1316 ,  1312  may be configured to receive an O-ring (not shown) for facilitating sealing and/or secure coupling with optional dental structures for example including but not limited to abutments, healing caps, impression coping abutment, measuring abutments, tools or the like. 
         [0309]    Optionally medial portion  1310  may be fit with at least one or more recess  1312  and/or grooves along its distal end that is adjacent to and/or bordering with the distal portion  1304 . 
         [0310]      FIG. 14A-B  shows an optional embodiment of the present invention including a dental implant  1300  that is coupled and/or associated with an abutment  1320 , 1330  along the universal conical connection platform  1302 . 
         [0311]    Dental implant abutment  1330 , 1320  features an implant interface segment  1324 , 1334  and a crown interface segment  1332 ,  1322 . The abutment  1320 ,  1330  characterized in that the implant interface segment  1332 ,  1322  that is configured to be a universal abutment interface capable of fitting a plurality of dental implant of various diameters and/or sizes, for example a large diameter implant  1300   a  or a medium sized diameter implant  1300   b , or a small diameter implant  1300   c . The abutments  1330 ,  1320  according to an optional embodiment of the present invention is configured to be a universal abutment that is capable of coupling and/or interfacing with various implants of different diameters, for example shown. 
         [0312]    The abutment  1320 , 1330  may comprises at least one anti-rotational connection  1328 ,  1338  defining a first anti-rotational connection that is disposed along the distal part of the implant interface segment  1324 ,  1334 , for example as shown. 
         [0313]    Preferably the implant interface segment  1324 ,  1334  includes a distal portion  1328 , 1338  and a proximal portion  1335 , the distal portion provided in the form of an anti-rotational interface and provided for matching the implant&#39;s anti-rotational interface. 
         [0314]    Optionally the abutment may comprise at least two anti-rotational connection platforms a first anti-rotational connection platform disposed along the distal portion of the implant interface segment and a second anti-rotational connection platform disposed along the proximal portion of the implant interface segment. Optionally at least one of the two anti-rotational connection platforms may be provided in the form of inter-digitation connectors. Optionally both of the two anti-rotational connection platforms may be provided in the form of male inter-digitation connectors. 
         [0315]    Optionally the distal portion&#39;s anti-rotational interface may be fit with a snap fit male connector for example including but not limited to a cog and/or flange and/or extension, the like or any combination thereof. Most preferably the snap fit male connector is provided to fit and securely couple with a corresponding female connector and/or recess disposed along an implant connection platform. 
         [0316]    The abutment characterized in that the proximal portion of the abutment&#39;s implant interface segment features an external surface having conical profile that is widest at its proximal end adjacent and/or bordering with the abutment&#39;s crown interface segment, and configured to be narrowest adjacent to and/or bordering with the distal portion of the abutment&#39;s implant interface segment. 
         [0317]    Optionally and preferably the proximal portion&#39;s conical external surface defines a wall that is provided with a uniform angle and/or slope along the length of the abutment&#39;s implant interface segment&#39;s proximal portion. 
         [0318]    Optionally proximal portion&#39;s conical external surface defines a wall that is provided with at least two angles and/or slopes along the length of the proximal portion, therein defining two proximal portion sub-segments that are conical and continuous with one another. Preferably the first sub-segment is provided with a first angle and/or slope and the second segment is provided with a second angle and/or slope characterized in that the second angle and/slope is bigger than the first angle and/or slope relative to a common midline plane. 
         [0319]    Optionally the abutment comprises a central borehole configured to receive a fixation screw, as is known in the art. 
         [0320]    Optionally the abutment may feature an integrated fixation screw portion disposed distal to the implant interface segment. Preferably the integrated fixation screw portion is provided for coupling with an implant along its threaded borehole. 
         [0321]      FIG. 15A  shows abutment  1320  having two anti-rotation connection platforms that are provided in the form of an inter-digitation. 
         [0322]      FIG. 15B  shows abutment  1320  having one anti-rotation connection in the form of a snap fit male connector interface  1328 . 
         [0323]      FIG. 15C  shows an optional abutment according to the present invention where the abutment is configured to associate within an implant borehole along the external conical surface wall. 
         [0324]      FIG. 15D-E  show a universal abutment according to the present invention that is further configured to couple with at least one connection platform provided along the coronal portion  110 , for example as shown in  FIG. 6  and as previously described. 
         [0325]      FIG. 15F  shows an impression copying abutment that is fit with the conical interface according to embodiments of the present invention, therein providing a universal impression copying abutment that may be associated and/or fit with a plurality of implants of different sizes. 
         [0326]      FIG. 15G  shows an healing cap that is fit with the conical interface according to embodiments of the present invention, therein providing a universal impression copying abutment that may be associated and/or fit with a plurality of implants of different sizes. 
         [0327]    Optionally the universal conical interface according to embodiments of the present invention may be provided and/or fit on optional forms of dental tools, and/or devices that interface with an implant having the internal conical platform  1302  according to optional embodiments of the present invention. 
         [0328]      FIG. 16  shows an optional embodiment of the present invention showing a dedicated dental tool  1350  for associating with and manipulating and/or tooling and/or maneuvering a dental implant  1300  according to embodiments of the present invention. The device  1350  features a dental tooling connection interface  1352  for coupling with a dental hand piece tool that may be utilized to rotate a dental implant associated with the tool; 
         [0329]    a tooling body comprising a proximal portion  1355 , medial portion  1358  and a distal portion  1360 . As shown the proximal portion  1355  is disposed distal to and is continuous with the tooling connection interface  1352 . Most preferably the proximal portion  1355  defines a conical body having a proximal end  1355   p  and a distal end  1355   d  where the proximal end is configured to be wider than the distal end. 
         [0330]    The medial portion  1358  is disposed distal to the proximal portion  1355  and is fluid therewith, the medial portion  1355  is provided in the form of an anti-rotation interface for example including but not limited to a hexagon profile, for example as shown. 
         [0331]    The distal portion  1360  is disposed distal to the medial portion  1358  and is fluid therewith, preferably the distal portion  1360  is configured to have a smaller diameter than that of the medial portion so as to allow for entering into the dental implant borehole. 
         [0332]    Optionally the medial portion may substantially cylindrical. 
         [0333]    Optionally the dental implant insertion tool  1350  may be configured to have a hollow flow channel (not shown) along its length so as to facilitate fluid flow therethrough for example for conducting a flowing fluid such as a fluid and/or gas. For example, the hollow flow channel may be utilized to couple with a suction port to facilitate creating of suction at the distal end. For example the hollow flow channel may be utilized for introducing a flowing fluid such as water and/or saline and/or gas and/or air through the distal end. 
         [0334]    The conical body proximal portion  1355  features a plurality of inter-digitation male connects  1356 , as shown, that are disposed adjacent to the proximal end  1355   p . Most preferably the conical body  1355  comprises at least two inter-digitation male connectors  1356  extending form the external surface and are provided for associating with corresponding female inter-digitation connectors disposed on an implant  1300  internal connection interface  1302  as previously described in  FIG. 13-14 . Preferably the plurality of male inter-digitation connectors  1356  may be distributed evenly along the external surface of the conical body. 
         [0335]    Optionally the proximal portion  1355  may comprise from two and up to about six inter-digitation male connectors. 
         [0336]    Optionally the proximal portion  155  may be provided from at least two or more conical sub-segments  1354 ,  1356  that are continuous and fluid with one another. Preferably each conical sub-segment forming the proximal portion are arranged such that the proximal portion maintains a substantially conical profile arrangement that is increasing diameter in the proximal direction, therein the distal sub-segment  1354  is the narrowest while the proximal sub-segment  1356  is the widest. Preferably a first (distal) sub-segment  1354  may be provided with a first angle and/or slope and the second (proximal) sub-segment  1356  may be provided with a second angle and/or slope characterized in that the second angle and/slope is larger than the first angle and/or slope relative to a common midline plane. 
         [0337]    Optionally medial portion  1358  may be configured to have any anti-rotational configuration to match that distal anti-rotational platform of a dental implant  1300  for example including but not limited to at least one or more selected from the group consisting of internal six receptor sockets, scalloped, internal dodecagon, external dodecagon, internal hex internal, external hex, external octagon, internal octagon, external spline, internal spline, Morse taper, internal Morse taper, one piece, internal six lobe, external six lobe, internal tri lobe, external tri-lobe, internal six spline, external six-spline, internal thread, internal pentagon, external pentagon, external thread, internal square, external square, internal five lobe, internal four lobe, internal three spline, external triangle, internal eight spline, external six lobe, internal eight lobe, internal tube to tube plug in, triangular, polygonal of n sides where n&gt;=3 or more, the like as is known in the art or any combination thereof. 
         [0338]    While the invention has been described with respect to a limited number of embodiment, it is to be realized that the optimum dimensional relationships for the parts of the invention, to include variations in size, materials, shape, form, function and manner of operation, assembly and use, are deemed readily apparent and obvious to one skilled in the art, and all equivalent relationships to those illustrated in the drawings and described in the specification are intended to be encompassed by the present invention. 
         [0339]    Therefore, the foregoing is considered as illustrative only of the principles of the invention. Further, since numerous modifications and changes will readily occur to those skilled in the art, it is not described to limit the invention to the exact construction and operation shown and described and accordingly, all suitable modifications and equivalents may be resorted to, falling within the scope of the invention. 
         [0340]    Having described a specific preferred embodiment of the invention with reference to the accompanying drawings, it will be appreciated that the present invention is not limited to that precise embodiment and that various changes and modifications can be effected therein by one of ordinary skill in the art without departing from the scope or spirit of the invention defined by the appended claims. 
         [0341]    It is appreciated that certain features of the invention, which are, for clarity, described in the context of separate embodiments, may also be provided in combination in a single embodiment. Conversely, various features of the invention, which are, for brevity, described in the context of a single embodiment, may also be provided separately or in any suitable sub-combination or as suitable in any other described embodiment of the invention. Certain features described in the context of various embodiments are not to be considered essential features of those embodiments, unless the embodiment is inoperative without those elements. 
         [0342]    Although the invention has been described in conjunction with specific embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, it is intended to embrace all such alternatives, modifications and variations that fall within the scope of the appended claims. 
         [0343]    Citation or identification of any reference in this application shall not be construed as an admission that such reference is available as prior art to the invention. 
         [0344]    Section headings are used herein to ease understanding of the specification and should not be construed as necessarily limiting. 
         [0345]    While the invention has been described with respect to a limited number of embodiments, it will be appreciated that many variations, modifications and other applications of the invention may be made.