Abstract:
The improved endoprosthetic device surface treatment encourages soft tissue attachment thereto. A porous mesh surface treatment creates on an outer surface of the endoprosthetic device a three-dimensional surface structure similar to cancellous bone. Suture attachment features are provided at various locations around the treated surface structure to initially affix a vascularized soft tissue to the treated surface. As the patient heals the soft tissue grows and infiltrates the porous mesh surface to achieve an attachment strength substantially equal to the surrounding tissue.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
       [0001]    This application is a continuation of U.S. patent application Ser. No. 14/680,897, filed on Apr. 7, 2015. 
     
    
     STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT 
       [0002]    Not Applicable 
       THE NAMES OF THE PARTIES TO A JOINT RESEARCH AGREEMENT 
       [0003]    Not Applicable 
       INCORPORATION-BY-REFERENCE OF MATERIAL SUBMITTED ON A COMPACT DISC 
       [0004]    Not Applicable 
       BACKGROUND OF THE INVENTION 
       [0005]    1. Field of the Invention 
         [0006]    The present invention relates to orthopedic implant technology and, more specifically, to surface treatment of endoprosthetic devices that allows for soft tissue attachment thereto. 
         [0007]    2. Description of Related Art Including Information Disclosed Under 37 CFR 1.97 and 1.98 
         [0008]    In human patients, disease or extreme trauma can sometimes necessitate the repair or replacement of a portion or all of the bones and/or joints that comprise a patient&#39;s arm or leg. For example, a tumor that affects the proximal portion of a patient&#39;s humerus can require resection of the diseased portion and fixation of a humeral prosthesis that attempts to duplicate the functionality of the original humerus. Such an endoprosthetic device may typically include the humeral head, shaft, and even the elbow joint, with affixation at the distal end via a shaft feature that is cemented into a borehole formed within the remaining ulna or radial bone of the patient. While such extreme limb-salvage surgical repairs are made nowadays on a somewhat routine basis, existing prosthetic device technology falls short with regard to duplication of the range of movement of the original joints. Consequently, patients are typically left with limited functionality of the replaced anatomy due to limited range of motion. Moreover, patients with such repairs, who attempt arm movements to the limits of these prosthetic devices often weaken or damage the affixation site and may even cause dislocation of the shoulder joint, resulting in additional trauma to the bone and surrounding soft tissue. 
         [0009]    The instant inventor made tremendous advances in orthopedic implant technology with his invention disclosed in PCT Application No. PCT/US2011/056393 entitled “Modular Humeral Prosthesis With Spherocentric Feature,” filed on Oct. 14, 2011, the disclosure of which is incorporated by reference herein for all purposes. As the title states, this invention discloses a modular humeral prosthesis having a new and unique spherocentric elbow joint that allows full supination and pronation of the patient&#39;s hand post-recovery. However, as with this and other current humeral prostheses it was discovered that upon repeated medial and lateral rotation of the patient&#39;s repaired arm excessive torsional stresses were imparted on the humeral prosthesis shaft. In the case of complete shoulder repairs the excessive torsional stresses resulted in full separation and dislocation of the shoulder joint with resultant damage to the joint and surrounding soft tissue. In the case of partial humerus repair the excessive torsional stresses resulted in “windshield wiper” loosening of the cemented stem from the fixation site. 
         [0010]    In addition, successful attachment and integration of soft tissue to this and other endoprosthetic devices has been elusive. To reattach a forcefully contracting muscle to an inert endoprosthesis has currently required use of an artificial tendon or other point-type anchoring device. Such artificial tendons and anchoring devices do not afford optimal integration of the tendon to the prosthesis, which would spread the forces of muscle contraction over a greater area for optimal strength. Instead, the forces are concentrated in the artificial anchoring device, resulting in a weaker interface that causes patient discomfort or pain if the muscle separates completely from the anchor. What is needed is an endoprosthetic surface treatment and method for soft tissue attachment thereto that affords integration similar to the normal tendo-osseous junction. The instant invention addresses these shortcomings and others as will be understood by one of ordinary skill upon a thorough study of the embodiments described herein. 
       BRIEF SUMMARY OF THE INVENTION 
       [0011]    The present invention is embodied in numerous forms, including an embodiment of an endoprosthetic device comprising: a body segment having a defined outer surface comprising: a plurality of suture attachment features, the suture attachment features adapted to accept a tendon suture for affixation of a tendon thereto; and a porous mesh surface, the pores of which are adapted to encourage the growth and infiltration of tendon collagen fibers for formation of an enthesis. An additional embodiment of the suture attachment features comprises a through-hole feature for passage of the tendon suture therethrough. In another embodiment the porous mesh comprises a three-dimensional structure forming the pores, while in another the porous mesh comprises a three-dimensional structure forming the pores, wherein the porosity is in the range of approximately 600 to 800 microns in size. In yet another embodiment the porous mesh comprises a three-dimensional structure forming the pores, wherein the three-dimensional structure is formed using thermal deposition of biocompatible metal. Another embodiment of the porous mesh comprises a three-dimensional structure forming the pores, wherein the three-dimensional structure is formed using trabecular metal. 
         [0012]    The present invention is also embodied in a method for soft tissue attachment to an endoprosthetic device, the method steps comprising: providing an endoprosthetic device having a body segment with a defined outer surface comprising: a plurality of suture attachment features, the suture attachment features adapted to accept a tendon suture for affixation of a tendon thereto; and a porous mesh surface, the pores of which are adapted to encourage the growth and infiltration of tendon collagen fibers for formation of an enthesis; and affixing a sutured tendon end to at least one of the suture attachment features, wherein the tendon end is maintained in direct contact with the porous mesh surface for growth and infiltration of the tendon collagen fibers therein. In another embodiment the suture attachment features comprise a through-hole feature for passage of the tendon suture therethrough. In another embodiment the porous mesh comprises a three-dimensional structure forming the pores. In another embodiment the porous mesh comprises a three-dimensional structure forming the pores, wherein the porosity is in the range of approximately 600 to 800 microns in size. In another embodiment the porous mesh comprises a three-dimensional structure forming the pores, wherein the three-dimensional structure is formed using thermal deposition of biocompatible metal. In yet another embodiment the porous mesh comprises a three-dimensional structure forming the pores, wherein the three-dimensional structure is formed using trabecular metal. 
     
    
     
       BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING(S) 
         [0013]    The present invention will be more fully understood by reference to the following detailed description of the preferred embodiments of the present invention when read in conjunction with the accompanying drawings, wherein: 
           [0014]      FIG. 1  is an exploded perspective view of a first embodiment of a modular rotational component of the present invention; 
           [0015]      FIG. 2  is a close-up perspective view of the lobe ring utilized in the rotational component embodiment; 
           [0016]      FIG. 3  is an assembled perspective view of the rotational component embodiment; 
           [0017]      FIG. 4  is an exploded perspective view of an embodiment of a modular humeral prosthesis lower extremity component incorporating an embodiment of the rotational component; 
           [0018]      FIG. 5  is an assembled perspective view of the embodiment; 
           [0019]      FIG. 6  is an exploded view of a forearm component for completion of a humeroulnar/humeroradial articulation with the disclosed embodiment; 
           [0020]      FIG. 7  is an embodiment of a modular spacer for use with the modular humeral prosthesis as disclosed herein; 
           [0021]      FIG. 8  is an embodiment of the modular spacer with surface treatment for soft tissue attachment; 
           [0022]      FIG. 9  is another embodiment of the modular spacer with surface treatment for soft tissue attachment; 
           [0023]      FIG. 10  is an embodiment of a complete modular humeral prosthesis with rotational component, and featuring a reverse shoulder upper extremity and humeroulnar/humeroradial articulation; 
           [0024]      FIG. 11  is an embodiment of a partial modular humeral prosthesis with rotational component, and featuring a normal shoulder upper extremity; 
           [0025]      FIG. 12  is an embodiment of a partial modular humeral prosthesis with rotational component, and featuring a humeroulnar/humeroradial articulation; and 
           [0026]      FIG. 13  is an embodiment of a partial modular femoral prosthesis with rotational component, and featuring a normal femoral head. 
       
    
    
       [0027]    The above figures are provided for the purpose of illustration and description only, and are not intended to define the limits of the disclosed invention. Use of the same reference number in multiple figures is intended to designate the same or similar parts. Furthermore, if and when the terms “top,” “bottom,” “first,” “second,” “upper,” “lower,” “height,” “width,” “length,” “end,” “side,” “horizontal,” “vertical,” and similar terms are used herein, it should be understood that these terms have reference only to the structure shown in the drawing and are utilized only to facilitate describing the particular embodiment. The extension of the figures with respect to number, position, relationship, and dimensions of the parts to form the preferred embodiment will be explained or will be within the skill of the art after the following teachings of the present invention have been read and understood. 
       DETAILED DESCRIPTION OF THE INVENTION 
       [0028]    The following invention makes reference to the glenohumeral articulation (shoulder joint), the humeroulnar/humeroradial articulation (elbow joint), the acetabulofemoral articulation (hip joint), and the tibiofemoral/patellofemoral articulation (knee joint) of a patient. With regard to a humerus, the proximal articulation refers to the glenohumeral articulation and the respective distal articulation refers to the humeroulnar/humeroradial articulation. With regard to a femur, the proximal articulation refers to the acetabulofemoral articulation and the respective distal articulation refers to the tibiofemoral/patellofemoral articulation. 
         [0029]      FIG. 1  presents an exploded perspective view of a first embodiment of a modular rotational component as described herein and as utilized in the accompanying claims. As depicted, the modular rotational component ( 100 ) in this embodiment includes a machined axial component having a male threaded coupler feature ( 102 ) that is part of an elongated stem feature ( 104 ). The stem feature ( 104 ) centers the axial component within a mating passage of a machined housing component at a proximal end ( 110 ). 
         [0030]    The housing component proximal end ( 110 ) features a through-hole axial bore within which a proximal sleeve ( 108 ) is located. The proximal sleeve ( 108 ) in this embodiment utilizes ultra-high molecular weight polyethylene (UHMWPE), but may be made from any other friction-reducing biocompatible polymer. The proximal sleeve ( 108 ), likewise, has a through-hole axial bore within which the stem feature ( 104 ) is positioned. A lip on the proximal sleeve ( 108 ) prevents the assembled axial component from directly contacting the housing component ( 110 ), thereby reducing rotational friction of the components relative to one another. 
         [0031]    The stem feature ( 104 ) further extends into the distal end of the housing component ( 112 ), which includes an additional axial bore section within which a distal sleeve ( 114 ) is located. As with the proximal sleeve ( 108 ), the distal sleeve ( 114 ) utilizes UHMWPE as a friction-reducing and biocompatible bearing for rotation of the stem ( 104 ) relative the housing ( 110 ). The distal end of the stem feature ( 104 ) is drilled and tapped to accept a threaded fastener ( 118 ). The threaded fastener in this embodiment is a hex fastener ( 118 ), which allows for easier manufacturability due to the positive engagement of hex wrench tools, but may be any fastener known in the art. The use of a thread locking material ensures positive retention of the fastener ( 118 ) when affixed within a patient. 
         [0032]    The fastener ( 118 ) also retains a lobe ring ( 116 ) on the end of the stem ( 104 ). The lobe ring ( 116 ) fits within a mating groove feature ( 120 ) within the distal end of the housing ( 112 ), and is designed to provide a positive and gradual stop to rotation of the stem ( 104 ) to prevent over-rotation.  FIG. 2  is a close-up perspective view of the lobe ring ( 116 ) in the present embodiment, showing the features that prevent this over-rotation. As shown, the lobe bottom ( 206 ) is essentially circular, with the lobe top ( 202 ) extended in the “Y” direction. Within the mating groove ( 120 ) the lobe top ( 202 ) positively engages the mating groove ( 120 ) at each extreme of rotation, preventing further rotation (or “over-rotation”). Gradual ramps ( 204 ) are included to ease the transition to the lobe top ( 202 ), which slow the rotation within the groove ( 120 ), thereby preventing “hammering” impulse of the rotational component during rapid and full rotation of the prosthesis by the patient. Positive locating flats ( 208 ) in the bore of the lobe ( 116 ) mate with flats ( 106 ) on the stem feature ( 104 ) to prevent rotation of the lobe ( 116 ) with respect to the stem ( 104 ). Another embodiment might utilize a lobe ring with a simple tab feature and no ramps, but hammering of the rotational component might result. 
         [0033]    In another embodiment the lobe ring ( 116 ) does not utilize a physical rotation stop. Inside the patient, this embodiment allows the stem ( 104 ) to rotate to the fullest extent allowed by the patient&#39;s soft tissue. This can be advantageous because it prevents the harsh rotational stop “hammering” impulses that might be perceived by the patient as with the previous embodiment. The stops may be removed from within the groove ( 120 ), or the ramps may be removed from the lobe ring, making the lobe ring more circular in shape. 
         [0034]    The machined axial component, the housing component, and all other metal components of the embodiment are manufactured from biologically compatible and stable metals. In the instant embodiment the axial and housing components are titanium, but may be surgical stainless steel, niobium, gold, platinum, or the like. Moreover, combinations of metals and/or biocompatible polymers may also be utilized and are within the scope of the claimed invention. Internal components, likewise, are manufactured from these same metals and/or polymers. For example, the lobe ring component ( 116 ) of the present embodiment is manufactured from UHMWPE to reduce impulse forces that can result from rapid rotation of the device to a limit. However, metals may also be utilized to improve the wear resistance of the component. In another embodiment the comprises a combination of metal and polymer coating on the outer wear surface to soften the impulse. Yet another embodiment may utilize a polymer body with a metal layer on the outer wear surface to improve the wear characteristics while providing a reduction in impulse. 
         [0035]      FIG. 3  is an assembled perspective view of the embodiment showing the modular rotational component ( 100 ) in its assembled form, as it would be utilized to complete a torsionally stabilized humeral or femoral prosthesis. A male threaded coupler ( 202 ) and a female threaded coupler ( 202 ) feature allow for the attachment of additional endoprosthetic components. For example, modular spacers, intramedullary stems, and joint components necessary to construct a complete endoprosthetic may be attached. Further, other embodiments of the modular rotational component ( 100 ) might feature only male threaded couplers or female threaded couplers, or might have the two reversed from that of the present embodiment. Hexagonal features ( 306 ) are provided to allow the use of an open-end wrench when assembling other prosthesis components to the embodiment. 
         [0036]    The modular rotational component in other embodiments may include combined joint features. For example,  FIG. 4  presents an exploded perspective view of an embodiment of a modular distal humeral prosthesis component incorporating an embodiment of the rotational component. The machined axial component ( 402 ) is visible, along with the stem feature ( 404 ) and proximal sleeve ( 408 ) as in the previous embodiment. However, in this embodiment the distal humeral component housing ( 410 ) provides the through-hole axial bore that accepts the proximal sleeve ( 408 ) and stem ( 404 ). A distal sleeve ( 412 ) is located within a housing groove, as is a lobe ring ( 414 ). A fastener ( 418 ) and washer ( 416 ) retain the lobe ring on the stem ( 404 ), with flats ( 406 ) on the stem positively locating the lobe ring ( 416 ) within the housing groove ( 420 ). Completing the distal humeral component ( 400 ) are axle sleeves ( 422 ) for supporting an joint axle ( 424 ) within the housing distal end. The axle sleeves ( 400 ), as with the proximal and distal sleeves ( 408  and  412 ), are UHMWPE construction to reduce friction during rotation.  FIG. 5  is an assembled perspective view of this embodiment. 
         [0037]    To complete the construction of a humeral prosthesis with a humeroulnar articulation, it is helpful to describe the component that, when combined with the previous embodiment, may form the humeroulnar articulation.  FIG. 6  is an exploded view of a forearm component for completion of a humeroulnar/humeroradial articulation with the disclosed invention. As shown, an intramedullary ulnar stem ( 620 ) features longitudinal grooves ( 618 ) extending from the distal end to the proximal end of the stem for rotational stability when cemented into the patient&#39;s ulna or radius. Also featured is a taper segment ( 616 ) that is also coated with a means for apposition of bone (i.e., texture or chemical treatment). The proximal end of the ulnar stem ( 620 ) includes a shaft segment ( 614 ) that fits within and passes through a first thrust sleeve ( 610 ) and a second bearing sleeve ( 606 ), and ultimately engages within the positive engagement flats ( 612 ) of a lobe ring ( 604 ). A lobe ring fastener ( 602 ) engages the ulnar stem shaft ( 614 ) and retains the assembly. The sleeves ( 610  and  606 ) fit within machined recesses within the elbow assembly ( 600 ) body. The first thrust sleeve ( 610 ) features a thrust surface that minimizes friction between the ulnar stem taper ( 616 ) and the elbow assembly body ( 698 ). The thrust surface is comprised of the same plastic as the sleeve ( 610 ). However, the thrust surface may also be comprised of a suitable medical grade metal or polymer different from that of the sleeve. 
         [0038]    To afford rotation and to minimize friction while doing so, the ulnar stem shaft ( 614 ) utilizes similar materials as the articulating surfaces. For example, the shaft may be coated with cobalt chrome, pyrocarbon, ceramic, or other medical-grade, corrosion inhibiting, friction-reducing material. Likewise, the plastic sleeves ( 610  and  606 ) may utilize a medical-grade polymer, including UHMWPE, to reduce friction. 
         [0039]    The lobe ring ( 604 ) in this embodiment is similar in form and function to the previously discussed lobe ring. As shown, a positive engagement feature is provided that mates (or interlocks) with a related feature ( 612 ) on the ulnar stem shaft ( 614 ), causing the lobe ring and ulnar stem to rotate in unison. A tab feature ( 624 ) on the outer radius of the lobe ring ( 604 ) moves within a rotational groove feature ( 622 ) in the body ( 608 ) and serves to limit the degree of rotation within the elbow assembly body ( 608 ). In this embodiment the groove ( 622 ) is machined within the elbow assembly body ( 608 ) and is sized to allow the ulnar stem ( 620 ) to rotate approximately 180 degrees to approximate the normal range of rotational motion of a patient&#39;s wrist and hand, with the tab feature ( 624 ) contacting the ends of the groove feature ( 622 ) as in previous embodiments. The overall range of motion may be adjusted by changing the overall length of the rotational groove ( 622 ) to either increase or decrease this range (i.e., greater than or less than 180 degrees). Further, in another embodiment, the lobe ring is a machined feature of the ulnar stem shaft ( 420 ). 
         [0040]      FIG. 7  is an embodiment of a modular spacer for use with the modular humeral prosthesis as disclosed herein. The overall length of the space ( 700 ) allows the surgeon to size the resulting humeral prosthesis to fit the patient&#39;s anatomy. For example, a surgery center might maintain modular spacers in various lengths—10 mm to 50 mm—that afford the ability to tailor the length of the repair in 10 mm increments to fit the patient. 
         [0041]    The proximal end of the spacer features a Morse taper ( 702 ) followed by threads ( 704 ) for engaging a mating female end on another spacer. The Morse taper is a common machined taper that is used to positively join machined components. The proximal end ( 708 ) of the body of the spacer includes holes ( 706 ) for suture attachment of soft tissue. As with the modular rotational component embodiments, the body includes a hex feature ( 712 ) for engagement by an open ended wrench of appropriate size, which is used during assembly of the modular components. The distal end ( 710 ) features a complimentary female threaded coupler (not visible) for engaging with the male threaded coupler (see  702 / 704 ) of another spacer or rotational component. 
         [0042]      FIG. 8  is an embodiment of the modular spacer with surface treatment for soft tissue attachment. The proximal ( 802 ) and distal ( 804 ) body segments provide through-hole suture attachment features ( 806 ) and also includes a porous mesh surface treatment ( 808 ).  FIG. 9  presents yet another embodiment of the modular spacer with surface treatment for soft tissue attachment. In this embodiment the spacer provides only female thread couplers ( 902 ) for attachment. Visible once more are the suture attachment through holes ( 904 ) and surface texture ( 906 ), and hex wrench feature ( 908 ). The porous mesh surface treatment creates a three-dimensional surface structure that is similar to cancellous bone, and which encourages the attachment of soft tissue. The porous mesh surface treatment is created using the known process for creating common trabecular metal, albeit with a greater porosity. For example, the surface texture may be created by thermal deposition in which the texture is effectively “printed” onto the surface atom-by-atom. Biocompatible materials, including tantalum, may be utilized in this process to create the three-dimensional surface texture structure. In the instant invention it has been shown that a surface texture porosity of approximately 600 to 800 microns encourages soft tissue attachment to treated implants. Suturing the soft tissue to the suture attachment features ( 906 ) allows the soft tissue to affix to the surface structure ( 906 ) as the patient heals. 
         [0043]    A successful limb-sparing procedure for oncological purposes can be divided into three stages. The first stage involves tumor resection, and must spare significant tissue structures to support reconstruction while obtaining adequate oncologic margin to eliminate diseased tissue. The second stage involves the affixation of a stable, painless skeletal reconstruction (typically an endoprosthetic device). Third, the surrounding and supporting soft tissue is required to restore functionality to the skeletal reconstruction. The performance of the first two steps of this procedure is well understood, so it is not necessary to provide such detail herein. However, the endoprosthetic device and its use disclosed herein have heretofore never been contemplated. 
         [0044]      FIG. 10  presents an embodiment of a complete modular humeral prosthesis with rotational component, and featuring a reverse shoulder upper extremity and humeroulnar/humeroradial articulation ( 1000 ). The metaphyseal segment ( 1002 ) in this embodiment provides a spherical insert for engagement with a metal ball fixated within the glenoid cavity of the patient. The shaft is comprised of any number and size of modular spacers ( 800 ,  900 ) necessary to achieve the correct length for the repair. The lower extremity ( 400 ) features a rotational component ( 1006 ) as previously described, as well as a forearm component ( 600 ) to form the humeroulnar articulation. The intramedullary stem ( 1004 ) is affixed within an axial borehole in the ulna or radius of the patient. Normally during surgery the intramedullary stem ( 1004 ) is affixed to the patient&#39;s ulna. Following resection of the appropriate length of the ulna, the medullary canal is reamed to receive the stem ( 1004 ) to a depth up to the stem taper and is packed with cement. If the prosthetic device is being fixated in the patient&#39;s right arm, the stem ( 1004 ) is rotated counterclockwise as viewed from the distal end to the stop of its rotation and, with the patient&#39;s palm facing skyward, the stem is inserted into the medullary canal. The longitudinal channels of the ulnar stem in conjunction with the cement provide rotational stability within the ulna. If the patient&#39;s ulna is not serviceable, then the device may also be affixed to the patient&#39;s radius in the same fashion. 
         [0045]    To complete the procedure (third stage) it is necessary to reattach the surrounding and supporting soft tissue to the prosthesis. The present embodiment provides a porous mesh surface treatment and strategic suture attachments to effect reattachment. For example, the subscapularis must be reattached to the area of the prosthetic device that represents the lesser tuberosity of the original humerus ( 1006 ). The subscapularis tendon is affixed to a suture attachment feature in this area ( 1006 ) and, over time, the tendon collagen fibers anchor the tendon into the porous mesh surface treatment present at this enthesis. Likewise, the pectoralis major must be reattached to the area of the prosthetic device that represents the lateral lip of intertubercular groove of original humerus ( 1008 ). Accordingly, the pectoralis major tendon is affixed to a suture attachment feature in this area ( 1008 ) and, over time, these tendon collagen fibers anchor the tendon into the porous mesh surface treatment present at this enthesis. This is repeated for the remaining muscles, including the rotator cuff muscles, triceps, brachialis, and brachioradialis ( 1010 ). 
         [0046]      FIG. 11  is an embodiment of a partial modular humeral prosthesis with rotational component, and featuring a normal shoulder upper extremity. This configuration may be used in instances in which resection of a diseased proximal portion of a humor leaves sufficient shaft length for insertion and affixation of an intramedullary stem ( 1104 ) through common means. The metaphyseal segment ( 1102 ) includes a ball component ( 1106 ) for engagement with the glenoid process of the patient, or with a glenoid prosthetic device. A rotational component ( 100 ) as described herein is also included, with the rotational aspect nearest to the stem ( 1104 ). It is possible to add additional modular spacers ( 1108 ) to establish the proper length of the repair to ensure symmetry with regard to the patient&#39;s arms. 
         [0047]      FIG. 12  is an embodiment of a partial modular humeral prosthesis with rotational component, and featuring a humeroulnar/humeroradial articulation. This endoprosthetic device configuration ( 1200 ) may be used in instances in which the humeroulnar/humeroradial articulation must be resected due to disease, yet the glenohumeral articulation is retained. As shown, a proximal intramedullary stem ( 1202 ) is affixed within the patient&#39;s remaining humerus shaft segment, and a radial intramedullary stem ( 1208 ) is affixed within the patient&#39;s remaining radius shaft segment. A modular rotational component ( 100 ) is included, with the rotational component ( 1204 ) nearest the humeral stem ( 1202 ). A modular spacer ( 900 ) is incorporated as necessary to establish the proper repair length to ensure symmetry of the patient&#39;s arm length. The modular spacer ( 900 ) includes porous mesh metal surface treatment to ensure affixation of the soft muscle tissue of the forearm. 
         [0048]    The rotational component embodiment may also be utilized with femoral prosthetic devices to, likewise, prevent excessive torsional stresses during rapid full rotation of the patient&#39;s lower leg with respect to the hip. These torsional stresses can weaken the stem fixation site, and can cause dislocation of the acetabulofemoral articulation (hip socket) due to the impulse felt at the acetabulofemoral articulation at full rotation. As with the humeral prosthetic device, the rotational component is positioned proximate the intramedullary stem. Such a configuration is depicted in  FIG. 13 . 
         [0049]      FIG. 13  is an embodiment of a partial modular femoral prosthesis with rotational component, and featuring a normal femoral head. This endoprosthetic device configuration ( 1300 ) utilizes the modular rotational component ( 100 ) as described herein, coupled with the trochanter segment ( 1302 ) featuring a ball component ( 1308 ) for engagement with the acetabulum. The modular rotational component ( 100 ) is positively retained by the trochanter segment ( 1302 ) through use of a hex-headed locking screw ( 1304 ) that runs the length of the trochanter segment ( 1302 ). As depicted, the outer surface of the proximal segment ( 1302 ) includes a porous mesh surface treatment as previously described, to effect soft tissue attachment to the prosthesis. Suture attachment features ( 1306 ) provide for positive retention of the soft tissue until healing and attachment occurs. 
         [0050]    The invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive. Accordingly, the scope of the invention is established by the appended claims rather than by the foregoing description. All changes that come within the meaning and range of equivalency of the claims are intended therein. Further, the recitation of method steps does not denote a particular sequence for execution of the steps. Such method steps may therefore be performed in a sequence other than that recited unless the particular claim expressly states otherwise.