Patent Description:
Hip joint Osteoarthritis is a syndrome in which low-grade inflammation results in pain in the hip joints, caused by abnormal wearing of the Cartilage that acts as a cushion inside if the hip joint. This abnormal wearing of the cartilage also results in a decrease of the joints lubricating fluid called Synovial fluid. Hip joint Osteoarthritis is estimated to affect <NUM>% of all people over <NUM> years of age, in more or less serious forms.

The present treatment for hip osteoarthritis comprises NSAID drugs, local injections of Hyaluronic acid or Glucocorticoid to help lubricating the hip joint, and replacing parts of the hip joint with a prosthesis through hip joint surgery.

The replacing of parts of the hip joint is one of the most common surgeries to date performed at hundreds of thousands of patients in the world every year. The most common method comprises placing a metal prosthesis in Femur and a plastic bowl in Acetabulum. This operation is usually done through a lateral incision in the hip and upper thigh and through, Fascia Lata and the lateral muscles of the thigh. To get access to the hip joint, the supporting hip joint capsule attached to Femur and Ilium of Pelvis needs to be penetrated, making it difficult to get a fully functional joint after the surgery. Femur is then cut at the neck with a bone saw and the prosthesis is placed in femur either with bone cement or without. Acetabulum is slightly enlarged using an Acetabular reamer, and the plastic bowl is positioned using screws or bone cement.

The surgery typically requires one week of hospitalization due to the increased risk of infection. The recovery process is on average about <NUM> weeks, but even after this period the patient should not perform any physical activates that places large strain on the joint.

<CIT> discloses a reverse prosthesis for implantation in a hip joint of a human patient, the prosthesis comprising an artificial convex caput femur adapted to be fixated to the pelvic bone of the human patient and be in movable connection with an artificial acetabulum surface fixated to the femoral bone of the patient, thereby forming a ball and socket joint. The prosthesis further comprises a fixation element for fixating the prosthesis to the pelvic bone, wherein the fixation element comprises a fixation surface adapted to fit into the acetabulum of the pelvic bone. The prosthesis further comprises an elongated member adapted to be inserted into a hole in the pelvic bone.

<CIT> discloses a prosthesis for implantation in a hip joint of a human patient, the prosthesis comprising an artificial convex caput femur adapted to be fixated to the femoral bone of the human patient and be in movable connection with an artificial acetabulum surface fixated to the pelvic bone of the patient, thereby forming a ball and socket joint. The prosthesis further comprises a prosthetic part for fixating it to the pelvic bone. Additionally, the prosthesis comprises a supporting member adapted to engage the surface of the abdominal side of the pelvic bone, wherein the supporting member is adapted to be secured to the abdominal side of the pelvic bone by a screw.

The invention is set out in the appended set of claims and claim a medical device for implantation in a hip joint.

Some of the embodiments below are not according to the claimed invention, but included for illustrational purposes instead.

The medical device could comprise an artificial convex hip joint surface adapted to replace the convex hip joint surface. The artificial convex hip joint surface is adapted to be fixated to the pelvic bone of the human patient.

According to one embodiment, the medical device comprises an artificial convex hip joint surface adapted to be inserted through a hole in the pelvic bone of the human patient.

According to one embodiment, the medical device comprises an artificial convex hip joint surface adapted to be inserted through a hole in the hip joint capsule of the human patient.

According to one embodiment, the medical device comprises an artificial convex hip joint surface adapted to be inserted through a hole in the femoral bone of the human patient.

The medical device is adapted to be placed in an artificial replacement of the concave acetabulum hip joint surface. The artificial replacement is adapted to be fixated to the caput femur, the collum femur or the femoral bone.

According to one embodiment the artificial convex hip joint surface in the medical device comprises at least two artificial hip joint surface parts adapted to be placed in connection with each other after the insertion in the human patient. The at least two artificial hip joint surface parts could be adapted to be inserted through a hole in the pelvic bone from the opposite side from acetabulum of the human patient, said hole having a diameter less than the largest diameter of said medical device. It is also conceivable that the at least two artificial hip joint surface parts are adapted to be inserted through a hole in the femoral bone or the hip joint capsule of the human patient. The hole having a diameter smaller than the largest diameter of the medical device.

According to any of the embodiments above, at least one of said at least two artificial hip joint surface parts could be adapted to serve as base part to which at least one additional artificial caput femur surface part can be connected.

The connection of said at least two artificial hip joint surface parts could be performed using at least one of: at least one screw, at least one pin, at least one portion of at least one of the parts adapted to be introduced into the other part, the parts being adapted to be sliding into the other part, form fitting, welding, adhesive, pin, wire, a ball mounted into a bowl being portions of said parts, a male portion of one part mounted into a female portion of the other part, a key introduced into a lock being portions of said parts, band, or other mechanical connecting members. It is also conceivable that the at least two artificial hip joint surface parts are adapted to mechanically connect to each other using self locking members, in which case the self locking members could be assisted by adhesive or bone cement.

According to one embodiment, the medical device comprises at least one elastic member. The at least one elastic member could be adapted for changing the largest diameter or largest cross-sectional distance of the medical device for insertion through a hole having a diameter smaller than said largest diameter or cross-sectional distance of said medical device.

To fixate the medical device the medical device comprises a fixation element to anchor the artificial convex hip joint surface. The fixation support is adapted to anchor the artificial convex hip joint surface to the pelvic bone, to support at least part of the load applied to the hip joint in normal use.

According to one embodiment the fixation support comprises a displaceable part or section. The displaceable part or section could be adapted to carry the load applied to the hip joint in normal use.

According to one embodiment the medical device could be adapted to be fixated to the pelvic bone using at least one of: at least one screw, at least one pin, at least one portion of at least one of the parts adapted to be introduced into the other part, the parts being adapted to be sliding into the other part, form fitting, welding, adhesive, pin, wire, a ball mounted into a bowl being portions of said parts, a male portion of one part mounted into a female portion of the other part, a key introduced into a lock being portions of said parts, band, or other mechanical connecting members.

According to one embodiment the medical device could be fixated to the pelvic bone without penetration of the cortex of the pelvic bone. It is also conceivable that the medical device is adapted to be fixated to the pelvic bone by means of said elastic member exerting a clamping force on the pelvic bone.

The medical device according to any of the embodiments above could comprise at least one of the materials: polyethylene based material, PTFE, Corian, titanium, stainless steel, wolfram, other metal material, a combination of metal material, carbon fiber, boron, a combination of metal and plastic materials, a combination of metal and carbon based material, a combination of carbon and plastic based material, multi-material, wherein one material comprise a flexible material, multi-material, wherein one material comprise an elastic material, multi-material, wherein one material comprising more parts than the other at least one material, PE, and an acrylic polymer. It is also conceivable that the medical device comprises a self lubricating material. In cases where the medical device does not comprise a self lubricating material or if the self lubricating material is not sufficient it is conceivable that the medical device is adapted to be lubricated after insertion in the hip joint.

According to one embodiment the medical device could be adapted to be lubricated after insertion in the hip joint. It is furthermore conceivable that the medical device comprises a self lubricating material such as PTFE.

The present invention further relates to a medical device for treating hip joint osteoarthritis in a human patient by providing at least one artificial hip joint surface. The hip joint has a ball shaped caput femur as the proximal part of the femoral bone with a convex hip joint surface and a bowl shaped acetabulum as part of the pelvic bone with a concave hip joint surface.

The medical device comprises an artificial concave hip joint surface, adapted to be fixated to at least one of: caput femur, collum femur or another part of the femoral bone.

According to one embodiment, the medical device comprises an artificial concave hip joint surface adapted to be inserted through a hole in the pelvic bone of the human patient.

According to one embodiment, the medical device comprises an artificial concave hip joint surface adapted to be inserted through a hole in the hip joint capsule of the human patient.

According to one embodiment, the medical device comprises an artificial concave hip joint surface adapted to be inserted through a hole in the femoral bone of the human patient.

According to one embodiment the artificial concave hip joint surface is further adapted to be placed in connection with an artificial replacement of the convex hip joint surface. The artificial replacement could be adapted to be fixated to the pelvic bone.

According to one embodiment the artificial concave hip joint surface comprises at least two artificial hip joint surface parts adapted to be placed in connection with each other after the insertion in the human patient.

The at least two artificial hip joint surface parts could be adapted to be inserted through a hole in the pelvic bone from the opposite side from acetabulum of the human patient, said hole having a diameter less than the largest diameter of said medical device. It is also conceivable that the at least two artificial hip joint surface parts are adapted to be inserted through a hole in the femoral bone or the hip joint capsule of the human patient. The hole having a diameter less than the largest diameter of said medical device.

According to one embodiment of the present invention the medical device comprises at least one elastic member. The at least one elastic member could be adapted for changing the largest diameter or largest cross-sectional distance of the medical device for insertion through a hole having a diameter smaller than said largest diameter or cross-sectional distance of said medical device.

To fixate the medical device according to the present invention it is conceivable that the medical device comprises a fixation support to anchor said artificial concave hip joint surface. The fixation support is adapted to anchor said artificial concave hip joint surface to the caput femur, the collum femur or another part of the femoral bone of the human patient, to at least partly support the load applied to the hip joint in normal use.

The medical device according to claim <NUM>, wherein said fixation support comprises a displaceable part or section, and wherein said displaceable part or section is adapted to carry the load applied to the hip joint in normal use.

According to one embodiment the medical device could be adapted to be fixated to caput femur, the collum femur or the femoral bone using at least one of: at least one screw, at least one pin, at least one portion of at least one of the parts adapted to be introduced into the other part, the parts being adapted to be sliding into the other part, form fitting, welding, adhesive, pin, wire, a ball mounted into a bowl being portions of said parts, a male portion of one part mounted into a female portion of the other part, a key introduced into a lock being portions of said parts, band, or other mechanical connecting members. It is also conceivable that the fixation is done using self locking members, in which case the self locking members could be assisted by adhesive or bone cement.

According to one embodiment the medical device could be fixated to the caput femur, the collum femur or the femoral bone without penetration of the cortex of the pelvic bone. It is also conceivable that the medical device is adapted to be fixated to the caput femur, the collum femur or the femoral bone by means of said elastic member exerting a clamping force on the caput femur, collum femur or femoral bone.

The medical device according to any of the embodiments could comprise at least one of the materials: polyethylene based material, PTFE, Corian, titanium, stainless steel, wolfram, other metal material, a combination of metal material, carbon fiber, boron, a combination of metal and plastic materials, a combination of metal and carbon based material, a combination of carbon and plastic based material, multi-material, wherein one material comprise a flexible material, multi-material, wherein one material comprise an elastic material, multi-material, wherein one material comprising more parts than the other at least one material, PE, and an acrylic polymer. It is also conceivable that the medical device comprises a self lubricating material. In cases where the medical device do not comprise a self lubricating material or if the self lubricating material is not sufficient it is conceivable that the medical device is adapted to be lubricated after insertion in the hip joint.

The present invention further relates to a medical device system for treating hip joint osteoarthritis in a human patient by providing at least two hip joint surfaces. The system comprising the artificial convex hip joint surface according to any of the embodiments above and the artificial concave hip joint surface according to any of the embodiments above.

The artificial convex hip joint surface in the medical device system could be adapted to be placed, at least partly, inside of said artificial concave hip joint surface.

According to one embodiment the artificial convex hip joint surface comprises a largest diameter and said artificial concave hip joint surface could be adapted to travel beyond the largest diameter of the artificial convex hip joint surface.

According to one embodiment the medical device system has a ball shaped caput femur as the proximal part of the femoral bone with a convex hip joint surface, and a bowl shaped acetabulum as part of the pelvic bone with a concave hip joint surface. The artificial convex hip joint surface could be adapted to be placed, at least partly, inside of the caput femur.

According to one embodiment the medical device could be adapted to be lubricated after insertion in the hip joint. Said lubrication is preferably done with a biocompatible lubricator such as hyaluronic acid. It is furthermore conceivable that the medical device comprises a self lubricating material such as PTFE.

According to one embodiment the medical device comprising an artificial acetabulum or an artificial acetabulum surface, wherein said elongated member is adapted to centre and hold said artificial acetabulum or an artificial acetabulum surface during fixation in the hip joint.

According to one embodiment the medical device comprising an artificial caput femur or an artificial caput femur surface, wherein said elongated member is adapted to centre and hold said artificial caput femur or an artificial caput femur during fixation in the hip joint.

According to one embodiment said elongated member is adapted to centre and hold both said artificial caput femur or an artificial caput femur and said artificial acetabulum or an artificial acetabulum surface during fixation in the hip joint.

According to one further embodiment of the medical device, the artificial caput femur surface comprises a convex form towards the centre of the hip joint and the artificial acetabulum surface comprises a concave form towards the centre of the hip joint. The artificial caput femur surface and the artificial acetabulum surface is constructed to be placed in the hip joint in a opposite position towards each other, thus; the artificial convex caput femur surface is adapted to be fixated to the pelvic bone of the human patient, and the artificial concave acetabulum surface is adapted to be fixated to the femoral bone of the human patient.

According to one embodiment the artificial acetabulum or artificial acetabulum surface is adapted to be centered and held by said elongated member, during fixation in the hip joint.

According to one embodiment the artificial caput femur or an artificial caput femur surface is adapted to be centered and held by the elongated member, during fixation in the hip joint.

For illustrative purposes a method of treating hip joint osteoarthritis in a human patient is described below, by providing at least one hip joint surface. The method comprises the steps of: fixating the artificial convex hip joint surface, according to any of the embodiments above, to the pelvic bone, and fixating the artificial concave hip joint surface according to any of the embodiments above to at least one of; the caput femur, the collum femur or the femoral bone of the human patient.

The method could further comprise, the steps of: cutting the skin of the human patient, dissecting an area of the pelvic bone on the opposite side from the acetabulum, creating a hole in said dissected area, said hole passing through the pelvic bone and into the hip joint of the human patient, inserting said artificial hip joint surfaces into the hip joint through said hole. After the steps of fixating the artificial convex hip joint surface, according to any of the embodiments above, to the pelvic bone, and fixating the artificial concave hip joint surface according to any of the embodiments above to at least one of; the caput femur, the collum femur or the femoral bone of the human patient, the method further comprises the steps of: Closing the hole in the pelvic bone using bone material or a prosthetic part and closing, preferable in layers, the hip area of the human patient using sutures or staples.

According to a second non claimed example the method is a method of treating hip joint osteoarthritis by providing artificial hip joint surfaces according to any of the embodiments above. The hip joint comprises a ball shaped caput femur as the proximal part of the femoral bone with a convex hip joint surface and a bowl shaped acetabulum as part of the pelvic bone with a concave hip joint surface, the method comprises the steps of: cutting the skin of the human patient, dissecting an area of the hip joint, creating a hole in the hip joint capsule, inserting said artificial hip joint surfaces into the hip joint through said hole in the hip joint capsule, fixating the artificial convex hip joint surface device to the pelvic bone, fixating the concave artificial hip joint surface to at least one of; the caput femur, the collum femur or the femoral bone, and closing, preferable in layers, the hip area of the human patient using sutures or staples or adhesive.

According to a third non claimed example the method of treating hip joint osteoarthritis by providing artificial hip joint surfaces according to any of the embodiments above is a arthroscopic method. The hip joint comprises a ball shaped caput femur as the proximal part of the femoral bone with a convex hip joint surface and a bowl shaped acetabulum as part of the pelvic bone with a concave hip joint surface, the method comprises the steps of: inserting a needle or a tube like instrument into the patient's body, using the needle or tube like instrument to fill a part of the patient's body with gas and thereby expanding a cavity within said body, placing at least two arthroscopic trocars in said cavity, inserting a camera through one of the arthroscopic trocars into said cavity, inserting at least one dissecting tool through one of said at least two arthroscopic trocars, dissecting an area of the pelvic bone on the opposite side from the acetabulum, creating a hole in said dissected area, said hole passing through the pelvic bone and into the hip joint of the human patient, and providing said artificial hip joint surfaces to the hip joint, through said hole in the pelvic bone of the human patient.

According to a third non claimed example the method of treating hip joint osteoarthritis by providing artificial hip joint surfaces according to any of the embodiments above is a second arthroscopic method. The hip joint comprises a ball shaped caput femur as the proximal part of the femoral bone with a convex hip joint surface and a bowl shaped acetabulum as part of the pelvic bone with a concave hip joint surface, the method comprises the steps of: inserting a needle or a tube like instrument into the patient's body, using the needle or tube like instrument to fill a part of the patient's body with gas and thereby expanding a cavity within said body, placing at least two arthroscopic trocars in said cavity, inserting a camera through one of the arthroscopic trocars into said cavity, inserting at least one dissecting tool through one of said at least two arthroscopic trocars, dissecting an area of the hip joint, creating a hole in the hip joint capsule, inserting said artificial hip joint surfaces into the hip joint through said hole in the hip joint capsule, fixating the artificial convex hip joint surface device to the pelvic bone, fixating the concave artificial hip joint surface to at least one of; the caput femur, the collum femur or the femoral bone, and closing, preferable in layers, the hip area of the human patient using sutures or staples or adhesive.

According to one non claimed example the method of manipulation comprises the steps of; fixating an artificial acetabulum surface to the pelvic bone, wherein said elongated member; centers the artificial acetabulum surface, when the artificial acetabulum surface is fixated in the hip joint.

According to one non claimed example the method of manipulation comprises the step of; fixating an artificial caput femur surface to the femoral bone, wherein said elongated member; centers said artificial caput femur surface, when said artificial caput femur surface is fixated in the hip joint.

According to one non claimed example, a method of centering an artificial hip joint surface in a hip joint of a human patient is provided. The hip joint comprising a collum femur, being the proximal part of the femoral bone, a caput femur, being the upper extremity of the femoral bone, and an acetabulum, being a bowl shaped part of the pelvic bone, the method comprising the steps of: penetrating the skin of a lateral section of the thigh, creating a hole in the collum femur, along a length axis thereof, reaching an area of the hip joint, placing an elongated member in said hole, wherein said elongated member reaches centrally in said area of the hip joint, and centering said artificial hip joint surface onto said elongated member, wherein the artificial hip joint surface comprises a centre hole for guiding the elongated member, and placing the said artificial hip joint surface in a functional position in the hip joint.

The artificial hip joint surface, according to any of the embodiments above may comprise an artificial convex caput femur or an artificial convex caput femur surface or an artificial concave acetabulum or an artificial concave acetabulum surface.

According to one non claimed example the step of fixating said artificial acetabulum surface further comprises the step of placing a locking member in connection with the artificial acetabulum surface, such that said artificial acetabulum surface remains clasped to said surgically cut femoral bone.

According to one non claimed example the step of placing a locking member comprises the step of placing a locking member encircling the artificial acetabulum surface and the surgically cut caput femur.

The collum femur has a longitudinal extension, and a fixating member at least partly be positioned on and stabilized by the cortical bone of said stabilizing part of the collum femur from two different aspects of the collum femur, the method could comprise the steps of; positioning and stabilizing said fixating member from the inside of said stabilizing part of the collum femur, substantially perpendicular to the longitudinal extension thereof, and from the acetabulum side substantially in line with the longitudinal extension of the collum femur.

The collum femur has a longitudinal extension and a fixating member at least partly be positioned on, and stabilized by the cortical bone of said stabilizing part of the collum femur from three different aspects of the collum femur. The method could comprise the steps of; positioning and stabilizing said fixating member from the inside of said stabilizing part of the collum femur substantially perpendicular to the longitudinal extension thereof, from the acetabulum side substantially in line with the longitudinal extension of the collum femur and from the outside of the collum femur substantially perpendicular to the longitudinal extension thereof.

Please note that the claims constitute the scope of the protection in light of the definitions and explanations made in the specification.

In the following a detailed description of preferred embodiments of the present invention will be given. In the drawing figures, like reference numerals designate identical or corresponding elements throughout the several figures. It will be appreciated that these figures are for illustration only and are not in any way restricting the scope of the invention. Thus, any references to direction, such as "up" or "down", are only referring to the directions shown in the figures. Also, any dimensions etc. shown in the figures are for illustration purposes.

Functional hip movements are to be understood as movements of the hip that at least partly correspond to the natural movements of the hip. On some occasions the natural movements of the hip joint might be somewhat limited or altered after hip joint surgery, which makes the functional hip movements of a hip joint with artificial surfaces somewhat different than the functional hip movements of a natural hip joint.

The functional position of an implantable medical device or prosthesis is the position in which the hip joint can perform functional hip movements. The final position is to be understood as a functional position in which the medical device needs no further position change.

Arthroscopy is to be understood as key hole surgery performed in a joint, since the arthroscopic procedure could be performed in the abdomen of the patient some of the steps of this arthroscopic procedure is more laparoscopic, however for the purpose of this invention the two terms arthroscopy and laparoscopy is used synonymously and for the purpose of this invention the main purpose of these methods are is that they are minimally invasive.

The medical device according to any of the embodiments could comprise at least one material selected from a group consisting of: polytetrafluoroethylene (PTFE), perfluoroalkoxy (PFA) and fluorinated ethylene propylene (FEP). It is furthermore conceivable that the material comprises a metal alloy, such as cobalt-chromium-molybdenum or titanium or stainless steel, or polyethylene, such as cross-linked polyethylene or gas sterilized polyethylene. The use of ceramic material is also conceivable, in the contacting surfaces or the entire medical device such as zirconium or zirconium dioxide ceramics or alumina ceramics. The part of the medical device in contact with human bone for fixation of the medical device to human bone could comprise a poorhouse structure which could be a porous micro or nano-structure adapted to promote the growth-in of human bone in the medical device for fixating the medical device. The porous structure could be achieved by applying a hydroxy-apatite (HA) coating, or a rough open-pored titanium coating, which could be produced by air plasma spraying, a combination comprising a rough open-pored titanium coating and a HA top layer is also conceivable. The contacting parts could be made of a self lubricated material such as a waxy polymer, such as PTFE, PFA, FEP, PE and UHMWPE, or a powder metallurgy material which could be infused with a lubricant, which preferably is a biocompatible lubricant such as a Hyaluronic acid derivate. It is also conceivable that the material of contacting parts or surfaces of the medical device herein is adapted to be constantly or intermittently lubricated. According to some embodiments the parts or portions of the medical device could comprise a combination of metal materials and/or carbon fibers and/or boron, a combination of metal and plastic materials, a combination of metal and carbon based material, a combination of carbon and plastic based material, a combination of flexible and stiff materials, a combination of elastic and less elastic materials, Corian or acrylic polymers.

<FIG> shows the hip joint of a human patient in section. The hip joint comprises a caput femur <NUM> placed at the very top of collum femur <NUM> which is the top part of the femoral bone <NUM>. The caput femur is in connection with the acetabulum <NUM>, which is a bowl shaped part of the pelvic bone <NUM>. Both the caput femur surface <NUM> and the acetabulum surface <NUM> is covered with articular cartilage <NUM> which acts as a cushion in the hip joint. In patients with hip joint osteoarthritis, this articular cartilage <NUM> is abnormally worn down due to a low grade inflammation. The hip joint is surrounded by the hip joint capsule <NUM> which provides support for the joint and hinders luxation. After conventional hip joint surgery, penetrating the hip joint capsule <NUM>, the capsule <NUM> is dramatically weakened due to the limited healing possibilities of its ligament tissue. By performing hip joint surgery without damaging the hip joint capsule <NUM> the patient can fully recover and place equal amount of strain on an artificial joint as is possible on a natural one.

<FIG> shows a section A - A of the collum femur, as shown in <FIG>. The section A - A shows the collum femur comprising cortical bone <NUM>, the outer more sclerotic bone, and cancellous bone <NUM>, the inner porous bone located in the bone marrow <NUM>. Further, <FIG> shows a section B - B of the caput femur, perpendicular to the length axis of the collum <NUM> and caput <NUM> femur.

<FIG> shows a lateral view of a human patient when an incision in the thigh region has been made. The femoral bone <NUM> comprising the collum femur <NUM> and the caput femur <NUM> has been dislocated from its usual position in the hip joint, in connection with the acetabulum, which is a part of the pelvic bone <NUM>, the caput femur <NUM> being a part of the hip joint normally being covered by the hip joint capsule.

<FIG> shows the proximal part of the caput femur <NUM> being removed e.g. by means of a bone saw. A surface of a section <NUM> is thus created perpendicularly to a length axis of the collum femur <NUM>.

<FIG> shows the reaming of the collum femur <NUM> and caput femur <NUM> using a reamer <NUM> connecting to an elongated member <NUM> by a connecting section <NUM>. The reamer <NUM> creating a hemi-spherical cavity, having a concave surface <NUM>, centrally placed in the caput <NUM> and collum femur <NUM>.

<FIG> shows the step of applying an adhesive <NUM> to the created hemi-spherical cavity in the femoral bone using an injecting member <NUM> having an injecting nozzle <NUM>. In the embodiment shown in <FIG> the injecting member is inserted into an area of the hip joint through a hole <NUM> in the pelvic bone <NUM>, however it is equally conceivable that the injecting member is inserted through the hip joint capsule <NUM> or the femoral bone <NUM>.

<FIG> shows the femoral bone <NUM> when a medical device <NUM> having a concave contacting surface has been provided to the hemi-spherical cavity, centrally placed in the caput <NUM> and collum femur. An elastic layer 109b adapted to absorb shocks from the femoral bone has been placed between the surface 109c adapted to be in contact with the artificial caput femur surface, and the femoral bone <NUM>, <NUM>. The elastic layer 109b could be an elastic polymer layer, such as a polyurethane or silicone layer. Having a layer absorbing shocks in the hip joint reduces the risk of fastening elements in contact with bone being affected by strains such that the fastening elements are loosened from their respective fastening positions, it also increases the comfort for the patient.

<FIG> shows the femoral bone <NUM> when a medical device having a concave contacting surface <NUM> has been provided to the hemi-spherical cavity, centrally placed in the caput <NUM> and collum femur. The medical device has been fixated to the femoral bone <NUM> using screws <NUM> placed aligned with the caput and collum femur center axis and entering the cortical bone of the caput femur.

<FIG> shows the femoral bone <NUM> when a medical device having a concave contacting surface <NUM> has been provided to the hemi-spherical cavity, centrally placed in the caput <NUM> and collum femur. The medical device comprises fixating portions <NUM> extending on the outside of the surface of a section <NUM> of the surgically cut caput femur, comprising cortical bone in the periphery thereof, thereby stabilizing the medical device with the artificial concave acetabulum surface <NUM> in the surgically cut caput femur.

<FIG> shows an alternative embodiment, in which the medical device has been fixated to the surgically cut caput femur using screws <NUM> entering the cortical bone <NUM> of the caput femur.

<FIG> shows yet another embodiment, in which the medical device is fixated to the femoral bone using fixating portions, in accordance with the embodiment described with reference to <FIG>, and an elongated member <NUM>. The elongated member is according to this embodiment a threaded member <NUM> extending along the collum and caput femur center axis, in the cancellous bone <NUM> of the collum femur, and entering the cortical bone <NUM> of the femoral bone, on the inside thereof, in the area of the greater trochanter. The threaded elongated member <NUM> creates an axial force when pulled pressing the medical device towards the surface of a section <NUM> of the surgically cut caput femur, thereby stabilizing and fixating the medical device in the concave cavity created in the caput femur.

<FIG> shows yet an alternative embodiment of the medical device in which the fixating portions <NUM> are additionally fixated using screws <NUM> placed from the outside of the surgically cut caput femur, perpendicularly to the collum and caput femur center axis.

<FIG> shows the medical device in an embodiment in which the fixating portions <NUM> extends beyond the greatest circumference of the surgically cut caput femur and thereby clasps the medical device to the surgically cut caput femur, fixating the medical device thereon. The concave contacting surface <NUM> is also adapted to travel beyond the equator of an artificial caput femur which is placed in the artificial acetabulum when mounted into a functioning artificial hip joint, and clasping the artificial caput femur when mounted therein.

<FIG> shows yet another embodiment where the medical device is additionally fixated using a fixating band <NUM> encircling the fixating portions of the medical device and thereby further clasping the medical device to the surgically cut caput femur.

<FIG> shows three different embodiment of medical devices comprising fixating portions <NUM> which are slightly tilted towards the collum and caput femur center axis, thereby clasping a portion of the surgically cut caput femur for fixating the medical device to the surgically cut caput femur. The three different embodiments shown is first, without screws <NUM>, second, with screws entering the cortical bone, and third, with screws penetrating the cortical bone and entering the medical device on the inside of the concave cavity, which enables the screws to squeeze a portion of the cortical bone for tight fixation of the medical device.

<FIG> shows two embodiments in which the concave contacting surface <NUM> only comprises the part placed inside of the concave cavity. The first embodiment shows the acetabulum surface <NUM> fixated to the concave cavity using screws <NUM>, whereas the second embodiment shows the artificial acetabulum surface fixated without screws, such as using an adhesive.

<FIG> shows two embodiments in which the artificial acetabulum surface extends into a portion placed on the surface of a section created when the caput femur is surgically cut. In the first embodiment the medical device is fixated using screws entering the cortical bone, whereas in the second embodiment the artificial contacting surface is fixated without screws, such as using an adhesive.

<FIG> describes an embodiment in which the medical device is further fixated using an elongated member <NUM>, fixating portions <NUM>, and screws <NUM> placed between the fixating portions <NUM> and the inside of the artificial acetabulum contacting surface <NUM>. The elongated member <NUM> is according to this embodiment a threaded member <NUM> and the first fig. discloses the preparation of the cancellous bone <NUM> with a curing fluid <NUM>, such as bone cement, creating a sturdy base for the fixation of the threaded member <NUM>.

<FIG> shows the artificial acetabulum surface <NUM> in further detail when the artificial acetabulum surface comprises a fixating portion <NUM> extending on the outside of the cortical bone <NUM>. The fixating portion <NUM> is further fixated using screws <NUM> placed from the outside, through a hole in the medical device, penetrating the cortical bone <NUM> of the surgically cut caput femur and entering the medical device placed in the concave cavity in the caput femur.

<FIG> shows a section of the medical device according to the embodiment also described with reference to <FIG>, in further detail. The medical device according to the embodiment in <FIG> comprises fixating portions <NUM> which reaches on the outside of the surgically cut caput femur and clasps the cortical bone of the caput femur. The medical device clasps the caput femur since a distance <NUM>, between the collum and caput femur center axis CA and the fixating portion in shorter than a distance <NUM> between the collum and caput femur center axis CA and a portion of the fixating portion placed more proximally when the medical device is implanted. On the inside of the artificial concave acetabulum surface, the surface extends beyond the equator of the artificial caput femur adapted to be placed therein. An extending portion <NUM> clasps the artificial caput femur placed in the artificial acetabulum surface <NUM> since a distance <NUM>, between the collum and caput femur center axis CA and the inside of the artificial acetabulum surface <NUM> is shorter than a distance <NUM> between the collum and caput femur center axis CA and a point on the inside of the artificial acetabulum contacting surface <NUM> being more distal when the medical device is implanted. In other embodiments, the fixating portions <NUM> could be operable or adjustable for further fixating the medical device to the cortical bone. The fixating portions <NUM> could be operable for example by means of a screw for tightening the fixating portions <NUM> to the cortical bone, which could squeeze the cortical bone between the fixating portions <NUM> and the part of the medical device placed inside of the femoral bone.

<FIG> shows the step of milling the periphery <NUM> of the cortical bone of the caput femur after the caput femur has been surgically cut, using a milling device <NUM> adapted therefor. The milling process creates a straighter edge which facilitates the fixation of a medical device on the outside of the caput femur.

<FIG> shows the milling of the inside of the cortical bone of the caput femur after the caput femur has been surgically cut, using a milling device <NUM> adapted therefor, creating a straighter edge which facilitates the fixation of a medical device on the inside of the caput femur.

<FIG> shows an artificial convex caput femur surface <NUM> adapted to be placed in an artificial acetabulum surface according to any of the embodiments herein. After the artificial convex caput femur surface has been placed in the artificial acetabulum surface it is locked using a locking member <NUM> comprising a surface <NUM> adapted to be in contact with the artificial convex hip joint surface <NUM>. The locking member <NUM> further comprises fixating members <NUM> which are adapted to assist in the fixation of the locking member <NUM> to the caput femur <NUM> or collum femur <NUM>, which in turns fixates the artificial convex hip joint surface <NUM>. The fixating members comprises a fixating portion <NUM> which travels on the outside of the surgically cut caput femur for radially stabilizing and fixating the locking member to the surgically cut caput femur. The artificial convex hip joint surface <NUM> is fixated to an attachment rod <NUM> comprising a thread <NUM>.

<FIG> shows the artificial convex caput femur surface <NUM> as disclosed with reference to <FIG> when mounted in an artificial acetabulum surface <NUM> placed in a concave cavity in the femoral bone. The artificial acetabulum surface is according to this embodiment is fixated to the femoral bone using an elongated member <NUM>, here being a threaded member placed aligned with the collum and caput center axis.

<FIG> shows the artificial convex caput femur surface <NUM> as disclosed with reference to <FIG> when mounted in an artificial acetabulum surface <NUM> placed in a concave cavity in the femoral bone. The artificial acetabulum surface is according to this embodiment is fixated using screws <NUM> entering the cortical bone of the surgically cut caput femur.

<FIG> shows the injection of an adhesive <NUM> in the acetabulum <NUM> in the pelvic bone <NUM> using an injecting member comprising an injecting nozzle <NUM>, which is a preparation for the fixation of a medical device to the pelvic bone <NUM>.

<FIG> shows the placing of a medical device in the reamed acetabulum <NUM> surface of the pelvic bone <NUM>. The medical device comprises a convex hip joint surface <NUM> fixated to a fixation element <NUM>, which in turn is fixated to the acetabulum <NUM> using the injected fluid, which could be assisted or replaced by a mechanical fixation element such as screws. The medical device further comprises a pre-mounted locking member <NUM> for locking the convex hip joint surface of the concave hip joint surface placed in the caput <NUM> and collum femur <NUM> for hindering dislocation of the hip joint when the hip joint is in its functional position.

<FIG> shows the step of creating a hole in the pelvic bone <NUM> from the acetabulum side of the pelvic bone <NUM>.

<FIG> shows the medical device according to an embodiment in which the medical device comprises a fixation element <NUM> adapted to fixate the artificial convex caput femur <NUM> to the pelvic bone <NUM>. The fixation element <NUM> comprises a fixation surface <NUM> which is adapted to fit into the acetabulum <NUM>. The fixation surface <NUM> could be adapted to be fixated against the acetabulum <NUM> using an adhesive, such as bone cement, applied to the fixation surface <NUM> and/or the acetabulum surface <NUM>. The medical device further comprises an elongated element <NUM>, here being an integrated part of the fixation element <NUM>. The elongated element <NUM> is inserted through the hole in the pelvic bone <NUM>, such that said elongated member <NUM> is partially placed on the abdominal side of the pelvic bone <NUM>. After insertion of the elongated member <NUM>, the elongated member <NUM> is structurally changed on the abdominal side of the pelvic bone <NUM>, such that said elongated member <NUM> fixates the fixation element <NUM> to the pelvic bone <NUM>. According to the embodiment of <FIG> the elongated member <NUM> comprises an expandable portion <NUM>, and the structural change comprises the expandable portion <NUM> changing from a first, non-expanded state, in which the elongated element <NUM> is inserted into the hole in the pelvic bone <NUM> substantially along a length axis of the elongated element <NUM> into an expanded state, in which the expandable portion <NUM> is expanded in at least one away from the length axis, such that said elongated element <NUM> is placed in an expanded state, which fixates the fixation element <NUM> to the pelvic bone <NUM>. The expandable portion <NUM> according to the embodiment shown in <FIG> comprises a plurality of expanding elements in connection with an anvil member <NUM>. A threaded member <NUM> is placed centrally in the elongated element <NUM> and is in one end connected to an anvil member <NUM> and in the other end connected to a threaded portion <NUM> of the artificial caput femur <NUM>. By the connection with the threaded member <NUM>, the anvil member <NUM> is adapted to press on the expanding elements following an action performed from the acetabulum side of the pelvic bone <NUM>, such that said expanding elements expand in at least one direction substantially perpendicular to the length axis of the elongated element <NUM>. The fixation element shown in <FIG> further comprises a flange <NUM> adapted to extend out of the acetabulum <NUM> and be placed in contact with the pelvic bone <NUM>.

<FIG> shows the expandable portion <NUM> when the anvil member <NUM> has pressed the expandable elements in two directions perpendicular to the length axis of the elongated element <NUM> for fixating the elongated element <NUM> and the entire artificial caput femur <NUM> to the pelvic bone <NUM>. The threaded part <NUM>, being a portion of the artificial caput femur <NUM>, has been partially inserted into the artificial caput femur <NUM>, and thus the anvil member <NUM> is pulled towards the hole in the pelvic bone <NUM>.

<FIG> shows the elongated member <NUM> in the wholly expanded state fixating the artificial caput femur <NUM> to the pelvic bone <NUM>. In this state the threaded member <NUM> is positioned further into the artificial caput femur <NUM> which is rotated to tighten the expandable elongated element <NUM>. The locking member <NUM> is according to this embodiment pre-mounted onto the artificial caput femur <NUM> when the artificial caput femur <NUM> is implanted, however, according to other embodiments it is equally conceivable that the locking member <NUM> is adapted to be mounted after the artificial caput femur <NUM> has been implanted in the hip joint.

<FIG> shows the medical device according to an embodiment in which the implantable medical device comprises an elongated element <NUM> comprising a movable locking portion <NUM> adapted to have a first and second state, wherein said movable locking portion <NUM>, in said first state is adapted to be inserted into a hole in the pelvic bone <NUM>, and in said second state is adapted to hinder the elongated element <NUM> from passing through said hole in the pelvic bone <NUM> by said movable locking portion <NUM> contacting the surface of the pelvic bone <NUM> on the abdominal side. Fig. 8f shows the elongated element <NUM> in its first state after having passed through the hole in the pelvic bone <NUM>.

<FIG> shows the movable locking portion <NUM> changing from the first to the second state at the same time as the artificial caput femur <NUM>, comprising a threaded part <NUM>, interacts with a corresponding threaded member <NUM> being part of the elongated element <NUM>. The movable locking portion <NUM> is pivotally arranged at a pivot point <NUM> and changes from the first to the second state using the pivot point <NUM>.

<FIG> shows the medical device according to the embodiment of <FIG> when the movable member <NUM> is placed in the second state, in which the artificial caput femur <NUM> is fixated to the pelvic bone <NUM> by the movable member <NUM> being in contact with the abdominal side of the pelvic bone <NUM>. The artificial caput femur <NUM> has been tightened using the threaded part <NUM> and corresponding threaded member <NUM>, such that the entire medical device comprising the artificial caput femur <NUM> is securely fixated to the pelvic bone <NUM>. Similar to the embodiments shown with reference to <FIG> the fixation element <NUM> could be further fixated to the acetabulum <NUM> using an adhesive, such as bone cement, applied to the fixation surface and/or the acetabulum surface <NUM>.

<FIG> shows an embodiment in which the fixation element comprises a fixation surface <NUM> comprising two holes adapted to receive two mechanical fixation elements <NUM>. In the embodiment of fig. 8i the mechanical fixation elements <NUM> are expanding fixation elements <NUM>, such as the expanding fixation elements described with reference to <FIG>, however in other embodiments it is equally conceivable that the mechanical fixation elements are elements adapted to fixate the medical device to the internal periphery of the holes, such as screws. Similar to the embodiments shown with reference to <FIG> the fixation element <NUM> could be further fixated to the acetabulum using an adhesive, such as bone cement, applied to the fixation surface and/or the acetabulum surface. <FIG> shows an embodiment in which the medical device has a pre-mounted locking member <NUM>, however, in other embodiments it is equally conceivable that the locking member <NUM> is adapted to be mounted after the artificial caput femur <NUM> has been implanted in the hip joint.

<FIG> shows the artificial hip joint in section, when the medical device described with reference to <FIG> has been implanted. Furthermore an artificial acetabulum surface <NUM> having a concave surface towards the center of the hip joint has been implanted. The artificial acetabulum surface <NUM> has been fixated to the femoral bone <NUM>, and placed in movable contact with the artificial caput femur surface <NUM>, thus creating a functioning artificial hip joint. The locking member <NUM> has been fixated to the femoral bone <NUM>, thus locking the artificial caput femur <NUM> in the artificial acetabulum surface <NUM>. The locking member <NUM> is according to the embodiment shown in fig. 8j fixated using screws <NUM>, however the screws <NUM> could be assisted or replaced by an adhesive, such as bone cement.

<FIG> are not a part of the claimed invention, but only in the specification for illustrative purposes. <FIG> shows an assembled artificial hip joint with an artificial caput femur surface <NUM> fixated to the pelvic bone <NUM> using two fixating members adapted to expand inside of the cortical bone of the pelvic bone <NUM>. The fixating members comprises a screw <NUM> in connection with an anvil member <NUM> affecting an expandable portion <NUM> pressing the expandable members in two directions perpendicular to the length axis of the fixation members for fixating the artificial caput femur <NUM> to the pelvic bone <NUM>. The artificial acetabulum <NUM> is fixated to the femoral bone <NUM> using an elongated member 1310b placed in the cancellous bone and aligned with the caput and collum femur center axis. The elongated member comprises an expandable portion 1311b which is pressed by an anvil member 1312b connected to a threaded member 1313b pressing the expandable members 1311b in two directions perpendicular to the length axis of the elongated member 1310b for fixating the artificial acetabulum surface to the femoral bone <NUM>.

<FIG> shows an embodiment similar to the embodiment shown in <FIG> with the difference that the artificial acetabulum surface is fixated using an elongated member 1310c which penetrates the cancellous bone of the collum femur and the cortical bone of the femoral bone in the area of the greater trochanter <NUM>. The elongated member comprises a movable locking portion 1321b, pivotally arranged at a pivot point 1322b. The movable locking portion 1321b could change from a first to a second state around the pivot point 1322b. When the movable locking portion 1321b is placed in the second state it locks the elongated member on the outside of the femoral bone <NUM> in the area of the greater trochanter <NUM>.

<FIG> shows an embodiment similar to the embodiment shown in <FIG> with the difference that the artificial acetabulum surface is fixated using an elongated member 1310d which penetrates the cancellous bone of the collum femur and enters the cortical bone of the femoral bone in the area of the greater trochanter <NUM> but never exits the bone but rather is fixated inside of the bone <NUM>.

<FIG> shows an embodiment where the artificial acetabulum <NUM> is fixated to the femoral bone <NUM> using fixating portions <NUM> being part of the locking member <NUM>. The fixating portions <NUM> comprises portions <NUM>' clasping the surgically cut femoral bone and thereby fixating the artificial acetabulum surface to the femoral bone.

<FIG> shows an embodiment similar to the embodiment described with reference to <FIG> with the difference that the locking member is fixated to the surgically cut caput femur using screws <NUM>.

<FIG> shows the hip joint in section when the medical device is assembled and in its functional position in the hip joint. The artificial caput femur surface <NUM> or convex hip joint surface <NUM> is fixated to the fixation part <NUM>, which in turn is fixated to the acetabulum <NUM>, The locking member <NUM> locks the artificial convex caput femur surface <NUM> in the artificial concave acetabulum surface in the caput <NUM> and collum femur <NUM>.

<FIG> shows a frontal view of a human patient when an incision for reaching an area of the hip joint through the pelvic bone in a surgical method has been performed. According to one embodiment the incision <NUM> is made in the abdominal wall of the human patient. The incision <NUM> passes through the abdominal wall, preferably rectus abdominis and peritoneum, in to the abdomen of the human patent. In a second embodiment the incision <NUM> is conducted through the rectus abdominis and in to the pelvic area, below peritoneum. According to a third embodiment the incision <NUM> is performed just between Illium and the surrounding tissue, an incision <NUM> which could enable the pelvic bone to be dissected with very little penetration of fascia and muscular tissue. According to a fourth embodiment the incision <NUM> is made in the inguinal channel. In all of the four embodiments the tissue surrounding the pelvic bone <NUM> in the area opposite to acetabulum is removed or penetrated which enables the surgeon to reach the pelvic bone <NUM>. It is obvious that the methods described may both be combined or altered reaching the same goal to dissect the pelvic bone on the opposite side of the acetabulum.

<FIG> shows a frontal view of a human patient when small incisions for reaching an area of the hip joint through the pelvic bone in a arthroscopic method has been performed. According to a first embodiment the incisions <NUM> is made in the abdominal wall of the human patient. The small incisions enable the surgeon to insert arthroscopic trocars into the abdomen of the human patient. According to the first embodiment the incisions <NUM> passes through the abdomen, preferably rectus abdominis and peritoneum, in to the abdomen of the human patent. According to a second embodiment the small incisions <NUM> is conducted through the rectus abdominis and in to the pelvic area, below peritoneum. According to a third embodiment the small incisions <NUM> is performed just between Illium and the surrounding tissue, an incision <NUM> which could enable the pelvic bone to be dissected with very little penetration of fascia and muscular tissue. According to a fourth embodiment the incision <NUM> is made in the inguinal channel. In all of the four embodiments the tissue surrounding the pelvic bone <NUM> in the area opposite to acetabulum <NUM> is removed or penetrated which enables the surgeon to reach the pelvic bone <NUM>.

<FIG> shows the human patient in section when a medical device for creating a hole <NUM> in the pelvic bone <NUM> is inserted through an incision according to any of the embodiments described above. An elongated member <NUM>, which could comprise a part or section adapted to be bent transfers force from an operating device (not shown) to the bone contacting organ <NUM>. The bone contacting organ <NUM> is placed in contact with the pelvic bone <NUM> and creates a hole through a drilling, sawing or milling process powered by a rotating, vibrating or oscillating force distributed from the elongated member <NUM>.

<FIG> shows the hip joint in section after the medical device for creating a hole <NUM> in the pelvic bone <NUM> has created said hole <NUM>. According to this embodiment the hole <NUM> is created through the removal of a bone plug <NUM>, however it is equally conceivable that said medical device comprises a bone contacting organ <NUM> adapted to create small pieces of bone, in which case the medical device could further comprise a system for transport of said small pieces of bone.

<FIG> shows how the medical device adapted to create a hole is inserted into the hip joint and placed in contact with the caput femur <NUM>. According to this embodiment the medical device for creating a hole in the pelvic bone <NUM> and surgically cutting the caput femur <NUM> is the same medical device, however it is equally conceivable that there is a second medical device particularly adapted to surgically cut the caput femur <NUM>.

<FIG> shows the hip joint in section when a second medical device <NUM> surgically removes the most proximal portion of the caput femur <NUM>. The second medical device <NUM> comprises a drilling portion in which a cutting member in a folded position 605a is placed.

<FIG> shows the second medical device <NUM> when the drilling portion is positioned inside of the femoral bone, and the cutting member is placed in a cutting position 605b for cutting the proximal portion of the caput femur <NUM>.

<FIG> shows the caput femur <NUM> after the proximal part has been removed along the section created by the medical device for creating a hole. The removing of the proximal part of the caput femur <NUM> create a surface of a section <NUM> in the cortical bone of the caput femur <NUM>. A reamer <NUM> adapted to create a concave surface <NUM> in the caput femur <NUM> is applied to the elongated member <NUM> through a connecting section <NUM>. According to this embodiment the elongated member <NUM> is the same as the elongated member used for the medical device adapted to create a hole in the pelvic bone <NUM>, however it is equally conceivable that the elongated member <NUM> is specifically designed to enable the reaming of the caput femur <NUM>. The reaming in the caput femur and part of the collum femur <NUM> is mainly performed in the cancellous bone, however that does not exclude the possibility the some of the reaming needs to be performed in the cortical bone of the caput femur <NUM> and/or the collum femur <NUM>.

<FIG> shows the step of applying an adhesive <NUM> to the concave surface created by the reamer <NUM>. The adhesive <NUM> is applied by an injecting member <NUM> comprising an injecting nozzle <NUM>. The adhesive <NUM> is preferably a biocompatible adhesive such as bone cement. The injecting member <NUM> is in this embodiment adapted for introduction through a hole <NUM> in the pelvic bone <NUM>, through the injecting member <NUM> being bent.

<FIG> shows the step of providing a medical device <NUM> comprising an artificial concave hip joint surface <NUM>. The artificial concave hip joint surface <NUM> is fixated to the concave surface <NUM> created in the caput femur <NUM> and collum femur <NUM>. The medical device <NUM> comprises a fixation support <NUM> adapted to anchor said artificial concave hip joint surface <NUM>, to at least one of the caput femur <NUM> and the collum femur <NUM>. The medical device <NUM> is adapted to be introduced to the hip joint through a hole <NUM> in the pelvic bone <NUM> using a inserting member <NUM>. According to this embodiment the inserting member is bent and thereby adapted to operate through a hole <NUM> in the pelvic bone <NUM>. The inserting member <NUM> comprises a connecting member <NUM> which is adapted to connect to the medical device <NUM>. According to one embodiment the medical device <NUM> comprises a self lubricating material such as PTFE, however it is also conceivable that said medical device comprises: titanium, stainless steel, Corian, PE, or other acrylic polymers, in which case the medical device could be adapted to be lubricated after insertion in the hip joint.

<FIG> shows a medical device comprising an artificial convex hip joint surface <NUM>. The artificial convex hip joint surface <NUM> is adapted to be fixated to the pelvic bone <NUM>, and is adapted to be inserted through a hole <NUM> in the pelvic bone <NUM>. The medical device comprises a nut <NUM>, comprising threads for securely fixating the medical device to the pelvic bone <NUM>. The medical device further comprises a prosthetic part <NUM> adapted to occupy the hole <NUM> created in the pelvic bone <NUM> after the medical device has been implanted in the patient. The prosthetic part <NUM> comprises supporting members <NUM> adapted to be in contact with the pelvic bone <NUM> and assist in the carrying of the load placed on the medical device from the weight of the human patient in normal use. Normal use is defined as the same as a person would use a natural hip joint. Further the medical device comprises a locking member <NUM> comprising a surface <NUM> adapted to be in contact with the artificial convex hip joint surface <NUM>. The locking member <NUM> further comprises fixating members <NUM> which are adapted to assist in the fixation of the locking member <NUM> to the caput femur <NUM> or collum femur <NUM>, which in turns fixates the artificial convex hip joint surface <NUM>. The artificial convex hip joint surface <NUM> is fixated to an attachment rod <NUM> comprising a thread <NUM> that corresponds to the thread of the nut <NUM> in connection with the prosthetic part <NUM>.

<FIG> shows the hip joint in section when the artificial convex hip joint surface is fixated in the medical device <NUM> comprising a concave hip joint surface <NUM>. The convex hip joint surface <NUM> is secured in place by the locking member <NUM> which is fixated to the caput femur using screws <NUM>. The surface of the locking member <NUM> and the concave hip joint surface <NUM> is placed in connection with the convex hip joint surface and could be made of a friction reducing material such as PTFE or a self lubricating powder material. However it is also conceivable that the connecting surfaces are lubricated using an implantable lubrication system adapted to lubricate the medical device after said medical device has been implanted in the human patient.

<FIG> shows the placing of a prosthetic part <NUM> adapted to occupy the hole <NUM> created in the pelvic bone <NUM>. The prosthetic part <NUM> comprises supporting members <NUM> adapted to be in contact with the pelvic bone <NUM> and assist in the carrying of the load placed on the medical device from the weight of the human patient. According to the embodiment shown in <FIG> the supporting members <NUM> are located on the abdominal side of the pelvic bone <NUM>, however it is equally conceivable the supporting members <NUM> are located on the acetabulum side of the pelvic bone <NUM>, in which case they are preferably displaceable for allowing insertion of the prosthetic part <NUM> through the hole <NUM> in the pelvic bone <NUM>. Furthermore <FIG> shows the fixation of a nut <NUM> to the attachment rod <NUM>. According to the embodiment shown in <FIG> the hole <NUM> in the pelvic bone <NUM> is adapted to be larger than the medical device allowing the medical device to be inserted in its full functional size. According to other embodiments the hole <NUM> is smaller in which case the medical device could comprise of several parts adapted to be connected after insertion in the hip joint, or the medical device could be expandable for insertion through a hole smaller than the full functional size of the medical device. The expandable medical device could be enabled through the elements of the medical device comprising elastic material.

<FIG> shows the hip joint in section when all the elements of the medical device has been fixated in the area of the hip joint or its surroundings. The prosthetic part <NUM> adapted to occupy the hole <NUM> in the pelvic bone <NUM> is here fixated with screws <NUM>, however these screws <NUM> could be assisted or replaced by an adhesive which could be applied to the surface S between the prosthetic part and the pelvic bone <NUM>.

<FIG> shows the hip joint in section when the method of supplying the medical device is conducted according to another embodiment. The proximal part of the caput femur has been removed along the section created by the medical device for creating a hole. A reaming member <NUM> adapted to create a concave surface <NUM> in the caput femur <NUM> is here applied to a elongated member <NUM> which is inserted through a hole <NUM> going from the lateral side of the thigh, penetrating the cortical bone of the femoral bone <NUM> propagating along a length axis of the collum femur in the cancellous bone and entering the area of the hip joint. The elongated member <NUM> is operated using an operating device <NUM> which could be an electrically powered operating device, a hydraulically powered operating device or a pneumatically powered operating device. The reaming in the caput femur and part of the collum femur <NUM> is mainly performed in the cancellous bone, however that does not exclude the possibility the some of the reaming needs to be performed in the cortical bone of the caput femur <NUM> or the collum femur <NUM>.

<FIG> shows the step of providing a medical device <NUM> comprising an artificial concave hip joint surface <NUM>. The medical device is according to this embodiment provided with a hole positioned in the length axis of the collum femur <NUM>. The medical device is through the hole adapted to be guided by the elongated member <NUM> or a guiding rod placed in the hole <NUM> along a length axis of the collum femur <NUM>. Inserting the medical device into the hip joint while the elongated member <NUM> or guiding rod runs through the hole of the medical device facilitates the positioning of the medical device and ensures the different parts of the medical device is centered for functioning as a unit. In the embodiment shown in <FIG> the medical device <NUM> is inserted into the hip joint as a single unit, however it is equally conceivable that the medical device <NUM> is inserted in parts (not shown) which are then connected to form the medical device after implantation in the patient. The artificial concave hip joint surface <NUM> is fixated to the concave surface <NUM> created in the caput femur <NUM> and collum femur <NUM>. The medical device <NUM> comprises a fixation support <NUM> adapted to anchor said artificial concave hip joint surface <NUM>, to at least one of the caput femur <NUM> and the collum femur <NUM>. The medical device <NUM> is adapted to be introduced to the hip joint through a hole <NUM> in the pelvic bone <NUM> using a manipulation device <NUM> comprising a gripping member <NUM>. According to this embodiment the manipulation device <NUM> is bent and thereby adapted to operate through a hole <NUM> in the pelvic bone <NUM>. According to one embodiment the medical device <NUM> comprises a self lubricating material such as PTFE, however it is also conceivable that said medical device comprises: titanium, stainless steel, Corian, PE, or other acrylic polymers, in which case the medical device could be adapted to be lubricated after insertion in the hip joint.

<FIG> shows the hip joint in section when the artificial convex hip joint surface is fixated in the medical device <NUM> comprising a concave hip joint surface <NUM>, the medical device is guided using the elongated member <NUM> or a guiding rod. The convex hip joint surface <NUM> is secured in place by the locking member <NUM> which is fixated to the caput femur using screws <NUM>, the convex hip joint surface is guided using the elongated member <NUM> or a guiding rod. The surface of the locking member <NUM> and the concave hip joint surface <NUM> is placed in connection with the convex hip joint surface and could be made of a friction reducing material such as PTFE or a self lubricating powder material. However it is also conceivable that the connecting surfaces are lubricated using an implantable lubrication system adapted to lubricate the medical device after said medical device has been implanted in the human patient. The elongated member or guiding rod <NUM> can be adapted to act as a centering rod for centering the at least one artificial hip joint surface inside of the hip joint. According to the embodiment shown the elongated member <NUM> is inserted through the femoral bone, however according to other embodiments, not shown, the elongated member is positioned inside of the hip joint from the acetabulum side.

<FIG> shows the placing of a prosthetic part <NUM> adapted to occupy the hole <NUM> created in the pelvic bone <NUM>. The prosthetic part <NUM> comprises supporting members <NUM> adapted to be in contact with the pelvic bone <NUM> and assist in the carrying of the load placed on the medical device from the weight of the human patient. Furthermore <FIG> shows the fixation of a nut <NUM> to the attachment rod <NUM>, which in turn is guided by the elongated member <NUM> or a guiding rod.

<FIG> shows the hip joint in section when all the elements of the medical device has been fixated in the area of the hip joint or its surroundings. The prosthetic part <NUM> adapted to occupy the hole <NUM> in the pelvic bone <NUM> is here fixated with screws <NUM>, however these screws <NUM> could be assisted or replaced by an adhesive which could be applied to the surface S between the prosthetic part and the pelvic bone <NUM>. The elongated member <NUM> or guiding rod has been retracted through the incision in the thigh.

<FIG> shows an embodiment of a locking member <NUM>, wherein the locking member <NUM> comprises a surface adapted to be in contact with the artificial convex hip joint surface <NUM>, the locking member <NUM> is adapted to, in a first state, lock the artificial caput femur <NUM> to the artificial acetabulum surface <NUM>, and in a second state, release said artificial caput femur <NUM> from said artificial acetabulum <NUM>. The locking member <NUM> is adapted to change from the first to the second state when a predetermined amount of strain is placed on the locking member <NUM>. The locking member <NUM> according to the embodiment shown in <FIG>, comprises four elastic portions <NUM>, and the locking member <NUM> is adapted to change from the first to the second state using the elasticity of the elastic portions <NUM>. The locking member <NUM> is adapted to be fixated to the femoral bone <NUM> using screws adapted to be placed in holes <NUM> adapted therefor.

<FIG> shows the hip joint in section when a two state locking member <NUM> locks the artificial caput femur <NUM> in the artificial acetabulum <NUM>. The two state locking member <NUM> is fixated to the femoral bone <NUM> using screws <NUM>, and is here shown in its first state in which the locking member <NUM> locks the artificial caput femur <NUM> to the artificial acetabulum <NUM>.

<FIG> shows the hip joint in section according to the embodiment of <FIG>, but when the two state locking member <NUM> is in its second state, in which the locking ring <NUM> releases the artificial caput femur <NUM> from the artificial acetabulum surface <NUM>. The construction with the releasing locking ring <NUM> reduces the risk of strain placed on the artificial joint injuring the fixation points, i.e. the contact with bone; it further enables the artificial joint to be non-invasively relocated in case of luxation.

According to the above mentioned embodiments the medical device is adapted to be inserted through a hole in the pelvic bone, however it is equally conceivable that the medical device according to any of the embodiment above is adapted to be inserted through a hole in the hip joint capsule or the femoral bone of the human patient.

Claim 1:
A medical device for implantation in a hip joint of a human patient, the natural hip joint having a ball shaped caput femur (<NUM>) as the proximal part of the femoral bone (<NUM>) with a convex hip joint surface towards the center of the hip joint and a bowl shaped acetabulum (<NUM>) as part of the pelvic bone (<NUM>) with a concave hip joint surface towards the center of the hip joint, the medical device comprising;
an artificial caput femur (<NUM>), comprising a convex surface towards the center of the hip joint, wherein said artificial convex caput femur is adapted to, when implanted:
a. be fixated to the pelvic bone of the human patient, and
b. be in movable connection with an artificial acetabulum surface (<NUM>) fixated to the femoral bone of the patient, thereby forming a ball and socket joint,
wherein the medical device further comprises a fixation element (<NUM>) for fixating the medical device to the pelvic bone, wherein the fixation element (<NUM>) comprises a fixation surface (<NUM>) adapted to fit into the acetabulum of the pelvic bone,
characterized in that
the medical device comprises an elongated member (<NUM>) adapted to be inserted into a hole in the pelvic bone, and in that
the elongated member is adapted to be structurally changed on the abdominal side of the pelvic bone, such that it fixates the fixation element (<NUM>) to the pelvic bone when implanted.