Hip replacement

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Hip replacement
An X-ray showing a left hip (right of image) that has been replaced, with the ball of this ball-and-socket joint replaced by a metal head that is set in the femur and the socket replaced by a cup
Other namesHip arthroplasty
ICD-9-CM81.5181.53
MeSHD019644
MedlinePlus002975

Hip replacement is a surgical procedure in which the hip joint is replaced by a prosthetic implant, that is, a hip prosthesis. Hip replacement surgery can be performed as a total replacement or a hemi/semi(half) replacement. Such joint replacement orthopaedic surgery is generally conducted to relieve arthritis pain or in some hip fractures. A total hip replacement (total hip arthroplasty or THA) consists of replacing both the acetabulum and the femoral head while hemiarthroplasty generally only replaces the femoral head. Hip replacement is one of the most common orthopaedic operations, though patient satisfaction varies widely. Approximately 58% of total hip replacements are estimated to last 25 years.[1] The average cost of a total hip replacement in 2012 was $40,364 in the United States, and about $7,700 to $12,000 in most European countries.[2]

Medical uses[edit]

Total hip replacement is most commonly used to treat joint failure caused by osteoarthritis. Other indications include rheumatoid arthritis, avascular necrosis, traumatic arthritis, protrusio acetabuli, certain hip fractures, benign and malignant bone tumors, arthritis associated with Paget's disease, ankylosing spondylitis and juvenile rheumatoid arthritis. The aims of the procedure are pain relief and improvement in hip function. Hip replacement is usually considered only after other therapies, such as physical therapy and pain medications, have failed.[citation needed]

Risks[edit]

Risks and complications in hip replacement are similar to those associated with all joint replacements. They can include infection, dislocation, limb length inequality, loosening, impingement, osteolysis, metal sensitivity, nerve palsy, chronic pain and death. Weight loss surgery before a hip replacement does not appear to change outcomes.[3]

Follow-up assessments are conducted to examine the need for revision surgery. However, a UK study showed that only 3-6% of hip replacements needed a revision. Researchers recommended that routine follow-up may not be needed for up to 10 years. At this point, x-rays should be used to assess the joint, and there should be a clinical assessment of pain and mobility.[4][5]

Edema appears around the hip in the hours or days following the surgery. This swelling is typically at its maximum 7 days after the operation,[6] then decreases and disappears over the course of weeks. Only 5% of patients still have swelling 6 months after the operation.[7]

Dislocation[edit]

Dislocated artificial hip
Liner wear, particularly when over 2 mm, increases the risk of dislocation.[8] Liner creep, on the other hand, is normal remoulding.[9]

Dislocation (the ball coming out of the socket) is the most common complication. The most common causes vary by the duration since the surgery.[citation needed]

Hip prosthesis dislocation mostly occurs in the first three months after insertion, mainly because of incomplete scar formation and relaxed soft tissues.[8] It takes eight to twelve weeks for the soft tissues injured or cut during surgery to heal. The chance of this is diminished if less tissue is cut, if the cut tissue is repaired and if large diameter head balls are used.

Dislocations occurring between three months and five years after insertion usually occur due to malposition of the components, or dysfunction of nearby muscles.[8]

Risk factors of late dislocation (after five years) mainly include:[8]

  • Female sex
  • Younger age
  • Previous subluxation without complete dislocation
  • Previous trauma
  • Substantial weight loss
  • Recent onset or progression of dementia or a neurological disorder
  • Malposition of the cup
  • Liner wear, particularly when it allows head movement of more than 2 mm within the cup compared to its original position
  • Prosthesis loosening with migration

Surgeons who perform more operations tend to have fewer dislocations. An anterior approach seems to lower dislocation rates when small diameter heads are used, but that benefit has not been shown when compared to modern posterior incisions with the use of larger diameter heads. The use of larger diameter head size in itself decreases dislocation risk, even though this correlation is only found in head sizes up to 28 mm: larger heads do not result in a statistically significant decrease in dislocation rate.[10] Keeping the leg out of certain positions during the first few months after surgery further reduces risk.[citation needed]

Infection[edit]

Infection is one of the most common causes for revision of a total hip replacement. The incidence of infection in primary hip replacement is 1% or less in the United States.[11] Risk factors for infection include obesity, diabetes, smoking, immunosuppressive medications or diseases, and history of infection.[citation needed]

In revision surgery, infected tissue surrounding the joint is removed, and the artificial joint replaced. Typically, this is carried out in 2 stages: infected tissue and all joint replacement implants are removed in the first stage, and, after the infection is completely cleared, a new artificial joint is inserted in the second stage. One-stage surgery is also available whereby infected tissue and implants are removed, and the new joint inserted, in a single procedure. One-stage hip revisions were found to be as effective as two-stage procedures at relieving pain and improving hip stiffness and function. One-stage procedures were also better value for money.[12][13]

Limb length inequality[edit]

Most adults have a limb length inequality of 0–2 cm which causes no deficits.[14] It is common for people to sense a larger limb length inequality after total hip replacement.[15] Sometimes the leg seems long immediately after surgery when in fact both are equal length. An arthritic hip can develop contractures that make the leg behave as if it is short. When these are relieved with replacement surgery and normal motion and function are restored, the body feels that the limb is now longer than it was. This feeling usually subsides by six months after surgery as the body adjusts to the new hip joint. The cause of this feeling is variable, and usually related to abductor muscle weakness, pelvic obliquity, and minor lengthening of the hip during surgery (<1 cm) to achieve stability and restore the joint to pre-arthritic mechanics. If the limb length difference remains bothersome to the patient more than six months after surgery, a shoe lift can be used. Only in extreme cases is surgery required for correction.[citation needed] The perceived difference in limb length for a patient after surgery is a common cause for lawsuits against the healthcare provider.[16][17][18][19][20]

Fracture[edit]

Intraoperative acetabular fracture

Intraoperative fractures may occur. After surgery, bones with internal fixation devices in situ are at risk of periprosthetic fractures at the end of the implant, an area of relative mechanical stress. Post-operative femoral fractures are graded by the Vancouver classification.

Vein thrombosis[edit]

Venous thrombosis such as deep vein thrombosis and pulmonary embolism are relatively common following hip replacement surgery. Standard treatment with anticoagulants is for 7–10 days; however, treatment for 21+ days may be superior.[21][22] Extended-duration anticoagulants (up to 35 days following surgery) may prevent VTE in people undergoing hip replacement surgery.[22] Other research suggested that anticoagulants in otherwise healthy patients undergoing a so-called fast track protocol with hospital stays under five days, might only be necessary while in the hospital.[23] Emerging evidence supports the use of aspirin for venous thromboembolism prophylaxis. Large randomised control trials suggested that aspirin is not inferior to low-molecular weight heparins and rivaroxaban.[24][25] However, aspirin may not be appropriate in all cases, especially for patients who have additional risk factors for venous thromboembolisms or may have an inadequate response to aspirin.[26]

Some physicians and patients may consider having an ultrasonography for deep vein thrombosis after hip replacement.[27] However, this kind of screening should only be done when indicated because to perform it routinely would be unnecessary health care.[27]

Intermittent pneumatic compression (IPC) devices are sometimes used for prevention of blood clots following total hip replacement.[28]

Osteolysis[edit]

Many long-term problems with hip replacements are the result of osteolysis. This is the loss of bone caused by the body's reaction to polyethylene wear debris, fine bits of plastic that wear off the cup liner over time. An inflammatory process causes bone resorption that may lead to subsequent loosening of the hip implants and even fractures in the bone around the implants. Ceramic bearing surfaces may eliminate the generation of wear particles. Metal cup liners joined with metal heads (metal-on-metal hip arthroplasty) were developed for similar reasons. In the lab these show excellent wear characteristics and benefit from a different mode of lubrication.

Highly cross-linked polyethylene plastic liners experience significantly reduced plastic wear debris. The newer ceramic and metal prostheses may not have long-term performance records. Ceramic piece breakage can lead to catastrophic failure. This occurs in about 2% of implants. They may also cause an audible, high pitched squeaking noise with activity. Metal-on-metal arthroplasty can release metal debris into the body. Highly cross linked polyethylene is not as strong as regular polyethylene. These plastic liners can crack or break free of the metal shell that holds them.[citation needed]

Loosening[edit]

Hip prosthesis displaying aseptic loosening (arrows)
Hip prosthesis zones according to DeLee and Charnley,[29] and Gruen.[30] These are used to describe the location of for example areas of loosening.

On radiography, it is normal to see thin radiolucent areas of less than 2 mm around hip prosthesis components, or between a cement mantle and bone. These may indicate loosening of the prosthesis if they are new or changing, while areas greater than 2 mm may be harmless if they are stable.[31] The most important prognostic factors of cemented cups are absence of radiolucent lines in DeLee and Charnley zone I, as well as adequate cement mantle thickness.[32] In the first year after insertion of uncemented femoral stems, it is normal to have mild subsidence (less than 10 mm).[31] The direct anterior approach has been shown to itself be a risk factor for early femoral component loosening.[33][34][35]

Metal sensitivity[edit]

Concerns were raised in the early 2000s regarding metal sensitivity and the potential dangers of metal particulate debris from hip prostheses, including the development of pseudotumors, soft tissue masses containing necrotic tissue, around the hip joint. It appears these masses were more common in women, and these patients showed a higher level of iron in the blood. The cause was then unknown, and was probably multifactorial. There may have been a toxic reaction to an excess of particulate metal wear debris or a hypersensitivity reaction to a "normal" amount of metal debris.[36][37]

Metal hypersensitivity is a well-established phenomenon and is not uncommon, affecting about 10–15% of the population.[38] Skin contact with certain metals can cause immune reactions such as hives, eczema, redness and itching. Although little is known about the short- and long-term pharmacodynamics and bioavailability of circulating metal degradation products in vivo, there have been many reports of immunologic-type responses temporally associated with implantation of metal components. Individual case reports link immune hypersensitivity reactions with adverse performance of metallic cardiovascular, orthopedic and plastic surgical and dental implants.[38]

Metal toxicity[edit]

Most hip replacements consist of cobalt and chromium alloys, or titanium. Stainless steel is no longer used. Any metal implant releases its constituent ions into the blood. Typically, these are excreted in the urine, but in certain individuals the ions can accumulate in the body. In implants which involve metal-on-metal contact, microscopic fragments of cobalt and chromium can be absorbed into the person's bloodstream. There are reports of cobalt toxicity with hip replacement, particularly metal-on-metal hip replacements, which are no longer in use.[39][40]

Use of metal-on-metal hip replacements from the 1970s was discontinued in the 1980s and 1990s, particularly after the discovery of aseptic lymphocyte-dominant vasculitis-associated lesions (ALVAL). However, the FDA's 510k approval process allowed companies to have new and "improved" metal-on-metal hips approved without much clinical testing.[41] Some people with these prostheses experienced similar reactions to the metal debris as occurred in the 20th century; some devices were recalled.[42][43]

Nerve palsy[edit]

Post operative sciatic nerve palsy is another possible complication. The frequency of this complication is low. Femoral nerve palsy is another, but much rarer, complication. Both of these will typically resolve over time, but the healing process is slow. Patients with pre-existing nerve injury are at greater risk of experiencing this complication and are also slower to recover.[citation needed]

Chronic pain[edit]

A few patients who have had a hip replacement suffer chronic pain after the surgery. Groin pain can develop if the muscle that raises the hip (iliopsoas) rubs against the edge of the acetabular cup. Bursitis can develop at the trochanter where a surgical scar crosses the bone, or if the femoral component used pushes the leg out to the side too far. Also some patients can experience pain in cold or damp weather.[citation needed] Incision made in the front of the hip (anterior approach) can cut a nerve running down the thigh leading to numbness in the thigh and occasionally chronic pain at the point where the nerve was cut (a neuroma).

Death[edit]

The rate of perioperative mortality for elective hip replacements is significantly less than 1%.[44][45]

Metal-on-metal hip implant failure[edit]

By 2010, reports in the orthopaedic literature increasingly cited the problem of early failure of metal-on-metal prostheses in a small percentage of patients.[46] Failures may have related to the release of minute metallic particles or metal ions from wear on the implants, causing pain and disability severe enough to require revision surgery in 1–3% of patients.[47] Design deficits of some prothesis models, especially with heat-treated alloys and a lack of specialized surgical experience, accounted for most of the failures. In 2010, surgeons at medical centers such as the Mayo Clinic reported curtailing their use of metal-on-metal implants by 80 percent over the previous year, in favor of those made from other materials, such as combinations of metal and plastic.[48] The cause of these failures remains controversial, and may include both design factors, operative technique factors, and factors related to patient immune response. In the United Kingdom, the Medicines and Healthcare products Regulatory Agency commenced an annual monitoring regime for metal-on-metal hip replacement patients from May 2010.[49] Data which are shown in The Australian Orthopaedic Association's 2008 National Joint replacement registry, a record of nearly every hip implanted in that country over the previous 10 years, tracked 6,773 BHR (Birmingham Hip Resurfacing) hips and found that less than 0.33% may have been revised due to the patient's reaction to the metal component.[50] Other, similar, metal-on-metal designs have not fared as well, with some reports showing that 76–100% of people with these metal-on-metal implants with aseptic implant failures and needing revision surgery also had histological evidence of inflammation, accompanied by extensive lymphocyte infiltrates characteristic of delayed-type hypersensitivity reactions.[51] It is not clear to what extent this phenomenon negatively affects orthopedic implant patients. However, for patients presenting with signs of allergic reaction, testing for sensitivity should be conducted. Removal of the device should be considered, since removal may alleviate the symptoms. Patients who have allergic reactions to alloy jewelry are more likely to have reactions to orthopedic implants. There is increasing awareness of the phenomenon of metal sensitivity, and many surgeons now take this into account when planning which implant is optimal for each patient.

On March 12, 2012, The Lancet published a study, based on data from the National Joint Registry of England and Wales, finding that metal-on-metal hip implants failed at much higher rates than other types of hip implants, and calling for a ban on all metal-on-metal hip prostheses.[52] The analysis of 402,051 hip replacements showed that 6.2% of metal-on-metal hip implants had failed within five years, compared to 1.7% of metal-on-plastic and 2.3% of ceramic-on-ceramic hip implants. Each 1 mm (0.039 in) increase in head size of metal-on-metal hip implants was associated with a 2% increase in failure rate.[53] Surgeons of the British Hip Society recommended that large head metal-on-metal implants should no longer be implanted.[54][55]

On February 10, 2011, the U.S. FDA issued an advisory on metal-on-metal hip implants, stating it was continuing to gather and review all available information about metal-on-metal hip systems.[56] On June 27–28, 2012, an advisory panel met to decide whether to impose new standards, taking into account findings of the study in The Lancet.[40][57][58] No new standards, such as routine checking of blood levels of metal ions, were set, but guidance was updated.[59] The U.S. FDA does not require hip implants to be tested in clinical trials before they can be sold in the U.S.[60] Instead, companies making new hip implants only need to prove that they are "substantially equivalent" to other hip implants already on the market. The exception is metal-on-metal implants, which were not tested in clinical trials, but, due to the high revision rate of metal-on-metal hips, the FDA has stated that, in the future, clinical trials will be required for approval, and that post-market studies will be required to keep metal-on-metal hip implants on the market.[61]

Modern process[edit]

Hip prosthesis 3D model
Different parts of hip prosthesis
A titanium hip prosthesis, with a ceramic head and polyethylene acetabular cup

The modern artificial joint owes much to the 1962 work of Sir John Charnley at Wrightington Hospital in the United Kingdom. His work in the field of tribology resulted in a design that almost completely replaced the other designs by the 1970s. Charnley's design consisted of three parts:

  1. stainless steel one-piece femoral stem and head
  2. polyethylene (originally Teflon), acetabular component, both of which were fixed to the bone using
  3. PMMA (acrylic) bone cement

The replacement joint, which was known as the Low Friction Arthroplasty, was lubricated with synovial fluid. The small femoral head (78 in (22.2 mm)) was chosen for Charnley's belief that it would have lower friction against the acetabular component and thus wear out the acetabulum more slowly. Unfortunately, the smaller head dislocated more easily. Alternative designs with larger heads such as the Mueller prosthesis were proposed. Stability was improved, but acetabular wear and subsequent failure rates were increased with these designs. The Teflon acetabular components of Charnley's early designs failed within a year or two of implantation. This prompted a search for a more suitable material. A German salesman showed a polyethylene gear sample to Charnley's machinist, sparking the idea to use this material for the acetabular component. The UHMWPE acetabular component was introduced in 1962. Charnley's other major contribution was to use polymethylmethacrylate (PMMA) bone cement to attach the two components to the bone. For over two decades, the Charnley Low Friction Arthroplasty, and derivative designs were the most used systems in the world. It formed the basis for all modern hip implants. An example can be seen at the Science Museum, London.[62]

The Exeter hip stem was developed in the United Kingdom during the same time as the Charnley device. Its development occurred following a collaboration between Orthopaedic Surgeon Robin Ling and University of Exeter engineer Clive Lee and it was first implanted at the Princess Elizabeth Orthopaedic Hospital in Exeter in 1970.[63] The Exeter Hip is a cemented device, but with a slightly different stem geometry. Both designs have shown excellent long-term durability when properly placed and are still widely used in slightly modified versions.

Early implant designs had the potential to loosen from their attachment to the bones, typically becoming painful ten to twelve years after placement. In addition, erosion of the bone around the implant was seen on x-rays. Initially, surgeons believed this was caused by an abnormal reaction to the cement holding the implant in place. That belief prompted a search for an alternative method to attach the implants. The Austin Moore device had a small hole in the stem into which bone graft was placed before implanting the stem. It was hoped bone would then grow through the window over time and hold the stem in position. Success was unpredictable and the fixation not very robust. In the early 1980s, surgeons in the United States applied a coating of small beads to the Austin Moore device and implanted it without cement. The beads were constructed so that gaps between beads matched the size of the pores in native bone. Over time, bone cells from the patient would grow into these spaces and fix the stem in position. The stem was modified slightly to fit more tightly into the femoral canal, resulting in the Anatomic Medullary Locking (AML) stem design. With time, other forms of stem surface treatment and stem geometry have been developed and improved.

Initial hip designs were made of a one-piece femoral component and a one-piece acetabular component. Current designs have a femoral stem and separate head piece. Using an independent head allows the surgeon to adjust leg length (some heads seat more or less onto the stem) and to select from various materials from which the head is formed. A modern acetabulum component is also made up of two parts: a metal shell with a coating for bone attachment and a separate liner. First the shell is placed. Its position can be adjusted, unlike the original cemented cup design which are fixed in place once the cement sets. When proper positioning of the metal shell is obtained, the surgeon may select a liner made from various materials.

To combat loosening caused by polyethylene wear debris, hip manufacturers developed improved and novel materials for the acetabular liners. Ceramic heads mated with regular polyethylene liners or a ceramic liner were the first significant alternative. Metal liners to mate with a metal head were also developed. At the same time these designs were being developed, the problems that caused polyethylene wear were determined and manufacturing of this material improved. Highly crosslinked UHMWPE was introduced in the late 1990s. The most recent data comparing the various bearing surfaces has shown no clinically significant differences in their performance. Potential early problems with each material are discussed below. Performance data after 20 or 30 years may be needed to demonstrate significant differences in the devices. All newer materials allow use of larger diameter femoral heads. Use of larger heads significantly decreases the chance of the hip dislocating, which remains the greatest complication of the surgery.

When available implants are used, cemented stems tend to have a better longevity than uncemented stems. No significant difference is observed in the clinical performance of the various methods of surface treatment of uncemented devices. Uncemented stems are selected for patients with good quality bone that can resist the forces needed to drive the stem in tightly. Cemented devices are typically selected for patients with poor quality bone who are at risk of fracture during stem insertion. Cemented stems are less expensive due to lower manufacturing cost, but require good surgical technique to place them correctly. Uncemented stems can cause pain with activity in up to 20% of patients during the first year after placement as the bone adapts to the device. This is rarely seen with cemented stems.[citation needed]

Techniques[edit]

There are several incisions, defined by their relation to the gluteus medius. The approaches are posterior (Moore), lateral (Hardinge or Liverpool),[64] antero-lateral (Watson-Jones),[65] anterior (Smith-Petersen)[66] and greater trochanter osteotomy. There is no compelling evidence in the literature for any particular approach.

Posterior approach[edit]

The posterior (Moore or Southern) approach accesses the joint and capsule through the back, taking piriformis muscle and the short external rotators of the femur. This approach gives excellent access to the acetabulum and femur and preserves the hip abductors and thus minimizes the risk of abductor dysfunction post operatively. It has the advantage of becoming a more extensile approach if needed. Critics cite a higher dislocation rate, although repair of the capsule, piriformis and the short external rotators along with use of modern large diameter head balls reduces this risk. Limited evidence suggests that the posterior approach may cause less nerve damage.[67]

Lateral approach[edit]

The lateral approach is also commonly used for hip replacement. The approach requires elevation of the hip abductors (gluteus medius and gluteus minimus) to access the joint. The abductors may be lifted up by osteotomy of the greater trochanter and reapplying it afterwards using wires (as per Charnley),[citation needed] or may be divided at their tendinous portion, or through the functional tendon (as per Hardinge) and repaired using sutures. Although this approach has a lower dislocation risk than the posterior approach, critics note that occasionally the abductor muscles do not heal back on, leading to pain and weakness which is often very difficult to treat.

Antero-lateral approach[edit]

The anterolateral approach develops the interval between the tensor fasciae latae and the gluteus medius. The Gluteus medius, gluteus minimus and hip capsule are detached from the anterior (front) for the greater trochanter and femoral neck and then repaired with heavy suture after the replacement of the joint.

Anterior approach[edit]

The anterior approach uses an interval between the sartorius muscle and tensor fasciae latae. This approach, which was commonly used for pelvic fracture repair surgery, has been adapted for use when performing hip replacement. When used with older hip implant systems that had a small diameter head, dislocation rates were reduced compared to surgery performed through a posterior approach. With modern implant designs, dislocation rates are similar between the anterior and posterior approaches.[68] The anterior approach has been shown in studies to variably improve early functional recovery, with possible complications of femoral component loosening and early revision compared to other approaches.[35][33][69][70][71][72]

Minimally invasive approaches[edit]

The dual incision approach and other minimally invasive surgery seeks to reduce soft tissue damage through reducing the size of the incision. However, component positioning accuracy and visualization of the bone structures can be significantly impaired as the approaches get smaller. This can result in unintended fractures and soft tissue injury. The majority of current orthopedic surgeons use a "minimally invasive" approach compared to traditional approaches which were quite large comparatively.

Computer-assisted surgery and robotic surgery techniques are also available to guide the surgeon to provide enhanced component accuracy.[73] Several commercial CAS and robotic systems are available for use worldwide. Improved patient outcomes and reduced complications have not been demonstrated when these systems are used when compared to standard techniques.[74][75]

Implants[edit]

Metal on metal prosthetic hip
Cement-free implant sixteen days after surgery. Femoral component is cobalt chromium combined with titanium which induces bone growth into the implant. Ceramic head. Acetabular cup coated with bone growth-inducing material and held temporarily in place with a single screw.

The prosthetic implant used in hip replacement consists of three parts: the acetabular cup, the femoral component, and the articular interface. Options exist for different people and indications. The evidence for a number of newer devices is not very good, including: ceramic-on-ceramic bearings, modular femoral necks, and uncemented monoblock cups.[76] Correct selection of the prosthesis is important.

Acetabular cup[edit]

The acetabular cup is the component which is placed into the acetabulum (hip socket). Cartilage and bone are removed from the acetabulum and the acetabular cup is attached using friction or cement. Some acetabular cups are one piece, while others are modular. One-piece (monobloc) shells are either ultra-high-molecular-weight polyethylene (UHMWPE) or metal, they have their articular surface machined on the inside surface of the cup and do not rely on a locking mechanism to hold a liner in place. A monobloc polyethylene cup is cemented in place while a metal cup is held in place by a metal coating on the outside of the cup. Modular cups consist of two pieces, a shell and liner. The shell is made of metal; the outside has a porous coating while the inside contains a locking mechanism designed to accept a liner. Two types of porous coating used to form a friction fit are sintered beads and a foam metal design to mimic the trabeculae of cancellous bone and initial stability is influenced by under-reaming and insertion force.[77] Permanent fixation is achieved as bone grows onto or into the porous coating. Screws can be used to lag the shell to the bone providing even more fixation. Polyethylene liners are placed into the shell and connected by a rim locking mechanism; ceramic and metal liners are attached with a Morse taper.[citation needed]

Femoral component[edit]

The femoral component is the component that fits in the femur (thigh bone). Bone is removed and the femur is shaped to accept the femoral stem with attached prosthetic femoral head (ball). There are two types of fixation: cemented and uncemented. Cemented stems use acrylic bone cement to form a mantle between the stem and to the bone. Uncemented stems use friction, shape and surface coatings to stimulate bone to remodel and bond to the implant. Stems are made of multiple materials (titanium, cobalt chromium, stainless steel, and polymer composites) and they can be monolithic or modular. Modular components consist of different head dimensions and/or modular neck orientations; these attach via a taper similar to a Morse taper. These options allow for variability in leg length, offset and version. Femoral heads are made of metal or ceramic material. Metal heads, made of cobalt chromium for hardness, are machined to size and then polished to reduce wear of the socket liner. Ceramic heads are more smooth than polished metal heads, have a lower coefficient of friction than a cobalt chrome head, and in theory will wear down the socket liner more slowly. As of early 2011, follow-up studies in patients have not demonstrated significant reductions in wear rates between the various types of femoral heads on the market. Ceramic implants are more brittle and may break after being implanted.

Articular interface[edit]

The articular interface is not part of either implant, rather it is the area between the acetabular cup and femoral component. The articular interface of the hip is a simple ball and socket joint. Size, material properties and machining tolerances at the articular interface can be selected based on patient demand to optimise implant function and longevity whilst mitigating associated risks. The interface size is measured by the outside diameter of the head or the inside diameter of the socket. Common sizes of femoral heads are 28 mm (1.1 in), 32 mm (1.3 in) and 36 mm (1.4 in). While 22.25 mm (78 in) was common in the first modern prostheses, now even larger sizes are available from 38 to over 54 mm. Larger-diameter heads lead to increased stability and range of motion whilst lowering the risk of dislocation. At the same time they are also subject to higher stresses such as friction and inertia. Different combinations of materials have different physical properties which can be coupled to reduce the amount of wear debris generated by friction. Typical pairings of materials include metal on polyethylene (MOP), metal on crosslinked polyethylene (MOXP), ceramic on ceramic (COC), ceramic on crosslinked polyethylene (COXP), and metal on metal (MOM). Each combination has different advantages and disadvantages.

Dual mobility hip replacements reduce the risk of dislocation.[78][79]

Configuration[edit]

Post-operative projectional radiography is routinely performed to ensure proper configuration of hip prostheses.

The direction of the acetabular cup influences the range of motion of the leg, and also affects the risk of dislocation.[9] For this purpose, the acetabular inclination and the acetabular anteversion are measurements of cup angulation in the coronal plane and the sagittal plane, respectively.

Alternatives and variations[edit]

Conservative management[edit]

The first line approach as an alternative to hip replacement is conservative management which involves a multimodal approach of oral medication, injections, activity modification and physical therapy.[82] Conservative management can prevent or delay the need for hip replacement.

Preoperative care[edit]

Preoperative education is an important part of patient care. Some evidence indicates that it may slightly reduce anxiety before hip or knee replacement, with low risk of negative effects.[83]

Hemiarthroplasty[edit]

Femoral (neck) offset is defined as the perpendicular distance between the intramedullary or longitudinal axis of the femur and the center of rotation of the native or prosthetic femoral head. An offset of less than 33 mm is associated with hip dislocation.[84][85]

Hemiarthroplasty is a surgical procedure that replaces one half of the joint with an artificial surface and leaves the other part unchanged. This class of procedure is most commonly performed on the hip after an intracapsular fracture of the femur neck (hip fracture). The procedure is performed by removing the head of the femur and replacing it with a metal or composite prosthesis. The most commonly used prosthesis designs are the Austin Moore and Thompson prostheses. A composite of metal and HDPE that forms two interphases (bipolar prosthesis) can be used. The monopolar prosthesis has not been shown to offer any advantage over bipolar designs. The procedure is recommended only for elderly/frail patients, due to their lower life expectancy and activity level. This is because over time the prosthesis tends to loosen or to erode the acetabulum.[86] Independently mobile older adults with hip fractures may benefit from a total hip replacement instead of hemiarthroplasty.[87]

Hip resurfacing[edit]

Hip resurfacing is an alternative to hip replacement surgery. It has been used in Europe since 1998 and became a common procedure. Health-related quality of life measures are markedly improved and patient satisfaction is favorable after hip resurfacing arthroplasty.[88]

The minimally invasive hip resurfacing procedure is a further refinement to hip resurfacing.

Viscosupplementation[edit]

Viscosupplementation is the injection of artificial lubricants into the joint.[89] Use of these medications in the hip is off label. The cost of treatment is typically not covered by health insurance.

Some authorities claim that the future of osteoarthritis treatment is bioengineering, targeting the growth and/or repair of the damaged, arthritic joint. Centeno et al. reported on the partial regeneration of an arthritic human hip joint using mesenchymal stem cells.[90] It is yet to be shown that this result will apply to a large group of patients and result in significant benefits. The FDA stated that this procedure does not conform to regulations, but Centeno claims that it is exempt from FDA regulation. It has not been shown in controlled clinical trials to be effective.[citation needed]

Prevalence and cost[edit]

Total hip replacement incidence varies in developed countries between 30 (Romania) and 290 (Germany) procedures per 100,000 population per year.[91] Approximately 0.8% of Americans have undergone the procedure.[92]

According to the International Federation of Healthcare Plans, the average cost of a total hip replacement in 2012 was $40,364 in the United States, $11,889 in the United Kingdom, $10,987 in France, $9,574 in Switzerland, and $7,731 in Spain.[2] In the United States, the average cost of a total hip replacement varies widely by geographic region, ranging from $11,327 (Birmingham, Alabama) to $73,927 (Boston, Massachusetts).[93]

History[edit]

Gosset-style hip prosthesis from 1960

The earliest recorded attempts at hip replacement were carried out in Germany in 1891 by Themistocles Gluck (1853–1942),[94][95] who used ivory to replace the femoral head (the ball on the femur), attaching it with nickel-plated screws.[96] Subsequently, he used a cement made from plaster of Paris, powdered pumice and glue.[97]

Molded-glass implants were introduced in the 1920s by Smith-Peterson in the USA. Although these showed good bio-compatibility, they were mechanically fragile so he started experiments with metallic prostheses in the 1930s.[97][98] In 1938, Philip Wiles of Middlesex General Hospital, UK carried out a total hip replacement using a stainless-steel prosthesis attached by bolts.[99] In 1940, Dr. Austin T. Moore (1899–1963)[100] at Columbia Hospital in Columbia, South Carolina performed a hip replacement using a prototype prosthesis made of the cobalt-chrome alloy Vitallium; it was inserted into the medullary canal and "fenestrated" to promote bone regrowth. A commercial version known as the "Austin Moore Prosthesis" was introduced in 1952; it is still in use today, typically for femoral neck fractures in the elderly.[97] Following the lead of Wiles, several UK general hospitals including Norwich, Wrightington, Stanmore, Redhill and Exeter developed metal-based prostheses during the 1950s and 1960s.[99]

Robert Juditt was the first to perform hip replacements via the anterior approach in 1947 in Paris. He taught this method to Émile Letournel [fr]. Joel Matta, who had studied with Letournel, brought this approach to the United States and went on to popularize it.[101]

Metal/Acrylic prostheses were tried in the 1950s [97][102] but were found to be susceptible to wear.  In the 1960s, John Charnley[103][97][98] at Wrightington General Hospital combined a metal prosthesis with a PTFE acetabular cup before settling on a metal/polyethylene design. Ceramic bearings were developed in the late 1970s.[97][98]

The means of attachment have also diversified.[97][98]  Early prostheses were attached by screws (e.g. Gluck, Wiles) with later developments using dental or bone cements (e.g. Charnley, Thompson[104][105]) or cementless systems which relied on bone regrowth (Austin-Moore,[106] Ring[98]). The choice of alloy, bearing material, attachment and detailed geometry has led to the wide variety of prosthesis designs available today.[97][98][99]

The London Science Museum has a collection of hip prostheses which reflect developments in the US, UK and elsewhere. These show the use of different materials and different designs for different circumstances (e.g. cemented and uncemented arthroplasty.)  Some are on display in the museum's "Medicine: The Wellcome Galleries". 

Hip prostheses on display in the London Science Museum

The items include:

  • Prosthesis from 1960: The "Gosset-style" prosthesis was first introduced in 1949, although the specific example was made by Lusterlite Ltd of Leeds in 1960.  It has a perspex "ball" and simple rod-like shaft made of nickel-plated stainless-steel.[102]
  • Examples of prostheses from 1970 to 1985: Examples provided by Ipswich Hospital, UK are made of Vitallium (Co/Cr alloy) with curved standard or slender femoral stems.[107][108] One example has a studded cup.[109]
  • Examples of prostheses from the 1990s: Examples, some of which were developed at the Redhill Group of Hospitals and Dorking Hospital, include a ringed titanium hip prosthesis with a screw stem and porous cup,[110] a modular hip prosthesis with a textured femoral stem to aid bone grafting (material unspecified),[111] two Thompson-type prostheses made of Vitallium alloy[104][105] and an Austin Moore type prosthesis (material unspecified), with a porous metal femoral stem.[106]
  • Example of acetabular cup prosthesis from 1998: Example of a prosthetic socket, from Sulzer Orthopedics Inc., is the Inter-Op Hemispherical Shell. This is made from materials not recognised by the human body, so the body's immune system does not attack and reject the joint.[112]
  • Examples of prostheses from 2006: Examples made by Smith & Nephew Orthopedics include an "Anthology" titanium prosthesis, which has a flat-tapered stem placed in the thigh bone, and an "Echelon" (cobalt-chrome prosthesis for both cementless and cemented arthroplasty. Both have porous coating to promote bone adhesion.[113][114]

The Science Museum's collection also includes specialised surgical tools for hip operations:

Other animals[edit]

See also[edit]

References[edit]

  1. ^ Evans JT, Evans JP, Walker RW, Blom AW, Whitehouse MR, Sayers A (February 2019). "How long does a hip replacement last? A systematic review and meta-analysis of case series and national registry reports with more than 15 years of follow-up". Lancet. 393 (10172): 647–654. doi:10.1016/S0140-6736(18)31665-9. PMC 6376618. PMID 30782340.
  2. ^ a b "2012 comparative price report" (PDF). International Federation of Health Plans. Retrieved 4 October 2015.
  3. ^ Smith TO, Aboelmagd T, Hing CB, MacGregor A (September 2016). "Does bariatric surgery prior to total hip or knee arthroplasty reduce post-operative complications and improve clinical outcomes for obese patients? Systematic review and meta-analysis" (PDF). The Bone & Joint Journal. 98-B (9): 1160–1166. doi:10.1302/0301-620x.98b9.38024. PMID 27587514.
  4. ^ "Joint replacements: many people can safely wait 10 years for follow-up". NIHR Evidence. 11 January 2023. doi:10.3310/nihrevidence_55501. S2CID 257843402.
  5. ^ Kingsbury SR, Smith LK, Czoski Murray CJ, Pinedo-Villanueva R, Judge A, West R, et al. (2022-06-01). "Safety of disinvestment in mid- to late-term follow-up post primary hip and knee replacement: the UK SAFE evidence synthesis and recommendations". Health and Social Care Delivery Research. 10 (16): 1–172. doi:10.3310/KODQ0769. PMID 35767667. S2CID 250133111.
  6. ^ Holm B, Kristensen MT, Husted H, Kehlet H, Bandholm T (February 2011). "Thigh and knee circumference, knee-extension strength, and functional performance after fast-track total hip arthroplasty". PM&R. 3 (2): 117–24, quiz 124. doi:10.1016/j.pmrj.2010.10.019. PMID 21333950. S2CID 21003271.
  7. ^ Heo SM, Harris I, Naylor J, Lewin AM (September 2020). "Complications to 6 months following total hip or knee arthroplasty: observations from an Australian clinical outcomes registry". BMC Musculoskeletal Disorders. 21 (1): 602. doi:10.1186/s12891-020-03612-8. PMC 7488141. PMID 32912197.
  8. ^ a b c d Berry DJ, Lieberman J (2012). Surgery of the Hip. Elsevier Health Sciences. p. 1035. ISBN 9781455727056.
  9. ^ a b c d e f g h Watt I, Boldrik S, van Langelaan E, Smithuis R. "Hip – Arthroplasty – Normal and abnormal imaging findings". Radiology Assistant. Retrieved 2017-05-21.
  10. ^ Hailer NP, Weiss RJ, Stark A, Kärrholm J (October 2012). "The risk of revision due to dislocation after total hip arthroplasty depends on surgical approach, femoral head size, sex, and primary diagnosis. An analysis of 78,098 operations in the Swedish Hip Arthroplasty Register". Acta Orthopaedica. 83 (5): 442–448. doi:10.3109/17453674.2012.733919. PMC 3488169. PMID 23039167.
  11. ^ Bozic KJ, Kurtz SM, Lau E, Ong K, Vail TP, Berry DJ (January 2009). "The epidemiology of revision total hip arthroplasty in the United States". The Journal of Bone and Joint Surgery. American Volume. 91 (1): 128–133. doi:10.2106/JBJS.H.00155. PMID 19122087.
  12. ^ "One-stage hip revisions are as good as 2-stage surgery to replace infected artificial hips". NIHR Evidence. 2023-04-25. doi:10.3310/nihrevidence_57776. S2CID 258340248.
  13. ^ Blom AW, Lenguerrand E, Strange S, Noble SM, Beswick AD, Burston A, et al. (October 2022). "Clinical and cost effectiveness of single stage compared with two stage revision for hip prosthetic joint infection (INFORM): pragmatic, parallel group, open label, randomised controlled trial". BMJ. 379: e071281. doi:10.1136/bmj-2022-071281. PMC 9645409. PMID 36316046.
  14. ^ Knutson GA (July 2005). "Anatomic and functional leg-length inequality: a review and recommendation for clinical decision-making. Part I, anatomic leg-length inequality: prevalence, magnitude, effects and clinical significance". Chiropractic & Osteopathy. 13 (1): 11. doi:10.1186/1746-1340-13-11. PMC 1232860. PMID 16026625.
  15. ^ Maloney WJ, Keeney JA (June 2004). "Leg length discrepancy after total hip arthroplasty". The Journal of Arthroplasty. 19 (4 Suppl 1): 108–110. doi:10.1016/j.arth.2004.02.018. PMID 15190563.
  16. ^ McWilliams AB, Douglas SL, Redmond AC, Grainger AJ, O'Connor PJ, Stewart TD, Stone MH (January 2013). "Litigation after hip and knee replacement in the National Health Service" (PDF). The Bone & Joint Journal. 95-B (1): 122–126. doi:10.1302/0301-620X.95B1.30908. PMID 23307685.
  17. ^ Hofmann AA, Skrzynski MC (September 2000). "Leg-length inequality and nerve palsy in total hip arthroplasty: a lawyer awaits!". Orthopedics. 23 (9): 943–944. doi:10.3928/0147-7447-20000901-20. PMID 11003095.
  18. ^ Upadhyay A, York S, Macaulay W, McGrory B, Robbennolt J, Bal BS (September 2007). "Medical malpractice in hip and knee arthroplasty". The Journal of Arthroplasty. 22 (6 Suppl 2): 2–7. doi:10.1016/j.arth.2007.05.003. PMID 17823005.
  19. ^ Konyves A, Bannister GC (February 2005). "The importance of leg length discrepancy after total hip arthroplasty". The Journal of Bone and Joint Surgery. British Volume. 87 (2): 155–157. doi:10.1302/0301-620X.87B2.14878. PMID 15736733.
  20. ^ O'Leary R, Saxena A, Arguelles W, Hernandez Y, Osondu CU, Suarez JC (December 2022). "Digital Fluoroscopic Navigation for Limb Length Restoration During Anterior Total Hip Arthroplasty". Arthroplasty Today. 18: 11–15. doi:10.1016/j.artd.2022.08.021. PMC 9576486. PMID 36267390.
  21. ^ Sobieraj DM, Lee S, Coleman CI, Tongbram V, Chen W, Colby J, et al. (May 2012). "Prolonged versus standard-duration venous thromboprophylaxis in major orthopedic surgery: a systematic review". Annals of Internal Medicine. 156 (10): 720–727. doi:10.7326/0003-4819-156-10-201205150-00423. PMID 22412039. S2CID 22797561.
  22. ^ a b Forster R, Stewart M, et al. (Cochrane Vascular Group) (March 2016). "Anticoagulants (extended duration) for prevention of venous thromboembolism following total hip or knee replacement or hip fracture repair". The Cochrane Database of Systematic Reviews. 2016 (3): CD004179. doi:10.1002/14651858.CD004179.pub2. hdl:20.500.11820/3f5a887a-031a-43bd-8406-b85ab02d6618. PMC 10332795. PMID 27027384.
  23. ^ Jørgensen CC, Jacobsen MK, Soeballe K, Hansen TB, Husted H, Kjærsgaard-Andersen P, et al. (December 2013). "Thromboprophylaxis only during hospitalisation in fast-track hip and knee arthroplasty, a prospective cohort study". BMJ Open. 3 (12): e003965. doi:10.1136/bmjopen-2013-003965. PMC 3863129. PMID 24334158.
  24. ^ Anderson DR, Dunbar MJ, Bohm ER, Belzile E, Kahn SR, Zukor D, et al. (June 2013). "Aspirin versus low-molecular-weight heparin for extended venous thromboembolism prophylaxis after total hip arthroplasty: a randomized trial". Annals of Internal Medicine. 158 (11): 800–806. doi:10.7326/0003-4819-158-11-201306040-00004. PMID 23732713. S2CID 207536641.
  25. ^ Anderson DR, Dunbar M, Murnaghan J, Kahn SR, Gross P, Forsythe M, et al. (February 2018). "Aspirin or Rivaroxaban for VTE Prophylaxis after Hip or Knee Arthroplasty". The New England Journal of Medicine. 378 (8): 699–707. doi:10.1056/NEJMoa1712746. PMID 29466159. S2CID 3625978.
  26. ^ van Oosterom N, Barras M, Bird R, Nusem I, Cottrell N (December 2020). "A Narrative Review of Aspirin Resistance in VTE Prophylaxis for Orthopaedic Surgery". Drugs. 80 (18): 1889–1899. doi:10.1007/s40265-020-01413-w. PMID 33037568. S2CID 222234431.
  27. ^ a b American Academy of Orthopaedic Surgeons (February 2013), "Five Things Physicians and Patients Should Question", Choosing Wisely: an initiative of the ABIM Foundation, American Academy of Orthopaedic Surgeons, retrieved 19 May 2013, which cites
  28. ^ Zhao JM, He ML, Xiao ZM, Li TS, Wu H, Jiang H, et al. (Cochrane Vascular Group) (December 2014). "Different types of intermittent pneumatic compression devices for preventing venous thromboembolism in patients after total hip replacement". The Cochrane Database of Systematic Reviews. 2014 (12): CD009543. doi:10.1002/14651858.CD009543.pub3. PMC 7100582. PMID 25528992.
  29. ^ Callaghan JJ, Rosenberg AG, Rubash HE (2007). The Adult Hip, Volume 1. Lippincott Williams & Wilkins. p. 958. ISBN 978-0-7817-5092-9.
  30. ^ Neumann DR, Thaler C, Hitzl W, Huber M, Hofstädter T, Dorn U (August 2010). "Long-term results of a contemporary metal-on-metal total hip arthroplasty: a 10-year follow-up study". The Journal of Arthroplasty. 25 (5): 700–708. doi:10.1016/j.arth.2009.05.018. PMID 19596544.
  31. ^ a b Roth TD, Maertz NA, Parr JA, Buckwalter KA, Choplin RH (2012). "CT of the hip prosthesis: appearance of components, fixation, and complications". Radiographics. 32 (4): 1089–1107. doi:10.1148/rg.324115183. PMID 22786996.
  32. ^ Breusch S, Malchau H (2005). The Well-Cemented Total Hip Arthroplasty: Theory and Practice. Springer Science & Business Media. p. 336. ISBN 978-3-540-24197-3.
  33. ^ a b Eto S, Hwang K, Huddleston JI, Amanatullah DF, Maloney WJ, Goodman SB (March 2017). "The Direct Anterior Approach is Associated With Early Revision Total Hip Arthroplasty". The Journal of Arthroplasty. 32 (3): 1001–1005. doi:10.1016/j.arth.2016.09.012. PMID 27843039.
  34. ^ Angerame MR, Fehring TK, Masonis JL, Mason JB, Odum SM, Springer BD (June 2018). "Early Failure of Primary Total Hip Arthroplasty: Is Surgical Approach a Risk Factor?". The Journal of Arthroplasty. 33 (6): 1780–1785. doi:10.1016/j.arth.2018.01.014. PMID 29439894. S2CID 29149705.
  35. ^ a b Meneghini RM, Elston AS, Chen AF, Kheir MM, Fehring TK, Springer BD (January 2017). "Direct Anterior Approach: Risk Factor for Early Femoral Failure of Cementless Total Hip Arthroplasty: A Multicenter Study". The Journal of Bone and Joint Surgery. American Volume. 99 (2): 99–105. doi:10.2106/JBJS.16.00060. PMID 28099299. S2CID 6299470.
  36. ^ Pandit H, Glyn-Jones S, McLardy-Smith P, Gundle R, Whitwell D, Gibbons CL, et al. (July 2008). "Pseudotumours associated with metal-on-metal hip resurfacings". The Journal of Bone and Joint Surgery. British Volume. 90 (7): 847–851. doi:10.1302/0301-620X.90B7.20213. PMID 18591590.
  37. ^ Boardman DR, Middleton FR, Kavanagh TG (March 2006). "A benign psoas mass following metal-on-metal resurfacing of the hip". The Journal of Bone and Joint Surgery. British Volume. 88 (3): 402–404. doi:10.1302/0301-620X.88B3.16748. PMID 16498023.
    Korovessis P, Petsinis G, Repanti M, Repantis T (June 2006). "Metallosis after contemporary metal-on-metal total hip arthroplasty. Five to nine-year follow-up". The Journal of Bone and Joint Surgery. American Volume. 88 (6): 1183–1191. doi:10.2106/JBJS.D.02916. PMID 16757749.
  38. ^ a b Hallab N, Merritt K, Jacobs JJ (March 2001). "Metal sensitivity in patients with orthopaedic implants". The Journal of Bone and Joint Surgery. American Volume. 83 (3): 428–436. doi:10.2106/00004623-200103000-00017. PMID 11263649.
  39. ^ Tower SS (May 28, 2010). "Cobalt Toxicity in Two Hip Replacement Patients" (PDF). State of Alaska Epidemiology Bulletin No. 14. Archived from the original (PDF) on September 18, 2020. Retrieved January 13, 2011.
  40. ^ a b "FDA seeks more advice on metal hip implants". Reuters. 29 March 2012. Retrieved 20 May 2012.
  41. ^ "510(k) Clearances". Center for Devices and Radiological Health. FDA. 9 February 2019. Retrieved 15 April 2020.
  42. ^ Triclot P (February 2011). "Metal-on-metal: history, state of the art (2010)". International Orthopaedics. 35 (2): 201–206. doi:10.1007/s00264-010-1180-8. PMC 3032111. PMID 21234564.
  43. ^ "510(k) Clearances". Health Center for Devices and Radiological. FDA. 2019-02-09. Retrieved 2020-04-15.
  44. ^ Coté J (July 22, 2007). "Hip replacement is not viewed as high-risk surgery; Death is rare, but underlying medical condition a factor". San Francisco Chronicle.
  45. ^ Medscape Conference Coverage, American Academy of Orthopaedic Surgeons (AAOS) 2009 Annual Meeting, AAOS 2009: Certain Factors Increase Risk for Death After Total Hip Arthroplasty, Barbara Boughton, March 3, 2009.
  46. ^ Mikhael MM, Hanssen AD, Sierra RJ (February 2009). "Failure of metal-on-metal total hip arthroplasty mimicking hip infection. A report of two cases". The Journal of Bone and Joint Surgery. American Volume. 91 (2): 443–446. doi:10.2106/JBJS.H.00603. PMID 19181991.
  47. ^ Meier B (March 3, 2010). "As Use of Metal-on-Metal Hip Implants Grows, Studies Raise Concerns". The New York Times.
  48. ^ Meier B (March 3, 2010). "Concerns Over 'Metal on Metal' Hip Implants". The New York Times.
  49. ^ "Medical Device Alert: All metal-on-metal (MoM) hip replacements". Medicines and Healthcare products Regulatory Agency. 22 April 2010. MDA/2010/033. Archived from the original on 25 April 2010. Retrieved 2010-05-07.
  50. ^ Table HT 46. Australian Orthopaedic Association National Joint Replacement Registry Annual Report. Adelaide: AOA; 2008
  51. ^ Milosev I, Trebse R, Kovac S, Cör A, Pisot V (June 2006). "Survivorship and retrieval analysis of Sikomet metal-on-metal total hip replacements at a mean of seven years". The Journal of Bone and Joint Surgery. American Volume. 88 (6): 1173–1182. doi:10.2106/JBJS.E.00604. PMID 16757748.
  52. ^ Smith AJ, Dieppe P, Vernon K, Porter M, Blom AW (March 2012). "Failure rates of stemmed metal-on-metal hip replacements: analysis of data from the National Joint Registry of England and Wales". Lancet. 379 (9822): 1199–1204. doi:10.1016/S0140-6736(12)60353-5. PMID 22417410. S2CID 9913872.
  53. ^ Gallagher J (13 March 2012). "Metal-on-metal hip replacements 'high failure rate'". BBC. Retrieved 20 May 2012.
  54. ^ Pijls BG, Meessen JM, Schoones JW, Fiocco M, van der Heide HJ, Sedrakyan A, Nelissen RG (2016). "Increased Mortality in Metal-on-Metal versus Non-Metal-on-Metal Primary Total Hip Arthroplasty at 10 Years and Longer Follow-Up: A Systematic Review and Meta-Analysis". PLOS ONE. 11 (6): e0156051. Bibcode:2016PLoSO..1156051P. doi:10.1371/journal.pone.0156051. PMC 4905643. PMID 27295038.
  55. ^ Roberts M (5 March 2012). "Surgeons call for end to metal hip replacements". BBC. Retrieved 20 May 2012.
  56. ^ "Metal-on-Metal Hip Implants". Food and Drug Administration. February 10, 2011. Retrieved January 4, 2012.
  57. ^ "Orthopaedic and Rehabilitation Devices Panel of the Medical Devices Advisory Committee Meeting Announcement". Food and Drug Administration. 27 March 2012. FDA-2012-N-0293. Retrieved 20 May 2012.
  58. ^ FDA Executive Summary Memorandum – Metal-on-Metal Hip Implant System (PDF) (Report). Food and Drug Administration. 27 June 2012. Retrieved 15 March 2013.
  59. ^ "Concerns about Metal-on-Metal Hip Implants". Food and Drug Administration. 17 January 2013. Retrieved 15 March 2013.
  60. ^ "Study Suggests Women Have Higher Risk of Hip Implant Failure". media.jamanetwork.com.
  61. ^ Rising JP, Reynolds IS, Sedrakyan A (July 2012). "Delays and difficulties in assessing metal-on-metal hip implants". The New England Journal of Medicine. 367 (1): e1. doi:10.1056/NEJMp1206794. PMID 22716934.
  62. ^ "Charnley-type artificial hip prosthesis, Science Museum Group Collection". 2022.
  63. ^ Timperley AJ (20 October 2017). "Robin Ling obituary". The Guardian. Retrieved 22 October 2017.
  64. ^ Pai VS (1997). "A comparison of three lateral approaches in primary total hip replacement". International Orthopaedics. 21 (6): 393–398. doi:10.1007/s002640050193. PMC 3619565. PMID 9498150. Archived from the original on 2002-01-08.
  65. ^ "Anterolateral Approach to Hip Joint: (Watson Jones) – Wheeless' Textbook of Orthopaedics". Retrieved 2007-11-26.
  66. ^ "Anterior Approach to the Hip (Smith Petersen) – Wheeless' Textbook of Orthopaedics". Retrieved 2007-11-26.
  67. ^ Jolles BM, Bogoch ER (July 2006). "Posterior versus lateral surgical approach for total hip arthroplasty in adults with osteoarthritis". The Cochrane Database of Systematic Reviews. 2006 (3): CD003828. doi:10.1002/14651858.cd003828.pub3. PMC 8740306. PMID 16856020.
  68. ^ Maratt JD, Gagnier JJ, Butler PD, Hallstrom BR, Urquhart AG, Roberts KC (September 2016). "No Difference in Dislocation Seen in Anterior Vs Posterior Approach Total Hip Arthroplasty". The Journal of Arthroplasty. 31 (9 Suppl): 127–130. doi:10.1016/j.arth.2016.02.071. PMID 27067754.
  69. ^ Christensen CP, Jacobs CA (September 2015). "Comparison of Patient Function during the First Six Weeks after Direct Anterior or Posterior Total Hip Arthroplasty (THA): A Randomized Study". The Journal of Arthroplasty. 30 (9 Suppl): 94–97. doi:10.1016/j.arth.2014.12.038. PMID 26096071.
  70. ^ Higgins BT, Barlow DR, Heagerty NE, Lin TJ (March 2015). "Anterior vs. posterior approach for total hip arthroplasty, a systematic review and meta-analysis". The Journal of Arthroplasty. 30 (3): 419–434. doi:10.1016/j.arth.2014.10.020. PMID 25453632.
  71. ^ Meermans G, Konan S, Das R, Volpin A, Haddad FS (June 2017). "The direct anterior approach in total hip arthroplasty: a systematic review of the literature". The Bone & Joint Journal. 99-B (6): 732–740. doi:10.1302/0301-620X.99B6.38053. PMID 28566391. S2CID 21287407.
  72. ^ Graves SC, Dropkin BM, Keeney BJ, Lurie JD, Tomek IM (April 2016). "Does Surgical Approach Affect Patient-reported Function After Primary THA?". Clinical Orthopaedics and Related Research. 474 (4): 971–981. doi:10.1007/s11999-015-4639-5. PMC 4773324. PMID 26620966.
  73. ^ Perets I, Walsh JP, Mu BH, Mansor Y, Rosinsky PJ, Maldonado DR, et al. (2021-03-01). "Short-term Clinical Outcomes of Robotic-Arm Assisted Total Hip Arthroplasty: A Pair-Matched Controlled Study". Orthopedics. 44 (2): e236–e242. doi:10.3928/01477447-20201119-10. PMID 33238012. S2CID 227176201.
  74. ^ Parsley BS (August 2018). "Robotics in Orthopedics: A Brave New World". The Journal of Arthroplasty. 33 (8): 2355–2357. doi:10.1016/j.arth.2018.02.032. PMID 29605151. S2CID 4557610.
  75. ^ Jacofsky DJ, Allen M (October 2016). "Robotics in Arthroplasty: A Comprehensive Review". The Journal of Arthroplasty. 31 (10): 2353–2363. doi:10.1016/j.arth.2016.05.026. PMID 27325369.
  76. ^ Nieuwenhuijse MJ, Nelissen RG, Schoones JW, Sedrakyan A (September 2014). "Appraisal of evidence base for introduction of new implants in hip and knee replacement: a systematic review of five widely used device technologies". BMJ. 349 (sep09 1): g5133. doi:10.1136/bmj.g5133. PMC 4159610. PMID 25208953.
  77. ^ Amirouche F, Solitro G, Broviak S, Gonzalez M, Goldstein W, Barmada R (December 2014). "Factors influencing initial cup stability in total hip arthroplasty". Clinical Biomechanics. 29 (10): 1177–1185. doi:10.1016/j.clinbiomech.2014.09.006. PMID 25266242.
  78. ^ Blakeney WG, Epinette JA, Vendittoli PA (September 2019). "Dual mobility total hip arthroplasty: should everyone get one?". EFORT Open Reviews. 4 (9): 541–547. doi:10.1302/2058-5241.4.180045. PMC 6771074. PMID 31598332.
  79. ^ Horriat S, Haddad FS (August 2018). "Dual mobility in hip arthroplasty: What evidence do we need?". Bone & Joint Research. 7 (8): 508–510. doi:10.1302/2046-3758.78.BJR-2018-0217. PMC 6138808. PMID 30258569.
  80. ^ a b c d e f g h Vanrusselt J, Vansevenant M, Vanderschueren G, Vanhoenacker F (December 2015). "Postoperative radiograph of the hip arthroplasty: what the radiologist should know". Insights into Imaging. 6 (6): 591–600. doi:10.1007/s13244-015-0438-5. PMC 4656234. PMID 26487647.
  81. ^ a b Shin WC, Lee SM, Lee KW, Cho HJ, Lee JS, Suh KT (May 2015). "The reliability and accuracy of measuring anteversion of the acetabular component on plain anteroposterior and lateral radiographs after total hip arthroplasty". The Bone & Joint Journal. 97-B (5): 611–616. doi:10.1302/0301-620X.97B5.34735. PMID 25922453.
  82. ^ Cibulka MT, White DM, Woehrle J, Harris-Hayes M, Enseki K, Fagerson TL, et al. (April 2009). "Hip pain and mobility deficits--hip osteoarthritis: clinical practice guidelines linked to the international classification of functioning, disability, and health from the orthopaedic section of the American Physical Therapy Association". The Journal of Orthopaedic and Sports Physical Therapy. 39 (4): A1-25. doi:10.2519/jospt.2009.0301. PMC 3963282. PMID 19352008.
  83. ^ McDonald S, Page MJ, Beringer K, Wasiak J, Sprowson A (May 2014). "Preoperative education for hip or knee replacement". The Cochrane Database of Systematic Reviews. 2014 (5) (published 13 May 2014): CD003526. doi:10.1002/14651858.CD003526.pub3. PMC 7154584. PMID 24820247.
  84. ^ Jones C, Briffa N, Jacob J, Hargrove R (2017). "The Dislocated Hip Hemiarthroplasty: Current Concepts of Etiological factors and Management". The Open Orthopaedics Journal. 11 (Suppl-7, M4): 1200–1212. doi:10.2174/1874325001711011200. PMC 5721319. PMID 29290857.
  85. ^ Ninh CC, Sethi A, Hatahet M, Les C, Morandi M, Vaidya R (August 2009). "Hip dislocation after modular unipolar hemiarthroplasty". The Journal of Arthroplasty. 24 (5): 768–774. doi:10.1016/j.arth.2008.02.019. PMID 18555648.
  86. ^ van der Meulen MC, Allen WA, Giddings VL, Athanasiou KA, Poser RD, Goodman SB, et al. "Effect of hemiarthroplasty on acetabular cartilage". 1996 Project Reports. VA Palo Alto Health Care System's Bone and Joint Rehabilitation Research and Development Center.
  87. ^ Metcalfe D, Judge A, Perry DC, Gabbe B, Zogg CK, Costa ML (May 2019). "Total hip arthroplasty versus hemiarthroplasty for independently mobile older adults with intracapsular hip fractures". BMC Musculoskeletal Disorders. 20 (1): 226. doi:10.1186/s12891-019-2590-4. PMC 6525472. PMID 31101041.
  88. ^ Koutras C, Antoniou SA, Talias MA, Heep H (November 2015). "Impact of Total Hip Resurfacing Arthroplasty on Health-Related Quality of Life Measures: A Systematic Review and Meta-Analysis". The Journal of Arthroplasty. 30 (11): 1938–1952. doi:10.1016/j.arth.2015.05.014. PMID 26067708.
  89. ^ van den Bekerom MP, Lamme B, Sermon A, Mulier M (August 2008). "What is the evidence for viscosupplementation in the treatment of patients with hip osteoarthritis? Systematic review of the literature". Archives of Orthopaedic and Trauma Surgery. 128 (8): 815–823. doi:10.1007/s00402-007-0447-z. PMID 17874246. S2CID 9983894.
  90. ^ Centeno CJ, Kisiday J, Freeman M, Schultz JR (July 2006). "Partial regeneration of the human hip via autologous bone marrow nucleated cell transfer: A case study". Pain Physician. 9 (3): 253–256. PMID 16886034. Archived from the original on 2009-02-12.
  91. ^ Kurtz SM, Ong KL, Lau E, Widmer M, Maravic M, Gómez-Barrena E, et al. (December 2011). "International survey of primary and revision total knee replacement". International Orthopaedics. 35 (12): 1783–1789. doi:10.1007/s00264-011-1235-5. PMC 3224613. PMID 21404023.
  92. ^ Maradit Kremers H, Larson DR, Crowson CS, Kremers WK, Washington RE, Steiner CA, et al. (September 2015). "Prevalence of Total Hip and Knee Replacement in the United States". The Journal of Bone and Joint Surgery. American Volume. 97 (17): 1386–1397. doi:10.2106/JBJS.N.01141. PMC 4551172. PMID 26333733.
  93. ^ "A study of cost variations for knee and hip replacement surgeries in the U.S." (PDF). Blue Cross Blue Shield Association. 21 January 2015. Archived from the original (PDF) on 22 October 2015. Retrieved 4 October 2015.
  94. ^ "History of Artificial Joints" (ppt video online download). slideplayer.com.
  95. ^ Brand RA, Mont MA, Manring MM (June 2011). "Biographical sketch: Themistocles Gluck (1853-1942)". Clinical Orthopaedics and Related Research. 469 (6): 1525–1527. doi:10.1007/s11999-011-1836-8. PMC 3094624. PMID 21403990.
  96. ^ Gomez PF, Morcuende JA (2005). "Early attempts at hip arthroplasty--1700s to 1950s". The Iowa Orthopaedic Journal. 25: 25–29. PMC 1888777. PMID 16089067.
  97. ^ a b c d e f g h Bota NC, Nistor DV, Caterev S, Todor A (March 2021). "Historical overview of hip arthroplasty: From humble beginnings to a high-tech future". Orthopedic Reviews. 13 (1): 8773. doi:10.4081/or.2021.8773. PMC 8054655. PMID 33897987.
  98. ^ a b c d e f Knight SR, Aujla R, Biswas SP (September 2011). "Total Hip Arthroplasty - over 100 years of operative history". Orthopedic Reviews. 3 (2): e16. doi:10.4081/or.2011.e16. PMC 3257425. PMID 22355482.
  99. ^ a b c Reynolds LA (2006). Early Development of Total Hip Replacement. Wellcome Trust Centre for the History of Medicine, University College London, UK. ISBN 978-085484-111-0.
  100. ^ "What You Need to Know About Joint Replacement Surgery". Verywell Health.
  101. ^ "Dr. Matta and Anterior Approach". Steadman Clinic. September 5, 2017. Retrieved March 26, 2023.
  102. ^ a b "Vitallium Hip prosthesis, Science Museum Group Collection". 2022.
  103. ^ Gomez PF, Morcuende JA (2005). "A historical and economic perspective on Sir John Charnley, Chas F. Thackray Limited, and the early arthoplasty industry". The Iowa Orthopaedic Journal. 25: 30–37. PMC 1888784. PMID 16089068.
  104. ^ a b "Thompson type prosthesis for hip replacement, Science Museum Group Collection". 2022.
  105. ^ a b "Thompson type prosthesis for hip replacement, Science Museum Group Collection". 2022.
  106. ^ a b "Austin Moore type prosthesis for hip replacement, Science Museum Group Collection". 2022.
  107. ^ "Vitallium Hip Prosthesis, Science Museum Group Collection". 2022.
  108. ^ "Vitallium Hip prosthesis, Science Museum Group Collection". 2022.
  109. ^ "Vitallium total hip prosthesis, Science Museum Group Collection". 2022.
  110. ^ "Ringed titanium hip prosthesis with screw stem, Science Museum Group Collection". 2022.
  111. ^ "Modular hip prosthesis with textured femoral stem, Science Museum Group Collection". 2022.
  112. ^ "Replacement hip joint, United States, 1998, Science Museum Group Collection". 2022.
  113. ^ "ANTHOLOGY Hip System, Science Museum Group Collection". 2022.
  114. ^ "ECHELON Hip System, Science Museum Group Collection". 2022.
  115. ^ "Instrument set for Austin-Moore hip replacement, Science Museum Group Collection". 2022.
  116. ^ "Instrument set by Downs Ltd. for ring hip prosthesis, Science Museum Group Collection". 2022.
  117. ^ "Prototype version of the Dobbie bone saw, England, 1966, Science Museum Group Collection". 2022.
  118. ^ "Prototype version of the Dobbie bone saw, England, 1967, Science Museum Group Collection". 2022.
  119. ^ Hurley S (2011). ""Prototypes", Science Museum Blog (April 2011)".

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