At present, most orthopaedic surgeons agree in classifying implants as linked (hinged) or unlinked (non-hinged) (Fig. 1). Linked implants are characterised by a physical connection mechanism between the ulnar and humeral components, which allows or prevents subluxation or dislocation, whilst unlinked implants do not have such a connection. In general, linked implants have a greater degree of constriction. However, some unlinked implants present more constriction than linked implants. Most currently existing linked implants are semiconstricted, which means that there is some degree of varus-valgus and rotational laxity. In theory, this degree of semiconstriction reduces tensions in the implant-cement–bone interface, thus decreasing the possibility of loosening of the components. At present, there are some designs that allow intraoperative selection of linked or unlinked implants, such as the Latitude® design.

Figure 1.

(A) Coonrad–Morrey linked elbow prosthesis. (B) Latitude® unlinked elbow prosthesis.

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Some characteristics related to the design of elbow joint implants have been shown to improve their survival. The majority of currently existing implants consist of rods which are inserted into the medullary canals of the humerus and ulna and are then fixed with acrylic cement, although certain components, such as the humeral Kudo-iBP component, seem to provide a good cementless fixation. Several of the humeral components currently used consist of an anterior flap, which seems to improve their anteroposterior and lateral intraosseous stability. The type of coating of the components is clearly related to their survival. In the case of Coonrad–Morrey arthroplasty, the generation of ulnar components with an acrylic cement pre-coating has been associated with an increased incidence of osteolysis and mechanical failure. Absence of a porous coating in other designs also appear to be associated with a higher incidence of mechanical failure.

The results and survival of each specific type of linked or unlinked component cannot be extrapolated to other types of implant in the same family. However, there are a series of general advantages and disadvantages which are inherent to linked and unlinked components.

Linked components ensure elbow stability, even in case of severe ligament failure or bone loss. These implants do not only eliminate the main complication of unlinked implants, instability, but also enable a wider release of soft tissues, in order to correct angular deformities and increase mobility. Their main disadvantage is the high transmission of tensions to the implant interface, which can lead to loosening. Semiconstricted components appear to be associated with a relatively low rate of loosening, but also present some risk of accelerated polyethylene wear, especially in the presence of angular deformities and soft tissue imbalance.

Some linked components enable prosthetic replacement in situations of severe bone loss, whereas most unlinked components require integrity of the humeral columns and the greater sigmoid cavity. Linked implants are also very useful in patients with high flexion contracture, which requires the non-anatomical implantation of the components in order to restore a functional range of motion.

The main advantages of unlinked implants are reduced invasion of the medullary canal through the use of shorter rods, the possibility of using the humeral component as hemiarthroplasty in some cases and increased theoretical survival of the components if an anatomical implantation with a perfect range of motion is achieved.

At present, the reports published seem to favour the use of linked implants. Little et al. published a systematic review of the literature published until 2003.2 Although the incidence of review surgery was similar (11% vs 13%), linked components presented a lower incidence of radiographic loosening and greater mobility in extension. In the only study comparing the survival of linked and unlinked implants, Levy et al. reported higher rates of review surgery with unlinked components.3

Inflammatory arthropathies, such as rheumatoid arthritis, constitute a classical indication for elbow prosthesis (Fig. 2). Patients with advanced degrees of joint destruction (Mayo Clinic grades III to V)4,5 experience a clear improvement in pain, mobility and function. Furthermore, due to the polyarticular nature of these diseases, the level of activity of patients is limited, thus reducing the incidence of mechanical failure of the implant.

Figure 2.

Preoperative radiograph of a patient with advanced rheumatoid arthritis and high degree of joint destruction. (A) Anteroposterior view. (B) Lateral view.

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The high success rate of elbow arthroplasty in inflammatory arthropathies has led to the expansion of its indications to other conditions. Posttraumatic elbow osteoarthritis is one of the most difficult processes to treat. Although elbow arthroplasty provides good results in terms of pain and mobility in these cases, patients are usually younger and more active, thus leading to an increased risk of wear and loosening.

At present, elbow arthroplasty is considered an ideal alternative in certain patients with fractures and nonunions of the distal humerus.6–8 In elderly patients with prior joint disease or severe osteopenia it is difficult to obtain a stable osteosynthesis. Other indications for elbow arthroplasty include severe intrinsic rigidity, large bone defects after severe trauma or tumour resection, haemophilic arthropathy and, only rarely, primary elbow osteoarthritis, which usually responds well to joint debridement.

Despite the relatively long history of elbow arthroplasty, there is still some disagreement concerning the surgical approach and management routes of the ulnar nerve. At our centre, the vast majority of elbow arthroplasties have been typically associated with ulnar nerve transposition. However, a relatively high percentage of patients develop ulnar neuropathy. There is some interest regarding the possibility of carrying out an in situ decompression of the ulnar nerve without transposition, in order to prevent nerve devascularisation. However, so far there is no firm scientific foundation supporting either option.

With respect to the management of the extensor apparatus, all approaches which carry out triceps detachment lead to weakness in extension in some percentage of patients. In some cases it is possible to conduct the intervention by working on both sides of the triceps.9,10 This approach is especially indicated in patients with distal humerus bone defects (severe trauma, tumours, review surgery), as well as fractures and nonunions of the distal humerus, a situation in which the distal fragments are resected.

In many cases it is extremely difficult to perform the procedure with an intact extensor mechanism. Currently, the most popular procedures are the approach described by Bryan and Morrey,11 division of the triceps at the medial line, and the modifications in the approach of Van Gorden, with detachment of the extensor apparatus at the myotendinous junction.12 At present, there is not enough evidence in the published literature which clearly favours any of these approaches, compared with the others (Fig. 3).

Figure 3.

(A) The Bryan and Morrey approach consists in disinsertion of the triceps, anconeus and extensor apparatus from medial to lateral. (B) This approach provides a perfect access for arthroplasty.

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Repair techniques and postoperative protection of the triceps represent 2 fundamental aspects related to the approach procedure. The repair must be performed meticulously and, more specifically, transosseous sutures must be used in the Bryan–Morrey and tricipital division approaches. Avoiding extension against resistance during the first 6 postoperative weeks is generally recommended.

Naturally, bone preparation for implantation of an elbow arthroplasty is specific for each type of implant. As a general rule, implants require careful preparation of the medullary canals, as well as creating bone cuts to accommodate the morphology of the articular portion of the implant. Preparation of the ulnar canal can be particularly difficult in patients with small skeletons.

Most currently used implants are fixed with acrylic cement. Given the high incidence of infection in elbow arthroplasties compared with other joints, we recommend the routine use of antibiotic cement. It is important to use cement restrictors, not only to improve cementing quality, but also to avoid the need to extract large quantities of cement in case of infection, as well as to leave space for a shoulder prosthesis in case this is required in the future. It is also important to achieve good apposition of the anterior flap of the humeral component with respect to the anterior humeral cortex or interposed graft, depending on the design employed and local bone morphology.

In cases of marked preoperative loss of mobility, soft tissue release may be insufficient to reestablish a suitable arc. In such cases, it may be necessary to insert the components in a non-anatomical position (a deeper insertion of components in both the humeral side and the ulnar side), thus eliminating any source of bone conflict.

The objectives of the first phase of postoperative treatment are to reduce oedema and facilitate full healing of the surgical wound. The operated elbow should be kept extended and elevated for a couple of days before starting active assisted mobility. When using linked prostheses, it may be necessary to keep the elbow immobilised for longer in order to protect the ligamentous structures. In elbows in which the extensor apparatus has been disinserted, it is important that the patient avoids active extension against resistance during the first 6 weeks.

Polyethylene wear seems to be the main factor limiting the longevity of current elbow prosthesis designs. In general, heavy lifting with the operated limb should be avoided. Empirically, it is best not to lift more than 5kg, especially in a repeated manner.

There are several studies on the results of elbow arthroplasty in cases of chronic inflammatory arthritis, using both linked and unlinked implants. Gill and Morrey published the results obtained in 78 rheumatoid elbows operated consecutively using Coonrad–Morrey arthroplasty.4 At the end of the follow-up period, 97% of patients reported no pain or mild pain and the mean range of motion was 28° extension and 131° flexion. The main complications reported were deep infection (2 elbows), loosening (2 elbows), triceps avulsion (3 cases), periprosthetic fractures (2 cases) and fracture of the ulnar component (1 case). Review-free survival was 92.4% at 10 years. Gschwend et al. published the results obtained with GSB III prostheses in 65 elbows, of which 31 were rheumatoid,13 with a mean follow-up period of 10 years. They obtained good clinical results in most cases and the main complications were infection (6%), loosening (4.6%) and failure of the link mechanism (13.6%).

Other authors have published the results obtained with linked prostheses. van der Lugt et al. published the results of 204 rheumatoid elbows using a Souter-Stratchlyde design14 and with a mean follow-up period of 6.4 years. In this series, only 6 patients reported pain at rest and the main complications were infection (10 elbows), humeral loosening (22 elbows) and dislocation (4 elbows). Kudo et al. published the results in 43 elbows followed for 3 years, with good or excellent results in 86% of cases.15

The overall experience at the Mayo Clinic with the Coonrad–Morrey prosthesis has recently been reviewed. The series includes a total of 461 arthroplasties with a mean follow-up period of 8 years (range: 2–25 years). Approximately 90% (418) of the implants did not require review, 2.2% were reviewed and resected due to infection, 5.4% due to loosening and 1.7% due to polyethylene wear. Three patients required osteosynthesis of periprosthetic fractures and 17 required debridement due to deep infection, with the overall rate of infection being 5.8% (Fig. 4).

Figure 4.

Anteroposterior (A) and lateral (B) radiographs, 20 years after implantation of a prosthetic elbow due to rheumatoid arthritis.

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Necessary improvements in the field of elbow arthroplasty in the near future are likely to offer more options for implants, a more accurate placement of the components, better stability of unlinked components, improved friction surfaces to reduce wear, better preservation of extensor apparatus integrity and reduction of the incidence of infection.1

There is considerable interest in the development and use of partial prostheses. Most current experience has focused on distal humerus partial arthroplasties and capitellum arthroplasties. Perhaps, coronoid prostheses and proximal ulnar prostheses will also be developed in the future. There have been some laboratory tests with navigation for component implantation. However, for the moment, the limiting factor appears to be the variability of the joint segment with respect to the medullary channels.31

The authors declare that this investigation did not require experiments on humans or animals.

The authors declare that this study does not reflect any patient data.

The authors declare that this study does not reflect any patient data.