• •

  1–3: I disagree with the statement (the lower the score, the greater the level of disagreement).

• •

  4–6: I neither agree nor disagree with the statement; my opinion on the issue is not fully defined (4 or 6 were chosen depending on whether one was probably closer to disagreement or agreement, respectively).

• •

  7–9: I agree with the statement (the higher the score, the greater the level of agreement).

There are many tests available to detect infection, but it is a unanimous opinion among the panelists that C-reactive protein (CRP) and erythrocyte sedimentation rate (ESR) should be the first tests requested, jointly, upon clinical suspicion of infection. Nevertheless, we must bear in mind that some inflammatory or neoplastic processes can also increase these markers.8

Although there are some doubts among the participating specialists on the value of the combined negativity of both tests to rule out infection, the literature contains strong evidence of their higher negative predictive value (negative probability ratio: 0–0.6).9,10

Therefore, the recommendation is to carry out these 2 tests jointly in order to rule out infection with a high negative predictive value.8

A large majority of panelists recommended joint puncture and aspiration for patients in whom both laboratory tests were positive. The fluid should be analyzed and cultured, provided that 2 weeks have elapsed since the last dose of antibiotics. In addition to a culture to identify the germ involved, synovial fluid analysis should also include a cell count. Various works have established different thresholds,11–13 but we can safely assume that a cell count over 3000cells/μL or over 65% neutrophils is highly suspicious of chronic prosthetic infection, although this has no value in acute phases where these figures may be temporarily increased.

In case of discrepancies between the results of this test and the analysis, the panel recommends repeating the punction.8,14

If the clinical suspicion of infection persists and the repeated puncture remains negative, there is a strong consensus among the panel that the test which should be requested is labeled-leukocyte scintigraphy. The majority of the panel believes it to be highly reliable.15–17 Nowadays, scintigraphy with gallium and technetium has been displaced by leukocyte radiolabels,18 which today represent the gold standard imaging test for suspicion of infected prosthesis.

The panelists agreed that magnetic resonance imaging does not play a role in these patients. It is evident that, today, resonance imaging scans present significant distortions due to the presence of metallic material.

Positron emission tomography (PET) is still being developed for the field of diagnosis of infected arthroplasties.19

A high level of consensus was reached regarding the observation that instability pain is primarily manifested during gait and in the standing position. Anterior knee pain after a TKA is a relatively common complaint among patients, but approximately 20% of cases were not satisfied with the final result regarding daily life activities.21

There was also a significant level of agreement regarding the exploration of joint instability in TKA, including the assessment of stability in extension, flexion and rotational stability. Physical examination of patients with an unstable TKA is helpful to identify the type of instability and its etiology. There are 3 main types of instability: instability in extension, instability in flexion and overall instability in addition to genu recurvatum.20,22

Preoperatively identifying patients at risk of suffering instability after undergoing a TKA (neuromuscular disease, hip or feet deformities, morbid obesity, etc.) would help to avoid creating this problem. The assessment should be carried out in a formal and exhaustive manner, in all planes, examining stability in extension, in 90° flexion, and in 30–45° intermediate and rotational arches.20,22

Regarding femoropatellar instability, there was a high level of consensus agreement that this pathological situation is defined by the observation of patellar dislocation/subluxation episodes. Anterior prosthetic knee pain should not be identified with patellar instability problems in flexion-extension, because it is usually due to other causes, such as internal rotation of the tibial component.23 The patellar “clunk” sign is related to overgrowth and fibrosis of suprapatellar soft tissues, which can become trapped in the anterior femoral shield during flexion-extension, especially with the posterior stabilized Insall-Burstein II prosthetic model type (Zimmer Inc., Warsaw, IN, USA), but it is not indicative of patellar instability.

The responses only offered a high level of consensus regarding the significance of varus–valgus gaping in the immediate postoperative period when there was an imbalance in flexion-extension spaces. Agreement was scarce regarding the influence on this laxity of polyethylene thickness and lesions of the collateral ligaments.

It is true that increased gaping (varus/valgus) in extension clearly indicates iatrogenic injury of the collateral ligaments during surgery. This may require repair, reconstruction or increased constriction of the system. Nevertheless, it has been shown that conservative treatment is able to achieve the same mechanical stability, compared to cases where the ligament was intact.24

There was greater consensus on the cause of increased varus–valgus mobility, due to polyethylene wear or collapse of the tibial component, not being synonymous with ligamentous failure, and not requiring a more constrained implant. Regarding the causes of this instability, these may include aseptic loosening, bone loss due to collapse, fracture and polyethylene wear.22

This question generated a broad consensus regarding the request for a radiographic study with functional forced varus/valgus tests. On the other hand, there was no consensus about requesting a radiographic study with load and maximum flexion, despite the fact that it can be useful to assess polyethylene usury and anterior subluxation in case of posterior cruciate ligament failure for CR-type prostheses. Radiographs with load may be useful depending on the type of instability, and oblique radiographs can help to assess osteolysis present in femoral condyles.23

There was a significant consensus about requesting a CT scan upon suspicion of patellar instability. However, this consensus did not apply to requesting the test in case of suspected rotatory instability. CT scans can be very useful in the detection of internal malrotation of the femoral component, taking the epicondylar axis as a reference. They can also be useful to evaluate periprosthetic osteolysis, especially when a 3D CT scan is obtained.23

Acute prosthetic infection is defined by local inflammatory signs and/or surgical wound drainage, with or without fever, with less than 4 weeks duration. Less frequently, it is due to hematogenous metastasis from a distant focus. In such cases it is known as late acute infection. Its symptoms are similar to septic arthritis in a native joint and it is important to ensure that the prosthesis worked properly before the onset of symptoms. Both types of acute infection, postoperative and acute hematogenous, should be treated with the same surgical procedure.25,26 This should consist in debridement and replacement of modular components which are not fixed to the bone, such as polyethylene inserts, with antibiotic treatment being initially contraindicated before surgery.

The Gram test is not useful to rule out infection, especially when used as an intraoperative screening method. Several authors27,28 have reviewed the usefulness of this test for the diagnosis of infection and all have agreed that it should not be used as a routine method for the screening of infection, as it has a sensitivity of 19%, despite having a specificity of 98% and a positive predictive value of 63%. The latest guideline on prosthetic infection8 issued by the American Association of Orthopedic Surgeons (AAOS) contained a strong recommendation against the use of this test in the diagnosis of prosthetic joint infection (Recommendation 11).

Regarding the intraoperative count of polymorphonuclear cells (PMN) for the confirmation of prosthetic infection, the cutoff value considered was 10 PMN/field in 5 different fields. A literature review10,29,30 showed that this test has a high positive predictive value, that is, the probability of infection is high when there are 10 or more PMN/field in 5 different fields. However, the fact that the count is less than 10 PMN, and specifically less than 5, does not rule out the presence of infection. The reduction of the threshold to 5 PMN count/field maintains a high sensitivity, but discretely decreases specificity, so it is advisable to maintain the criterion at 10 PMN/field in 5 different high-power fields.

Obtaining multiple cultures during the implantation of the revision prosthesis increases the probability of a diagnosis of infection and significantly reduces the rate of false negatives.31 The AAOS guideline recommendations on prosthetic infection8 consider that 5 intraoperative samples should be taken. Regarding transportation and culture, liquid material inoculated in blood culture vials obtains the best performance, followed by solid material. Certain studies recommend prolonging the conventional culture time in order to isolate slow-growing microorganisms, including Staphylococcus epidermidis, Propinobacterium acnes, etc., as these are, specifically, the microorganisms most frequently related to chronic prosthetic infection.32

Treatment of chronic prosthetic infection involves replacing the implant. The 2 main reimplantation techniques are replacement in 1 and in 2 surgical stages.

After studying 29 articles and a total of 1641 patients, the review conducted by Langlais33 found that the highest rate of cures was obtained with replacement in 2 stages using antibiotic cement for prosthetic fixation. This percentage was 93% versus 86% obtained with replacement in 1 stage also using antibiotic cement.

More recent works, based on the Norwegian registry,34 also found survival rates of 98% at 2 years with replacement in 2 stages, compared to 89% with replacement in 1 stage. Therefore, replacement in 2 stages is currently considered the gold standard for the treatment of chronic prosthetic infection.

The objective of bone resection is to create an identical space in flexion and extension.36 This should be rectangular rather than trapezoidal, according to the works by Laskin,37 who showed that they offered more mobility, less medial pain and less need for lateral retinacular release. The tension in both ligamentous complexes will determine the stability of the space in flexion and extension. Tibial shape equally affects the flexion and extension spaces, and therefore, the thickness of the polyethylene insert will be crucial to confer tension to the soft tissues and medial and lateral ligamentous complexes.35,38

We must bear in mind that an excessive increase in the height of the polyethylene can cause low patella and, conversely, a decrease in the thickness of the insert can generate instability, both in flexion and extension.39

Femoral rotation is essential in order to obtain a rectangular space in flexion. Failure to achieve adequate external rotation leads to alterations in the patellar path, instability and anterior knee pain.40,41 There are 2 methods to obtain an adequate rotation of the femoral component: the first is to start by cutting the tibia and then making the posterior femoral cut parallel to this.42 The second method is based on using the epicondyles, Whiteside's line and posterior condyles as anatomical references. The Perth protocol is routinely used to study the rotation of components in knee arthroplasty. The rotation of the femoral component is measured relative to the epicondylar line and that of the tibial component relative to the posterior tibial condyles and anterior tuberosity.43

Once the diagnosis of knee stiffness has been established, the etiological factor must be identified. The medical history will help to detect the onset of healing problems, presence of superficial infection in the immediate postoperative period, trauma, and the pattern of occurrence of rigidity.44 Symptoms occurring in the immediate postoperative period will indicate that the problem may be surgical error or inadequate rehabilitation, whereas late-onset stiffness after a period of satisfactory mobility should point to cementing problems or a latent infection process.

The treatment for cases of early rigidity includes aggressive rehabilitation with adequate and sufficient analgesia with the aid of dynamic splints and, if necessary, before the first 8 weeks, manipulation under anesthesia provided there are no prosthetic malpositioning errors.45,46 Open arthrolysis involves radical debridement with release of the posterior cruciate ligament, balancing of soft tissues, section of the external wing and, if necessary, a relaxation of the extensor apparatus, either through quadricepsplasty or osteotomy of the anterior tibial tuberosity.44–47

The duration of prosthetic implants is variable and subject to multiple circumstances. This is one of the main challenges faced by new designs and materials. Isolated wear of the polyethylene insert in prostheses with securely anchored components can be resolved by replacing the modular polyethylene component. If this is accompanied by osteolysis, it can be filled with an allograft, with good bone incorporation being reported.48 Griffin et al.49 obtained 84% good results in the replacement of modular polyethylene inserts in cases of implant wear and osteolysis with good fixation.

In any case, each joint must be evaluated individually, since some authors warn of a significant failure rate of these arthroplasties and a high number of revisions at 3 years of insert replacement.50

Knees with significant varus or valgus deformities, history of trauma or revision surgeries associated with significant bone loss present ligamentous deficiencies which require more constrained prosthesis models.

Intact and competent collateral ligaments are a prerequisite for the indication of primary knee prosthesis.51 Otherwise, the indication of condylar models carries a high failure rate in the short term.52 Furthermore, the reintegration or retensing of the lateral ligaments has been attempted by different methods, with very poor results which do not encourage further attempts with such techniques.53

Posterior stabilized or constrained rotational prostheses are indicated in different scenarios involving posterior cruciate ligament deficiencies or complex instabilities.53 However, posterior stabilized models do not offer sufficient stability in cases of large deformities, muscle atrophy, severe lesions of the extensor apparatus, need for large exposures to treat stiffness and other scenarios derived from revision surgery. In these cases it is necessary to use rotatory, constrained modular models.39