The efficacy of tourniquet assisted total knee arthroplasty on patient-reported and performance-based physical function: a randomized controlled trial protocol

Osteoarthritis (OA) is the most common joint disease and a significant cause of morbidity in middle-aged and older populations[1‐3]. Knee OA is characterized by joint pain, swelling, reduced range of motion (ROM), decreased physical activity, and impaired quality of life[4]. Following the development of OA, the associated pain and disability generally increase with time[5, 6]. In end-stage knee OA, total knee arthroplasty (TKA) may be the only effective treatment available to reduce pain and restore joint mobility and function.

TKA is an invasive procedure during which damaged cartilage is removed, joint deformities are corrected and the original knee joint is replaced with an artificial joint. The recovery period typically lasts for several months and patients often experience significant pain which may be only partly relieved by analgesia. Several factors such as the post-operative inflammatory response, muscle damage, pre-existing muscle weakness and swelling may contribute to the extensive recovery period. These factors may also negatively affect physical performance in the early post-surgery period.

Tourniquets inflated above systolic blood pressure have been used by surgeons for lower limb surgery for more than a century[7‐10] and are still the preferred method in elective TKA[9, 11‐13]. The rationale for tourniquet use in TKA is primarily the optimization of intra-operative visibility and reduced blood loss[9, 12, 14, 15]. However, such benefits must be weighed against the potential complications which include; increased risk of direct vascular injury[13, 16], nerve palsy[17‐19], deep-vein thrombosis[7, 8, 13, 20] and subsequent pulmonary embolism[7, 21, 22]. Additionally, acute pulmonary edema and cardiac arrest immediately following tourniquet release have been reported[7, 22, 23]. There are also studies in the literature demonstrating that tourniquet use in TKA does not improve fixation[24, 25]. Tourniquet use may also affect a patients’ physical recovery since its use causes microscopic muscle damage, post-surgery swelling, pain, and reduced knee joint ROM[7, 24‐28] and a greater understanding of patient-reported outcomes following TKA using a tourniquet is required. Furthermore, tourniquet use has been reported to cause post-surgery surface electromyography changes in the quadriceps muscles[29], and has been associated with increased levels of myoglobin in plasma[30], which collectively suggests pressure induced muscle damage does occur. Finally, patients undergoing non-tourniquet assisted TKA commenced rehabilitation exercises earlier and this may improve a patient confidence in using the new joint, decrease the incidence of complications associated with immobility and improve their overall satisfaction[7, 29]. The use of tourniquet for TKA is therefore controversial and well-designed randomized controlled trials are needed to provide high-level evidence to address these important issues. New trials should address aspects of recovery in physical function to fully capture the clinical implications of tourniquet use.

In response to the lack of high-level evidence the primary aim of this randomized trial is to assess the efficacy tourniquet assisted TKA on patient-reported physical function. The secondary aim is to compare post-surgery pain, function in sports and recreation, quality of life, and performance-based physical function. The explorative outcome measures include; use of pain medication, single-fiber muscle damage, and changes in mechanical muscle function. We hypothesize that non-tourniquet assisted TKA will result in superior patient-reported and physical performance-based outcome measures within the first 3-months compared with standard, tourniquet assisted, surgery.

This clinical trial will evaluate the efficacy of tourniquet assisted TKA on patient-reported and performance-based physical performance As a prospective randomized controlled trial the results of this study will provide a high level of evidence on the clinical implications of using a tourniquet during TKA. The primary end point, at 3-month, is a sufficiently long timeframe for the relevant clinical improvements between groups to show and yet short enough to assume that patients can recall their baseline condition. As part of the design, a single senior surgeon will perform the surgical procedures in both groups. The experience of the surgeon in both tourniquet-assisted and non-tourniquet TKA and use of random block size randomization will eliminate bias due to learning. Additionally use of a single surgeon will ensure we are comparing the TKA procedure rather than the skill of different surgeons.

The key aim of TKA in patients with OA is to relieve pain and improve function, both of which are patient reported outcome (PROs) measures reflected in the design of this trial and recommended outcome measures by the Osteoarthritis Research Society International (OARSI) and Outcome Measures in Rheumatology and Clinical Trials (OMERACT) group[39]. Ideally, changes in physical function following TKA should be evaluated using a combination of patient-reported outcomes (PROs) and performance-based outcome measures[39, 45] as they are complementary rather than competing[64, 65] and capture different constructs of physical function[66, 67]. In addition, responsiveness of a PROs ability to detect when patients are undergoing relevant clinical changes can be assessed using a global response evaluation (GPE), and a GPE questionnaire is a recommended part of the evaluation of a treatment in clinical trials[38, 39]. To accommodate these recommendations, the patients in the present trial will be asked to rate their current knee condition pre-surgery (baseline), and at each follow-up (KOOS) and also rate changes in their condition since baseline (GPE). These two patient-reported outcome measures (KOOS and GPE) will be supported by assessor-observed performance-based tests of physical function, hence evaluating, what ‘patients can do’ rather than what they ‘perceive they can do’[67].

According to WHOs classification of Functioning, Disability and Health (ICF) physical function can be classified as the ability to “perform daily activities”[68]. Hence, to fully capture physical function in patients following joint replacement, performance-based testing should represent a variety of physical function domains (activity themes) representing the following five daily activities; walking, sit-to-stand, ambulatory transitions, stair negotiation, and endurance[45]. The current trial uses the 2×20 m fast-paced walk test, the 30-s chair-stand test, and the timed up-and-go test evaluate; walking, sit-to-stand, and ambulatory transition activity domains, repetitively. Despite the importance of also evaluating stair negotiation activity, no specific test is planned in the trial for two reasons. First, no recommendations about specific performance-based tests of physical function, with good measurement-property evidence (reliability, validity, responsiveness, and interpretability), is currently available. Second, the feasibility of stair negotiation tests is largely dependent on the environmental setting making them unsuitable for clinical trials at present[45]. Likewise, no test for evaluating endurance activity has been planned for this trial due to the practical feasibilities issues associated with the six-minute walk test, e.g. patients are unable to walk for six minutes and exhausted following surgery. Further, endurance activity evaluation may be compromised in the early post-surgery phase since pain and swelling, rather than endurance, could limit patients’ performance. Consequently the current trial evaluates three primary activity themes using a core set of performance-based tests recommended by OARSI[45], and from this core set of tests efficient comparisons of treatment outcomes across published literature can be made.

Evaluating the domain of pain or physical function in patients following joint replacement surgery is important[39]. However, the decision to nominate physical function as primary outcome was due to two reasons. The KOOS questionnaire evaluates physical function in a variety of daily activities, and has an extensive subscale (KOOS-ADL, 17 items) devoted to evaluate physical function compared to the pain-subscale (KOOS-PS, 10 items). Additionally, WOMAC and KOOS are the most common PROs used to capture patient relevant information, relating to the impact of interventions in clinical research[69]. WOMAC scores can subsequently be calculated based on data collected using the KOOS questionnaire, thus making efficient comparisons across published literature possible.

Essential explorative outcome measures are also included in the present trial to study muscle mechanics and potential microscopic muscle damage. Studying muscle mechanics is clinical relevant in understanding body structure[51, 70] and the recovery of muscle strength and power are likely to be compromised in tourniquet assisted TKA patients. The theoretical disadvantages of tourniquet application on muscle mechanics is supported by one randomized trial[7] and two non-controlled studies in which reduced muscle function and neurological impairment have been reported[29, 71]. However, such findings should be confirmed in high-quality trials using randomized designs.

A number of other factors may also influence the effects of tourniquets[15]. It’s been suggested that the tourniquet position may be of clinical importance[72] but also cuff width, cuff pressure, time of cuff deflation (cementation of the prosthesis, would closure or application of dressing) must be considered factors that may affect outcome, and should be recorded[15]. Other factors include use of thromboprophylaxis, girth/circumference of thigh, and patient blood pressure. Data on these variables will be collected to insure uniform presentation of data in peer-reviewed papers[9, 15].

We have designed a randomized clinical trial with the main purpose of investigating the efficacy of tourniquet assisted TKA on patient-reported physical function, an outcome which will be supported by a range of performance-based secondary outcome measures. This part of the trial will provide results with high-level evidence and may help to determine whether tourniquet should be used in future TKA procedures for those with severe osteoarthritis of the knee. The explorative part of the trial could also provide further understanding of the underlying neurological and muscle mechanical impairments associated with use of tourniquet during TKA surgery. The results will be submitted to a peer-reviewed international journal for publication irrespective of the outcome in accordance with the CONSORT guidelines for reporting of clinical trials.