Reliability of trunk strength measurements with an isokinetic dynamometer in non-specific low back pain patients: A systematic review

1.Introduction

Low back pain (LBP) is the leading cause of decreased productivity worldwide and is one of the leading causes of years lived with disability [1]. In addition; it has been associated with other musculoskeletal injuries, such a fragility fractures [2, 3] and poor quality of life [4]. In 2017, LBP affected 577 million people worldwide [5]. LBP is defined as pain, muscle tension, or stiffness between the lower costal edge and the lower limit of the gluteal fold, with or without irradiation [4]. In addition, it can be characterized in terms of temporality as acute pain, less than six weeks, subacute, and chronic, when the pain extends beyond 12 weeks [6, 7]. It has been estimated that LBP will affect 90% of the population at least once in their lives [8, 9]. Of these acute episodes, most will recover within two weeks. However, about 70% will have recurrences, of which 40% will need to use health services [10], and it is expected that at least 5% of these patients with low back pain will develop chronic low back pain (cLBP) [11].

LBP is understood as multifactorial and involves several risk factors [12]. Thus, LBP is classified as specific when the anatomical structure can be identified, as in the presence of fractures, metastases, infections, etc. [13]. However, in 90% of the cases, it is impossible to find an anatomical cause, so it is called non-specific low back pain (NSLBP) [13]. However, several risk factors can be attributed to the development of NSLBP, such as the altered neuromuscular response of the trunk [14, 15], deconditioning of the lumbar musculature [16, 17], the reduced muscle mass [18], imbalance, and reduced trunk flexors and extensors muscle strength [19, 20].

Concerning trunk strength, there are records of its assessment since the 1940s [21]. Multiple evaluation systems have been developed to assess trunk strength [22, 23, 24], with isokinetic evaluation being the gold standard [25]. The measurement of trunk strength with an isokinetic dynamometer can be performed isometrically, at different angular positions, and isokinetically, i.e., at different angular velocities [26]. This type of assessment has proven valid for measuring trunk strength [27]. However, the assessments need to be reliable given the importance of trunk strength in health and performance. Reliability is defined as the consistency of measurements or the absence of measurement errors [28]. Reliability can be relative (intraclass correlation coefficient (ICC)) or absolute (standard error of measurement (SEM) or the coefficient of variation (CV)). Relative reliability indicates how similar the rank orders of the participants in the test are to the retest [29], whereas absolute reliability is related to the consistency of individual scores [30, 31]. For this, reliable measurements are relevant in sports medicine and research [31, 32] to objectively reflect the increase or decrease in strength rather than the product of procedural or equipment error.

Recently, Estrázulas et al. [33] reviewed the protocols for isokinetic and isometric measurements using a dynamometer in healthy subjects, recommending a protocol in seated and standing positions to increase the reliability of these measurements. Unfortunately, the results are contradictory in subjects with LBP since Gruther et al. [34], when comparing the isometric and isokinetic trunk assessment in healthy subjects and those with LBP, reported low reliability and therefore did not recommend this type of assessment in LBP patients. However, Verbrugghe et al. [35] reported substantial reliability (ICC = 0.93–0.98; SEM 5.5%–9.3%) in isometric trunk assessment using an isokinetic dynamometer when comparing healthy subjects with LBP patients.

Thus, the reliability of isokinetic trunk strength assessment in healthy subjects is well established; however, given the characteristics of pain and muscle function in LBP patients, to the best of our knowledge, the reliability of the trunk strength assessment using an isokinetic dynamometer in this type of patient has not been proven. Nevertheless, it is important from a clinical and researchers’ point of view since reliable measurements allow a better evaluation and monitoring of objective parameters, such as trunk strength, in these patients. Therefore, the aims of the present systematic review were: (I) to evaluate the quality of evidence of studies evaluating the reliability of trunk strength assessment with an isokinetic dynamometer in NSLBP patients, (II) to examine the reliability of trunk strength assessment using an isokinetic dynamometer in NSLBP patients and (III) to determine the most reliable protocol for trunk strength assessment using an isokinetic dynamometer in NSLBP patients.

2.Method

The Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) guidelines were used [36]. PRISMA was designed to help researchers transparently report why the review was done, what the authors did, and what they found (Supplementary Table S1). The protocol for this review was registered in PROSPERO (CRD42021247943).

2.4Quality of evidence assessment

Two authors (WR-F and AR-P) independently assessed the quality of evidence of the articles included in this review; in case of discrepancies, a third assessor (LC-R) was consulted and resolved by consensus. The Critical Appraisal Tool (CAT) scale was used to assess the quality of the evidence of the studies included in this review [40] and the Quality Appraisal for Reliability Studies (QAREL) checklist [41]. The agreement rate be-tween the reviewers was calculated using kappa statistics.

The CAT is a scale developed to evaluate the methodological quality of studies that verify the validity and reliability of objective clinical tools [40] and contains 13 items categorized as “yes” if the information is described in sufficient detail, “no” when the information is not clear enough, or “not applicable.” In addition, five items are related to validity and reliability, four to validity, and four to reliability only. For this reason, only nine items were considered in this review. Finally, the percentage of the evaluation was calculated ((Items “yes” × 100)/9), assuming a maximum of 100% (nine items), which was the highest methodological quality. Studies that scored over 45% were considered to be of high quality [42].

The quality appraisal tool for studies of diagnostic reliability (QAREL) checklist is an assessment tool for evaluating the quality of diagnostic reliability studies [41]. QAREL contains 11 items encompassing seven key domains (subjects, examiners, examiner blinding, order of assessment, time interval between repeated measurements, test application and interpretation, and statistical analysis). Each item is labeled as “yes”, “no”, or “unclear”. In addition, some items include the option “not applicable.” Quality was calculated ((Items “yes” × 100)/11), and the maximum value was 100%. Based on previous studies [42, 43, 44], a score higher or equal to 60% was considered high quality.

Figure 1.

PRISMA flowchart [63].

3.Results

No systematic reviews with a similar objective to the present study were found. From the initial search, 577 articles were found (Fig. 1), of which 201 articles were eliminated because they were duplicates. After evaluating titles and abstracts, 366 articles did not meet the inclusion criteria, leaving ten articles for full-text reading. Of the ten articles, one was not available because the authors could not be contacted. In addition, three articles were in languages other than English (German and Turkish), one did not evaluate subjects with NSLBP, and another compared inter-rater reliability. One additional article was identified from other sources. Finally, five studies were included in this systematic review.

4.Discussion

The present review aimed to (I) assess the quality of evidence from studies evaluating the reliability of trunk strength assessment using an isokinetic dynamometer in NSLBP patients, (II) examine the reliability of trunk strength assessment using an isokinetic dynamometer in NSLBP patients, and (III) determine the most reliable protocol in trunk strength assessment in NSLBP patients. The main findings of this review indicate that (I) there is good quality evidence from studies regarding the reliability of trunk strength assessment in patients with NSLBP, (II) the reliability of isometric and isokinetic assessment of trunk flexor and extensor strength in patients with NSLBP using an isokinetic dynamometer is excellent and (III) the most reliable protocol for isometric assessment is in functional seated (semi-flex) position, while for isokinetic assessment of flexors and extensors is in standing position with velocities of 60∘/s and 120∘/s and ROM of 60∘.

Concerning the quality of the evidence, three of the five articles retrieved presented good quality evidence when the CAT scale was used; however, when the QAREL checklist was used, none of the articles included were classified as high quality. This difference could be explained by the fact that, although both scales complement each other in the reliability assessment for objective evaluations [40, 41], the QAREL checklist has 36% of its items (four) corresponding to the process of blinding. In contrast, the CAT scale only considers one item according to whether intra- or inter-rater reliability was tested. In the case of this review, all the studies, except for Newton et al. [47], did not report information regarding whether or not a blinding process was performed. Hence, they were classified as “unclear,” and the QAREL checklist assessment score decreased.

Regarding the isometric assessment reliability using an isokinetic dynamometer in NSLBP patients, the evidence shows that this type of measurement has excellent reliability for flexors (ICC = 0.98 (0.95–0.99)) and good to excellent for extensors (ICC = 0.94 (0.86–0.98)) using the ICC 3.1 and the 95% confidence interval (95% CI) [35]. In addition, when the agreement was evaluated, SEM values of less than 10% were obtained. The protocol used by the authors can explain this high reliability [35], which consisted of a comprehensive trunk-specific warm-up to familiarize the subjects with the procedure, followed by an education period on the correct execution of the test. Grabiner et al. [49] reported variations between 17% and 26.5% in the retest of subjects with a history of LBP compared to healthy subjects in the strength evaluation, suggesting that clinicians and researchers should provide a substantial familiarization session when evaluating LBP patients to obtain clinically reliable data. Another reason for excellent reliability could be because when the assessment is conducted at zero velocity and with no change in ROM, there is less possibility of misalignment of the axis of motion or changes in the position and fixation of the subjects; this allows for minor variation between the test and retest. Having reliable protocols for measuring trunk isometric strength is essential for monitoring interventions in LBP patients but also for detecting individuals at risk for LBP since the incidence and severity of LBP is related to isometric and isokinetic weakness of trunk muscles [19].

Considering high methodological quality studies, the reliability of the isokinetic assessment of trunk flexors and extensors was also excellent considering the ICC. However, both Newton et al. [47] and Keller et al. [45] do not specified the 95% CI. If we thought the data reported by Keller et al. [45], who only measured extensor strength as total work (Nm), the most reliable condition was the concentric mode at 60∘/s with an ICC 0.98 and a CV = 10%. However, it is crucial to consider that Keller et al. [45] report the reliability of measurements two and three; since they found statistically significant differences in the strength between the first and second measurements. Thus, they did not evaluate the reliability and considered it as a learning effect. Something similar occurs with Newton et al. [47], who assessed the reliability in a subsample of 20 patients, reporting a learning effect between evaluation one and two, so reliability was evaluated between measurement two and four, reporting excellent reliability for trunk flexors and extensors at velocities of 60, 90 and 120∘/s with ICC between 0.97 and 0.98. Gruther et al. [34], only performed two evaluations separated by two weeks and reports “a few trials for familiarization,” finding a significant increase, between 45 and 160%, compared to baseline in flexors (p= 0.008) and extensors (p= 0.006) concentric isokinetic strength at 90∘/s. Hupli et al. [46], whose does not specify a familiarization process in their protocol, reported a variation in strength between measurements closer to 15% in the mild LBP group and 43–50% in the severe LBP group. This highlights the importance of familiarization when assessing muscle strength to optimize strength production while decreasing the learning effect. When familiarization is not performed, we could underestimate the results. On the other hand, excessive familiarization could produce training effects or fatigue without considering the loss of time in the evaluation [50]. For trunk isokinetic strength, Roth et al. [51], evaluating young, healthy subjects, reported good reliability (ICC = 0.85–0.96) with acceptable CVs between day one to day four measurement. However, reliability was lower when comparing familiarization to day one testing, reaffirming familiarization’s importance in decreasing basal variability, especially at high velocities. Urzica et al. [52] compared isokinetic strength measurements on days one, two, and 21 days of admission to a trunk strengthening treatment in LBP patients. They found significant differences between day one and day two measurements, possibly attributable to the learning effect, reaffirming the need for a familiarization process, especially when the isokinetic evaluation situates the patients in a condition unrelated to their natural movements.

Regarding the measurement position, when healthy subjects are testing, the most reliable protocol is in the standing position, at velocities of 60∘/s and 90∘/s with a ROM of 80∘ in concentric mode [33]. Therefore, according to this review, the most reliable protocol for LBP patients is standing at 60∘/s and 120∘/s and ROM of 60∘. Concerning the variable analyzed, peak torque has been widely used in healthy subjects [27] and LBP patients [39]. In this review, all the articles except for Keller et al. [45] used peak torque to determine the measurement reliability. Regarding the type of contraction, it is essential to consider that none of the articles retrieved in this review evaluated the reliability of the trunk flexors and extensors eccentric strength evaluation. Eccentric contraction occurs when the external strength is greater than the muscular strength, thus plays a vital role in daily life activities and sports, decelerating the body during movement [53]. Specifically, in the trunk, the spinal erectors are responsible for initiating the extension movement from the standing position, while the flexors must eccentrically control this movement [54, 55]. In addition, the extensor group has a clear eccentric antigravitational function [56]. In healthy men, eccentric trunk strength reliability is good to excellent (ICC = 0.78–0.91) [57]. In patients with a giant ventral hernia, the reliability of eccentric flexor strength was excellent (ICC = 0.92–0.96) [58].

To our knowledge, the reliability of eccentric trunk strength in LBP patients has not been probed. Therefore, we can suggest that determining the reliability of these measurements is necessary to understand trunk dynamics in these patients. Finally, from a clinical point of view, it is essential to note that measuring trunk strength using an isokinetic dynamometer does not generate adverse effects or aggravation of pain in LBP patients. It should encourage clinicians and researchers to evaluate and monitor these patients. In addition, after reviewing the evidence, it is clear that the familiarization process is essential in LBP patients. For this reason, it would be interesting to determine the best familiarization program in terms of series and repetitions and to determine whether it should be performed on the same day or on different days. Given the criticisms regarding unnatural movements during isokinetic assessment with classical dynamometers [59], it is necessary to know the reliability of the new generations of isokinetic dynamometers [60, 61], which have a more functional approach and could be a new assessment option in LBP patients.

This review is not exempt from limitations; we only use three databases and include only articles in English, which may have affected the number of articles retrieved. In addition, this review considered articles from two to 28 years old, which did not allow to characterize each study’s sample correctly due to heterogeneity in the presentation of the data in each study. It could be explained by the fact that the standards of scientific publication have changed, and new guidelines have been developed [62]. Notwithstanding this, we can consider as a strength the fact that we reviewed all the available evidence, with no publication deadline until March 2021.

5.Conclusion

There is good quality evidence regarding the trunk strength assessment’s reliability. Reliability is excellent in NSLBP patients; however, a familiarization process should be considered to obtain clinically reliable data. The most reliable protocol is in a seated position for isometric strength and a standing position for isokinetic strength.

Clinical message:

Author contributions

All authors contributed to the development of the research design, concept, data acquisition, data analysis, and interpretation, prepared the manuscript, revised it critically and approved the final version.

Funding

This study has been partially supported by FEDER/Ministry of Science, Innovation and Universities – State Research Agency (Dossier number: RTI2018-099723-B-I00).

Supplementary data

The supplementary files are available to download from http://dx.doi.org/10.3233/BMR-210261.