Development and validation of a short version of the Sarcopenia Quality of Life questionnaire: the SF-SarQoL

The short form described in this article was developed from the Sarcopenia Quality of Life (SarQoL) questionnaire. This auto-administered patient-reported outcome measure was developed with the specific aim of evaluating quality of life in sarcopenic, community-dwelling older people. The SarQoL measures QoL through 55 items categorized into seven domains of health-related dysfunction: physical and mental health, locomotion, body composition, functionality, activities of daily living, leisure activities, and fears [8]. The response options of the SarQoL questionnaire are a mix of Likert scales (3, 4, or 5 levels) and multiple-answer multiple-choice questions. The scoring algorithm calculates an overall QoL score which is scaled from 20 to 100 points (with complete data), and also provides seven domain scores, scaled from 0 (worst QoL possible) to 100 (best QoL possible) points. The scoring algorithm is not publicly available, but tools to calculate the scores are available by contacting info@sarqol.org. The clinimetric properties of the questionnaire have been evaluated in 11 different language-specific versions, and considerable information is available for known-groups validity, construct validity, internal consistency, floor and ceiling effects, test–retest reliability, standard error of measurement, smallest detectable change, and an evaluation of the responsiveness of the SarQoL has also been carried out [9‐20]. Based on these results, the SarQoL is considered to be a valid, reliable and responsive instrument. The SarQoL questionnaire itself and additional information on the various publications are available from www.​sarqol.​org.

The objectives of the item reduction process were to create a significantly shorter version of the SarQoL questionnaire that would represent as much of the conceptual model of the Overall QoL score of the original questionnaire as possible, and thus also be highly correlated with the same score.

The item selection process was carried out in two phases, presented in Fig. 1. The first phase served to collect and collate as much information on the properties of the items and domains in the SarQoL questionnaire. This phase started off with the calculation of item-impact scores to determine which items in the SarQoL questionnaire are the most relevant and impactful for sarcopenic people. For this purpose, we combined data collected in Brazil, the Czech Republic, the UK, Belgium (two separate cohorts), Poland, Spain and Switzerland. All data were collected in non-interventional studies (transversal and cohort) from community-dwelling older people (60 years and older) who were evaluated for sarcopenia according to the EWGSOP criteria [22]. In total, data from 1950 participants were included in this dataset, of which 267 were diagnosed as sarcopenic. By calculating the prevalence of an item occurring (those that experienced an item divided by those that did not) and dividing this by the mean impact, a ranking was established from most relevant and impactful to least [23]. The first phase of the item selection process continued with a 2-round modified Delphi method, so that the patient’s perspective quantified by the item-impact scores could be complemented with the opinion of health care professionals and researchers. We targeted researchers and clinicians involved in sarcopenia research who had previous experience with the SarQoL questionnaire, through use, translation, validation or development, and invited them to participate. The participants were provided with an Excel file wherein they were able to categorize each of the 55 items as either “must absolutely be kept in a short form” or “could be discarded”. Items were organized and presented per domain. In the second round, the participants were once again asked to categorize the items in the SarQoL questionnaire (keep or discard), but were now also provided the item-impact scores as well as the percentage of participants who agreed on whether to keep or discard an item in the first round. Consensus at the end of the second round was defined as 70% agreement. During both rounds, participants were able to add comments on their choices. The information from the Delphi method, the item-impact scores, and the already published information concerning the clinimetric properties of the SarQoL questionnaire was summarized into a report at the end of the first stage.

In the second phase of the item reduction process the report compiled at the end of phase one was presented to an expert group consisting of researchers specialized in sarcopenia and QoL, a clinical practitioner and a questionnaire methodologist (AG, CB, OB, ML, CM, SG). These discussed the available information and decided on the inclusion or exclusion of a number of items. As recommended in the guidelines formulated by Goetz et al., the expert group was asked to consider content validity (i.e. the results from the item-impact study and the Delphi method) as having the most weight in the decision-making process, followed by clinimetric properties and finally any additional analyses (factor analysis, correlations, or subgroup analyses) that were performed. To ensure an important reduction of the length of the questionnaire, an arbitrary goal of at least a 65% reduction was chosen at the start of the selection process, while maintaining the relative weight of the seven domains in the SarQoL questionnaire.

For the validation of the SF-SarQoL, we contacted the 314 participants who had previously participated in the fourth and/or fifth year of follow-up of the SarcoPhAge (Sarcopenia and Physical impairment with advancing Age) study [24]. In short, this study recruited older, community-dwelling volunteers from the Liège province of Belgium, and invited them once a year for a battery of physical and other measurements. Given that sarcopenia was the main focus of the SarcoPhAge study, body composition, muscle strength and physical performance were evaluated at each visit with dual-energy X-ray absorptiometry, a hydraulic hand-dynamometer and the Short Physical Performance Battery. Details on the SarcoPhAge study design and results have been reported previously [24, 25]

We provided the participants, through the postal service, with study packets composed of the short form SarQoL questionnaire, the EQ-5D and EQ-VAS questionnaire which are preference-based measures of health status, and the original SarQoL questionnaire. The study packets were accompanied by an explanatory letter and a pre-stamped envelope with which to return the study documents [26]. The people who consented to participate and sent back the completed questionnaires received a second packet by mail about 10 days after the date on which they completed the first packet. The second study packet consisted of the SF-SarQoL and a query on whether their health had changed in the interval between the two administrations of the SF-SarQoL. Demographic and clinical data were obtained from the existing datasets collected during the fourth or fifth year follow-up visits of the SarcoPhAge study. Sarcopenia was diagnosed with the revised consensus criteria from the EWGSOP2 (handgrip strength below 27 kg for men or 16 kg for women, together with low muscle mass defined as appendicular skeletal muscle mass divided by height-squared (ASM/Ht²) < 7.0 kg/m² for men or < 5.5 kg/m² for women) [3]. The research protocol (no 2012/277) and its amendment (dated 19/12/2019) were approved by the Ethics Committee of the University Teaching Hospital of Liège.

The clinimetric properties of the SF-SarQoL have been examined with the following indicators from classical test theory:

Before constructing and testing an IRT model, it is important to verify that the items meet the assumptions of unidimensionality, local independence and monotonicity [34].

After confirming unidimensionality, local independence and monotonicity, a logistic Graded Response Model (GRM) was fit to the data using the R package “mirt” (version 1.32.1). This model calculates both item thresholds (b) as well as item slopes (a). For the purpose of this analysis, the response options “I do not undertake these types of physical activities” in item 2.1 and 2.2, “not applicable” in item 3.1 and 3.2, “I am unable to walk” in item 4, and “I have never participated in leisure activities” in item 8 were treated as missing responses. The encoding of the responses on item 8 was also re-ordered, going from decreased participation to increased participation. Item fit was examined with the S − X² indicator, where p ≤ 0.001 indicates poor fit, and by examining the category characteristic curves. For all items, 3 thresholds were estimated, except for item 8, where only two thresholds were estimated.

All analyses were executed with SPSS version 27.0.0, R version 4.0.0. and JASP version 0.13.1.

In addition to the statistical manipulations described in the preceding paragraphs, we also verified normality of distribution for quantitative variables with the Shapiro–Wilk test, by comparing mean and median, and by evaluating the histogram and Q–Q plot. Continuous variables following a Gaussian distribution are reported as mean ± standard deviation, while skewed variables are reported as median (25th percentile–75th percentile). Nominal variables are reported as absolute (n) and relative (%) frequencies. All comparisons were considered significant at the 5% level (p ≤ 0.5).

A total of 214 older people participated in the validation study for the SF-SarQoL. The median age of the participants was 76 (73–81) years and 63.1% were women. We found 70 (32.7%) participants with probable sarcopenia (low grip strength in the EWGSOP2 algorithm), of whom 21 (9.8%) had confirmed sarcopenia. With the help of the SARC-F questionnaire, we found 30 (14.0%) participants at high risk of sarcopenia. The complete clinical and QoL characteristics are reported in Table 2.

To ease interpretation of the QoL scores of the short form questionnaire, it was decided to use a scale going from zero to 100, a deviation from the 20–100 scale of the long form questionnaire. Within the scale, lower scores represent persons whose quality of life is significantly impacted by sarcopenia, and higher scores indicate people with better QoL and a smaller impact of sarcopenia. Figure 2 shows the scatter plot of the short and long form Overall QoL score. From this figure, it can be observed that the short form scores Overall QoL scores are roughly parallel but below the dotted equivalence line, which represents perfect correspondence between the 2 scores.

The per-item percentage of missing responses ranged between 0 and 5.6%. Five (2.3%) participants scored zero points on the Overall QoL score of the SF-SarQoL, and 1 (0.5%) person scored 100 points, indicating that there are no floor or ceiling effects in this sample. We found excellent discriminative power when comparing probably sarcopenic versus probably not [32.74 (20.15–43.15) vs. 48.81 (28.57–70.24); p < 0.001; r = − 0.342], sarcopenic versus not sarcopenic [34.52 (18.59–43.45) vs. 42.86 (26.56–63.69); p = 0.043; r = − 0.144] and at high risk of sarcopenia versus low risk [17.86 (6.64–24.05) vs. 46.43 (30.95–65.48); p < 0.001; r = − 0.444]. Internal consistency among the items was excellent with a Cronbach’s alpha of 0.915 (95% CI = 0.896–0.930) and a McDonalds’ omega value of 0.917 (95% CI = 0.897–0.933). Test–retest reliability was calculated among 133 participants. Within this sub-sample, we found excellent test–retest reliability with an ICC of 0.912 (95% CI = 0.847–0.942) for the overall QoL score of the SF-SarQoL. On an item level, we found moderate to almost-perfect agreement between the first and second administration with weighted kappa coefficients, detailed in Table 3.

A Bland–Altman analysis revealed the presence of a systematic bias of 4.11 (95% CI 2.51; 5.72) points, with higher average scores for the retest scores (50.47 ± 24.82) compared to the test scores (46.36 ± 23.30).

The criterion construct validity, measuring the strength of relationship between the SarQoL overall QoL score and its short form equivalent, was excellent with an ICC of 0.835 (95% CI = 0.789–0.871). It should be noted that the scoring algorithm for the short form and the original SarQoL questionnaire are not on the same metric, and are thus not interchangeable. We also found strong correlations between the SF-SarQoL overall score and the EQ-5D index score (r = 0.671; p < 0.001) and the EQ-VAS (r = 0.697; p < 0.001). A confirmatory factor analysis of a one-dimensional model resulted in the following fit indices (χ² = 269.330, df = 77, p < 0.001; CFI = 0.978; TLI = 0.975; RMSEA = 0.108, 90% CI = 0.094–0.123; SRMR = 0.055). As the five items of question 1 share a common stem, we hypothesized that they would be highly correlated, with would lead to a deterioration of fit indices. To overcome this issue, an alternative model was tested, with the five items of question 1 loading on a first latent variable, and the remaining questions on a second latent variable (factor 1: items 1.1 to 1.5; factor 2: items 2.1 to 8) and a correlated residual variance between items 1.5 and 4. This model obtained adequate fit indices: (χ² = 161.847, df = 75, p < 0.001; CFI = 0.990; TLI = 0.988; RMSEA = 0.074, 90% CI = 0.058–0.089; SRMR = 0.042). The 2 latent variables in this model are highly correlated at r = 0.894. Standardized factor loadings for both models are reported in Table 3.

Confirmatory factor analysis did not conclusively indicate that the SF-SarQoL is unidimensional. Therefore, we investigated further with an exploratory factor analysis, which was considered appropriate when the Bartlett’s test returned a p value < 0.001 and the KMO test a value of 0.87. Parallel analysis identified a single factor in the data, as did the Velicer’s MAP test, which achieved a minimum of 0.05 with 1 factor. There were no locally dependent items found, with no residual correlations greater than the cut-off of 0.184 or − 0.216 (average residual correlation = − 0.016). The monotonicity assumption was confirmed when scalability coefficients H_i between 0.517 (“balance problems”) and 0.716 (“reduction physical capacity”) were found, alongside a Mokken scalability coefficient H for the entire short form of 0.635.

After fitting the logistic Graded Response Model to the data, we found no misfitting items, as evidenced by the fact that no p values for the S − X² indicator were smaller than 0.001. The item with the lowest discriminative ability was found to be “leisure activities” (a = 1.518) and the most discriminative item was “reduction of physical capacity” (a = 3.791). The item thresholds were spread out from − 1.889 (“Carrying heavy objects”) to 1.756 (“Tired moderate effort”). Detailed results on the model fit and item parameters are reported in Table 4. The category characteristics curves, a visual representation of the item parameters, are shown in Fig. 3.