Sarcopenia is a progressive skeletal muscle disorder, which is characterized by low muscle mass and strength and associated with increased risk of adverse outcomes, including premature death. 1 Despite improved awareness of the importance of sarcopenia by health care professionals, fundamental findings from research lack translation to clinical practice—a gap that must be bridged given the major personal, social, and economic burdens ensued by its presence. 1 We report on a renal transplant recipient who experienced substantial muscle wasting during 27.5 years of follow‐up. Height‐indexed 24 h creatinine excretion rate (CER index) was used as accurate marker of muscle mass. 2
A 22‐year‐old Black male was diagnosed with terminal renal insufficiency in May 1981. Chronic intermittent haemodialysis was initiated and maintained until successful renal transplantation in March 1982 (Figure 1A and 1B). At that time, body mass index (BMI) was 19.8 kg/m2 (Figure 1B). Serum creatinine had remained steady until de novo membranous glomerulopathy ensued in March 1985 and eventually graft failure in May 1986. Deteriorating renal function manifested as a gradual rise in serum creatinine (Figure 1A) and, interestingly, a concomitant decrease in CER index, indicating muscle wasting from chronic kidney disease (Figure 1B). Six years of haemodialysis followed until a second transplantation in June 1992. Importantly, CER index was considerably lower shortly after the second compared with the first transplantation (Figure 1B), whereas BMI had actually increased to 21.7 kg/m2 (Figure 1B). Eighteen months later, serum creatinine abruptly rose because of interstitial rejection and membranous glomerulopathy (Figure 1A), whereafter haemodialysis was resumed in January 1994. During the years 1995–2003, complaints of generalized arthropathy from haemodialysis‐associated β‐2 microglobulin amyloidosis gradually developed, which caused progressive decreases in mobility and, consequently, muscle mass and manifested as concomitant decreases in serum creatinine and CER index (Figure 1A and 1B). In December 2008, a third transplantation was performed because of progressive amyloid arthropathy. We observed an increase in BMI from 18.9 kg/m2 (first day after transplantation) to 23.1 kg/m2 (19 days later at discharge), and improved well‐being was reported shortly after. Remarkably, CER index had massively dropped to a quarter of that in June 1992, indicating substantial muscle wasting. Despite increases in BMI in absence of oedema (beginning of February 2009: 18.4 kg/m2; end of February 2009: 20.0 kg/m2; March 2009: 20.2 kg/m2; June 2009: 20.9 kg/m2), CER index steadily waned in the remaining months until the patient's death in August 2009 (Figure 1B).
Figure 1.
Serum creatinine, body mass index, and height‐indexed 24 h creatinine excretion rate over the course of the patient's follow‐up. Evolutions in serum creatinine (A), CER index, and BMI (B) are shown over the course of follow‐up. Moments of renal transplantation are represented by the vertical dashed dark green lines, whereas moments of graft failure are represented by the vertical dashed red lines. The non‐linear line represents the estimated CER index, and the shaded area about the line the associated 95% pointwise confidence interval. The line is solid and coloured dark green at follow‐up times where CER index was actually observed, whereas the line is dashed and coloured dark red at periods of haemodialysis (interpolation). Non‐linearity was modelled using natural cubic splines with two knots imposed at 2.1 and 11.7 years of follow‐up. Boundary knots were set to the 5th and 95th percentiles of follow‐up. The orange points through which the dark blue line is drawn represent observed BMIs. To facilitate appraisal of serum concentrations of creatinine, CER indices, and BMIs around the third renal transplantation (i.e. the rightmost vertical dashed dark green line), the range of the x and y axes of the original figure were cropped, and the resulting enlarged images are given in the upper border of the plots. BMI, body mass index; CER index, height‐indexed 24 h creatinine excretion rate.
Body mass index—defined as weight divided by height in metres squared—is considered the ‘gold standard’ measure of weight and hence abundantly used in clinical decision making and research. In 1985, however, Andres and colleagues called this concept into question by demonstrating that the association between height‐adjusted weight and mortality follows a U‐shaped curve. Moreover, the nadir of that curve (i.e. the weight at which mortality rates were lowest) was highly dependent on age. 3 These findings gave rise to a concept referred to as the ‘obesity paradox’, which still receives much attention. 4 We built on this concept with the patient's gradual, yet inexorable, wasting of muscle mass as harbinger of deteriorating clinical condition and, eventually, death—all in absence of declining BMI. This fuels the notion that muscle mass is superior to BMI in mirroring clinical condition. Indeed, the phenomenon of changing body composition with steady (or even gained) weight can be explained by disproportionate losses of lean mass and concurrent deposition of intramuscular adipose tissue. 5 Additionally, the inexorable nature of the observed muscle wasting indicates the difficulty of rebuilding muscle after serious events. We urge that surrogates of muscle mass, like CER index, as potentially superior prognosticators of adverse outcome to BMI, be considered in study design and more frequently used to inform clinical decision making in settings of low muscle mass or muscle wasting.
Funding
None.
Acknowledgement
The authors of this manuscript certify that they comply with the ethical guidelines for authorship and publishing in the Journal of Cachexia, Sarcopenia and Muscle. 6
Groothof D., Post A., Polinder‐Bos H. A., Hazenberg B. P. C., Gans R. O. B., and Bakker S. J. L. (2021) Muscle mass versus body mass index as predictor of adverse outcome, Journal of Cachexia, Sarcopenia and Muscle, 12, 517–518, 10.1002/jcsm.12686
References
- 1. Cruz‐Jentoft AJ, Bahat G, Bauer J, Boirie Y, Bruyère O, Cederholm T, et al. Sarcopenia: revised European consensus on definition and diagnosis. Age Ageing 2019;48:16–31. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 2. Bürger M. Beiträge zum Kreatininstoffwechsel. I. Die Bedeutung des Kreatininkoefizienten für die quantitative Bewertung der Muskulatur als Korpergewichtskomponente. Z Ges Exp Med 1919;9:262–284. [Google Scholar]
- 3. Andres R, Elahi D, Tobin D, Muller DC, Brant L. Impact of age on weight goals. Ann Intern Med 1985;103:1030–1033. [DOI] [PubMed] [Google Scholar]
- 4. Lee DH, Keum NN, Hu FB, Orav EJ, Rimm EB, Willett WC, et al. Predicted lean body mass, fat mass, and all cause and cause specific mortality in men: prospective US cohort study. BMJ 2018;362:k2575. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 5. Song M‐Y, Ruts E, Kim J, Janumala I, Heymsfield S, Gallagher D. Sarcopenia and increased adipose tissue infiltration of muscle in elderly African American women. Am J Clin Nutr 2004;79:874–880. [DOI] [PubMed] [Google Scholar]
- 6. von Haehling S, Morley JE, Coats AJS, Anker SD. Ethical guidelines for publishing in the Journal of Cachexia, Sarcopenia and Muscle: update 2019. J Cachexia Sarcopenia Muscle 2019;10:1143–1145. [DOI] [PMC free article] [PubMed] [Google Scholar]