OBJECTIVE

To explore the potential relevance of muscle mass as a variable contributor to BMI in limitations on BMI-based predictions of diabetes remission (DR) after Roux-en-Y gastric bypass (RYGB).

RESEARCH DESIGN AND METHODS

We evaluated the relationship between muscle mass and BMI in 501 patients with type 2 diabetes mellitus and overweight or obesity, of whom 186 patients who underwent RYGB were studied for determination of the role of baseline muscle mass and BMI in predicting DR. Muscle mass was assessed by estimated fat-free mass index (eFFMI) and psoas cross-sectional area (CSA).

RESULTS

A nonlinear relationship existed between psoas CSA and BMI, whereas psoas CSA showed a highly positive correlation with eFFMI. Baseline psoas CSA and eFFMI were better than BMI for predicting 1- and 5-year DR.

CONCLUSIONS

The nonlinear relationship between muscle mass and BMI may partially contribute to BMI limitations in predicting DR after RYGB.

BMI is widely used as a criterion to select candidates for metabolic surgery. However, no direct evidence supports the predictive ability of BMI for diabetes remission (DR) after surgery (1,2). BMI reflects both body fat mass and fat-free mass (FFM). Muscle mass, a major component of FFM (3), is crucial for glucose metabolism. Therefore, further investigation of the relationship between muscle mass and BMI might be important for understanding BMI limitations.

Cross-sectional imaging at the third lumbar (L3) vertebra level is an effective method for estimating whole-body composition (4,5), and the psoas cross-sectional area (CSA) has been suggested as a good estimate of whole-body muscle mass and has served as a prognostic biomarker (5,6). Alternatively, the estimated FFM index (eFFMI), derived from predictive equations, has also been developed (7). In this study, we explored the association of muscle mass assessed by psoas CSA and eFFMI with the limitations of BMI in predicting DR after Roux-en-Y gastric bypass (RYGB).

Study Participants

This study was approved by the local ethics committee. We conducted a cross-sectional study of 501 patients with type 2 diabetes mellitus (T2DM) and overweight or obesity, of whom 186 patients who underwent RYGB and had complete 1-year follow-up data were included in the longitudinal study. The primary outcome was complete DR during the 5-year follow-up period after RYGB. The population details and definitions for DR, T2DM, and obesity are presented in Supplementary Material.

Assessment of Body Composition

Details on the magnetic resonance imaging (MRI) scan and measurement of psoas CSA, subcutaneous fat area, and visceral fat area with sliceOmatic 5.0 software (TomoVision, Magog, Canada) can be found in Supplementary Material. The equation proposed by Deurenberg et al. (7) was used to calculate estimated body fat percentage (eBF[%)]): eBF[%] = (1.20 × BMI) + (0.23 × age) − (10.8 × sex) − 5.4, with 1 for male and 0 for female. The eFFMI was calculated as follows: BMI × (1 − (eBF[%]/100)). The estimated fat mass index (eFMI) was calculated as BMI × (eBF[%]/100).

Statistical Analysis

Break point analysis was conducted with the segmented, ggplot2, Hmisc, and rms packages in RStudio v.1.3.959 (https://www.r-project.org/) for evaluation of the best-fit relationships of MRI-measured body composition with BMI and eFFMI or eFMI. Receiver operating characteristic (ROC) analysis was performed with MedCalc v.18.9.1 software. Kaplan-Meier curves were conducted with the survival R package. Additional statistical approaches can be found in Supplementary Material.

Clinical characteristics of the participants in the cross-sectional study are presented in Supplementary Table 1. As shown in Fig. 1A and B and Supplementary Fig. 2. There was a strong linear correlation between BMI and total fat area and subcutaneous fat area (r > 0.80). However, the psoas CSA showed a nonlinear relationship with BMI (P = 0.006 for males and 0.005 for females), and visceral fat area also showed similar characteristics. When BMI was divided into eFFMI and eFMI, the results were similar, except that there was a significantly positive relationship between the eFFMI and psoas CSA. The comparison between linear and segmented linear regression is presented in Supplementary Tables 2, 3, and 4.

In the longitudinal study, significantly higher psoas CSA and eFFMI were observed in the DR group at baseline and even 1 year after RYGB compared with the non-DR group (Supplementary Table 5). Logistic regression analyses revealed the psoas CSA (not sex specific) and eFFMI (for females) as new predictors of 1-year DR (Supplementary Table 6). ROC and Kaplan-Meier analyses were performed for baseline psoas CSA, eFFMI, and BMI in predicting 1- and 5-year DR (Fig. 1C–H). Comparisons of the area under the curve revealed significant differences between BMI and both psoas CSA (P = 0.0039) and eFFMI (P = 0.045) in females, and these differences approached statistical significance in males. Moreover, patients in the highest tertile of baseline psoas CSA and eFFMI showed the longest estimated mean remission time and greatest remission rates during the 5-year follow-up (P = 0.001 and P = 0.020, respectively), while this was not the case for BMI (P = 0.150).

To our knowledge, this is the first study to report the nonlinear relationship between psoas CSA and BMI. Furthermore, baseline psoas CSA and eFFMI were better than BMI for predicting 1- and 5-year DR after RYGB. Our results demonstrate the limitations of BMI in assessing muscle mass and suggest eFFMI as an alternative muscle mass indicator for use in pre- and postoperative assessments.

Previous studies have reported the possible positive correlation between BMI and muscle mass (8). Our findings represent new evidence that, regardless of sex, when BMI exceeds a certain threshold, the muscle curves plateau and show almost no subsequent increment. According to Davis law (the corollary to Wolff law for bone) (9), the mechanical load and stimuli caused by weight gain may partially explain the increased muscle mass in the growth stage. However, due to the limited physiological capacity of tissue depot (10), the muscle and visceral fat showed a threshold effect. In contrast, subcutaneous fat did not show a break point due to the probable larger capacity limit. Meanwhile, the muscle lipotoxicity, inflammation, and atrophy induced by secretion of free fatty acids, chemokines, and cytokines from excessive visceral fat also inhibit the increase in muscle mass to a certain degree (11,12).

Muscle mass constitutes 40–50% of body weight and is considered the most important determinant of whole-body insulin sensitivity in normal-weight individuals (13). Individuals with high BMI almost invariably have more muscle mass; however, this does not imply an improvement in insulin sensitivity due to excessive body fat mass. Of note, a previous study revealed that the percentage change in fat mass was significantly larger than that in muscle mass at 1 year after RYGB (14). Therefore, the presence of more muscle mass before surgery means a greater possibility of a high body muscle ratio after surgery, which may contribute to DR and insulin resistance reduction following surgery.

The nonlinear relationship between muscle mass and BMI may explain why BMI is not a good predictor for DR after surgery. In the debate, the attenuated antidiabetes effect of metabolic surgery in low-BMI individuals (15) may be attributed to the significant differences in muscle mass among populations with different BMI ranges. Based on the existing guidelines, we support active surgical treatment for Asian T2DM patients with a BMI >32.5 kg/m2. However, for patients with a lower BMI range, muscle mass measurement may be crucial to determine suitability for surgery. Interventions (such as strength training and adequate protein intake) to attenuate muscle atrophy during the weight loss period may be important methods to maintain excellent long-term glycemic control (3,8).

The limitations of this study include the limited generalizability due to a single ethnic group, the relatively low 5-year follow-up rate (33.9%), and the lack of a causal effect of the association between muscle mass and DR.

In conclusion, the nonlinear relationship between muscle mass and BMI may partially contribute to the limitations of BMI in predicting DR after RYGB. Given the importance of BMI in determining the indications for metabolic surgery, this finding may be valuable for improving upon the current available scores to predict remission. Further studies are necessary to explore the potential implications in other clinical practices.

S.L. and H.Y. contributed equally to this work.

This article contains supplementary material online at https://doi.org/10.2337/figshare.16608080.

Acknowledgments. The authors thank all patients, research staff, and students who participated in this work.

Funding. This work was funded by the National Key Research and Development Project of China (grant 2016YFA0502003), the National Natural Sciences Foundation of China (81670791), the Shanghai Municipal Education Commission-Gaofeng Clinical Medicine Grant Support (20191920) to Junfeng Han, the Three Year Action Plan for Promoting Clinical Skills and Clinical Innovation in Municipal Hospitals (2020-2022) - Major Clinical Research Projects (SHDC2020CR1017B), and the Innovation Foundation of Translational Medicine of Shanghai Jiao Tong University School of Medicine and Shanghai SJTUSM Biobank.

The funders had no role in study design, data collection or analysis, decision to publish, or preparation of the manuscript.

Duality of Interest. No potential conflicts of interest relevant to this article were reported.

Author Contributions. S.L., H.Y., J.H., and W.J. conceived and designed the study. S.L. drafted the manuscript and researched the literature. S.L., Y.T., and D.Y. collected the data. S.L. and H.Y. contributed to the statistical analysis and figure construction. P.Z., Y.X., and Y.B. supervised the study. H.Y., Y.B., J.H., and W.J. interpreted data and revised the manuscript. All authors reviewed and approved the final version of the manuscript. J.H. and W.J. are the guarantors of this work and, as such, had full access to all the data in the study and take responsibility for the integrity of the data and the accuracy of the data analysis.

1.
Mingrone
G
,
Panunzi
S
,
De Gaetano
A
, et al
.
Bariatric surgery versus conventional medical therapy for type 2 diabetes
.
N Engl J Med
2012
;
366
:
1577
1585
2.
Panunzi
S
,
Carlsson
L
,
De Gaetano
A
, et al
.
Determinants of diabetes remission and glycemic control after bariatric surgery
.
Diabetes Care
2016
;
39
:
166
174
3.
Davidson
LE
,
Yu
W
,
Goodpaster
BH
, et al
.
Fat-free mass and skeletal muscle mass five years after bariatric surgery
.
Obesity (Silver Spring)
2018
;
26
:
1130
1136
4.
Schweitzer
L
,
Geisler
C
,
Pourhassan
M
, et al
.
What is the best reference site for a single MRI slice to assess whole-body skeletal muscle and adipose tissue volumes in healthy adults?
Am J Clin Nutr
2015
;
102
:
58
65
5.
Cruz-Jentoft
AJ
,
Bahat
G
,
Bauer
J
, et al.;
Writing Group for the European Working Group on Sarcopenia in Older People 2 (EWGSOP2), and the Extended Group for EWGSOP2
.
Sarcopenia: revised European consensus on definition and diagnosis
.
Age Ageing
2019
;
48
:
16
31
6.
Mamane
S
,
Mullie
L
,
Piazza
N
, et al
.
Psoas muscle area and all-cause mortality after transcatheter aortic valve replacement: The Montreal-Munich Study
.
Can J Cardiol
2016
;
32
:
177
182
7.
Deurenberg
P
,
Weststrate
JA
,
Seidell
JC
.
Body mass index as a measure of body fatness: age- and sex-specific prediction formulas
.
Br J Nutr
1991
;
65
:
105
114
8.
Lee
DH
,
Keum
N
,
Hu
FB
, 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
9.
Boutin
RD
,
Yao
L
,
Canter
RJ
,
Lenchik
L
.
Sarcopenia: current concepts and imaging implications
.
AJR Am J Roentgenol
2015
;
205
:
W255-66
10.
Bogin
B
.
Evolutionary perspective on human growth
.
Annu Rev Anthropol
1999
;
28
:
109
153
11.
Kalinkovich
A
,
Livshits
G
.
Sarcopenic obesity or obese sarcopenia: a cross talk between age-associated adipose tissue and skeletal muscle inflammation as a main mechanism of the pathogenesis
.
Ageing Res Rev
2017
;
35
:
200
221
12.
Pellegrinelli
V
,
Rouault
C
,
Rodriguez-Cuenca
S
, et al
.
Human adipocytes induce inflammation and atrophy in muscle cells during obesity
.
Diabetes
2015
;
64
:
3121
3134
13.
Yokoyama
I
,
Inoue
Y
,
Moritan
T
,
Ohtomo
K
,
Nagai
R
.
Simple quantification of skeletal muscle glucose utilization by static 18F-FDG PET
.
J Nucl Med
2003
;
44
:
1592
1598
14.
Alba
DL
,
Wu
L
,
Cawthon
PM
, et al
.
Changes in lean mass, absolute and relative muscle strength, and physical performance after gastric bypass surgery
.
J Clin Endocrinol Metab
2019
;
104
:
711
720
15.
Seki
Y
,
Kasama
K
,
Yasuda
K
,
Yokoyama
R
,
Porciuncula
JP
,
Kurokawa
Y
.
The effects of laparoscopic sleeve gastrectomy with duodenojejunal bypass on Japanese patients with BMI <35 kg/m2 on type 2 diabetes mellitus and the prediction of successful glycemic control
.
Obes Surg
2018
;
28
:
2429
2438
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