Exercise Interventions for the Prevention of Sarcopenia After Bariatric Surgery: A Systematic Review

Cláudia Mendes, Manuel Carvalho, Jorge Bravo, Sandra Martins, Armando Raimundo

Journal of Science in Sport and Exercise ›› 2024

Journal of Science in Sport and Exercise ›› 2024 DOI: 10.1007/s42978-024-00311-x
Review Articles

Exercise Interventions for the Prevention of Sarcopenia After Bariatric Surgery: A Systematic Review

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Abstract

Purpose

Bariatric surgery is a treatment for severe obesity and its associated conditions, which already has ample evidence of its benefits. In addition to the reduction in body fat mass, the weight loss caused by bariatric surgery includes a significant reduction in skeletal muscle and bone mineral mass, which could negatively affect functional capacity and increase the risk of sarcopenia. The need for prophylactic programs that prevent sarcopenia in bariatric surgery patients seems to be one of the crucial points for the long-term surgical success of bariatric and metabolic surgery. This study aims to review the published literature regarding the effects of physical exercise on the prevention of sarcopenia induced by bariatric surgery.

Methods

We followed the PRISMA checklist for systematic reviews conducted in PubMed/Medline, EBSCO, Web of Science, and Scopus databases. Randomized controlled, controlled clinical, and other types of experimental studies were considered for inclusion. A total of 356 possibly relevant studies were identified with quality considered reasonable and good. Eight studies were included in the review: six of which were randomized experimental studies, one was a pilot study, and one a quasi-experimental study.

Results

Structured physical exercise allows significant improvements in body composition, positively affecting functional capacity, muscle strength, cardio-metabolic risk factors, and quality of life in patients with obesity undergoing bariatric surgery, especially when combined exercise is implemented in the initial weeks following surgery.

Conclusion

A combined, individualized, and supervised exercise program contributes to preventing and reducing sarcopenia after bariatric surgery.

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Cláudia Mendes, Manuel Carvalho, Jorge Bravo, Sandra Martins, Armando Raimundo. Exercise Interventions for the Prevention of Sarcopenia After Bariatric Surgery: A Systematic Review. Journal of Science in Sport and Exercise, 2024 https://doi.org/10.1007/s42978-024-00311-x

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1.]
MarshallS, MackayH, MatthewsC, MaimoneIR, IsenringE. Does intensive multidisciplinary intervention for adults who elect bariatric surgery improve post-operative weight loss, co-morbidities, and quality of life? A systematic review and meta-analysis. Obes Rev, 2020, 21(7)
CrossRef Google scholar
[2.]
RozierMD, GhaferiAA, RoseA, SimonNJ, BirkmeyerN, ProsserLA. Patient preferences for bariatric surgery: findings from a survey using discrete choice experiment methodology. JAMA Surg, 2018, 154(1): e184375-e184375
CrossRef Google scholar
[3.]
WelbournR, HollymanM, KinsmanR, DixonJ, LiemR, OttossonJ, RamosA, VågeV, Al-SabahS, BrownW, CohenR, WaltonP, HimpensJ. Bariatric surgery worldwide: baseline demographic description and one-year outcomes from the Fourth IFSO Global Registry Report 2018. Obes Surg, 2018, 29(3): 782-795
CrossRef Google scholar
[4.]
EisenbergD, ShikoraSA, AartsE, AminianA, AngrisaniL, CohenRV, De LucaM, FariaSL, GoodpasterKPS, HaddadA, HimpensJM, KowL, KurianM, LoiK, MahawarK, NimeriA, O’KaneM, PapasavasPK, PonceJ, PrattJSA, RogersAM, SteeleKE, SuterM, KothariSN. American Society for Metabolic and Bariatric Surgery (ASMBS) and International Federation for the Surgery of Obesity and Metabolic Disorders (IFSO): indications for metabolic and bariatric surgery. Surg Obes Relat Dis, 2022, 18(12): 1345-1356
CrossRef Google scholar
[5.]
MatosO, RuthesEMP, MalinowskiAKC, LimaAL, VeigaMS, KrauseMP, FarahL, SouzaCJF, LassAD, Castelo-BrancoC. Changes in bone mass and body composition after bariatric surgery. Gynecol Endocrinol, 2020, 36(7): 578-581
CrossRef Google scholar
[6.]
VoicanCS, LebrunA, MaitreS, LainasP, LamouriK, Njike-NakseuM, GaillardM, TranchartH, BalianA, DagherI, PerlemuterG, NaveauS. Predictive score of sarcopenia occurrence one year after bariatric surgery in severely obese patients. PLoS ONE, 2018, 13(5): e0197248
CrossRef Google scholar
[7.]
MartínezMC, MeliEF, CandiaFP, FilippiF, VilallongaR, CorderoE, HernándezI, EguinoaAZ, BurgosR, VilaA, SimóR, CiudinA. The impact of bariatric surgery on the muscle mass in patients with obesity: 2-year follow-up. Obes Surg, 2022, 32: 625-633
CrossRef Google scholar
[8.]
GalataC, HodappJ, WeißC, KarampinisI, VassilevG, ReißfelderC, OttoM. Skeletal muscle mass index predicts postoperative complications in intestinal surgery for Crohn’s disease. J Parenter Enteral Nutr, 2020, 44(4): 714-721
CrossRef Google scholar
[9.]
SantosC, CarvalhoM, OliveiraL, PalmeiraA, RodriguesLM, GregórioJ. The long-term association between physical activity and weight regain, metabolic risk factors, quality of life and sleep after bariatric surgery. Int J Environ Res Public Health, 2022, 19(14): 8328
CrossRef Google scholar
[10.]
PradoCM, LieffersJR, McCargarLJ, ReimanT, SawyerMB, MartinL, BaracosVE. Prevalence and clinical implications of sarcopenic obesity in patients with solid tumours of the respiratory and gastrointestinal tracts: a population-based study. Lancet Oncol, 2008, 9(7): 629-635
CrossRef Google scholar
[11.]
Soriano-MaldonadoA, Martínez-ForteS, Ferrer-MárquezM, Martínez-RosalesE, Hernández-MartínezA, Carretero-RuizA, Villa-GonzálezE, Barranco-RuizY, Rodríguez-PérezMA, Torrente-SánchezMJ, Carmona-RodríguezL, Soriano-MaldonadoP, Vargas-HitosJA, Casimiro-AndújarAJ, ArteroEG, Fernández-AlonsoAM. Physical exercise following bariatric surgery in women with morbid obesity: study protocol clinical trial (SPIRIT compliant). Medicine (Baltimore), 2020, 99(12): e19427
CrossRef Google scholar
[12.]
Villa-GonzálezE, Barranco-RuizY, Rodríguez-PérezMA, Carretero-RuizA, García-MartínezJM, Hernández-MartínezA, Torrente-SánchezMJ, Ferrer-MárquezM, Soriano-MaldonadoA, ArteroEGEFIBAR Study Group. Supervised exercise following bariatric surgery in morbid obese adults: CERT-based exercise study protocol of the EFIBAR randomised controlled trial. BMC Surg, 2019, 19(1): 127
CrossRef Google scholar
[13.]
BastosECL, BarbosaEMWG, SorianoGMS, dos SantosEA, VasconcelosSML. Determinants of weight regain after bariatric surgery. Arq Bras Cir Dig, 2013, 26(1): 26-32
CrossRef Google scholar
[14.]
SuterM, CalmesJM, ParozA, GiustiV. A 10-year experience with laparoscopic gastric banding for morbid obesity: High long-term complication and failure rates. Obes Surg, 2006, 16(7): 829-835
CrossRef Google scholar
[15.]
DoniniLM, BusettoL, BischoffSC, CederholmT, Ballesteros-PomarMD, BatsisJA, BauerJM, BoirieY, Cruz-JentoftAJ, DickerD, FraraS, FrühbeckG, GentonL, GepnerY, GiustinaA, GonzalezMC, HanHS, HeymsfieldSB, HigashiguchiT, LavianoA, LenziA, NyulasiI, ParrinelloE, PoggiogalleE, PradoCM, SalvadorJ, RollandY, SantiniF, SerlieMJ, ShiH, SieberCC, SiervoM, VettorR, VillarealDT, VolkertD, YuJ, ZamboniM, BarazzoniR. Definition and diagnostic criteria for sarcopenic obesity: ESPEN and EASO consensus statement. Obes Facts, 2022, 15(3): 321-335
CrossRef Google scholar
[16.]
BellichaA, van BaakMA, BattistaF, BeaulieuK, BlundellJE, BusettoL, CarraçaEV, DickerD, EncantadoJ, ErmolaoA, Farpour-LambertN, PramonoA, WoodwardE, OppertJM. Effect of exercise training before and after bariatric surgery: A systematic review and meta-analysis. Obes Rev, 2021, 22(Suppl 4): e13296
CrossRef Google scholar
[17.]
BellichaA, van BaakMA, BattistaF, BeaulieuK, BlundellJE, BusettoL, CarraçaEV, DickerD, EncantadoJ, ErmolaoA, Farpour-LambertN, PramonoA, WoodwardE, OppertJM. Effect of exercise training on weight loss, body composition changes, and weight maintenance in adults with overweight or obesity: An overview of 12 systematic reviews and 149 studies. Obes Rev, 2021, 22(Suppl 4): e13256
CrossRef Google scholar
[18.]
ChenL, NelsonDR, ZhaoY, CuiZ, JohnstonJA. Relationship between muscle mass and muscle strength, and the impact of comorbidities: a population-based, cross-sectional study of older adults in the United States. BMC Geriatr, 2013, 13(1): 74
CrossRef Google scholar
[19.]
ChenJ, KaurH, JaquesJ, RockZ, DeanCM, LordRV, PredaV. Association of clinically significant weight loss with number of patient visits and months of attendance at an Australian multidisciplinary weight management clinic. Clin Obes., 2022, 12(3): e12520
CrossRef Google scholar
[20.]
KonopkaAR, HarberMP. Skeletal muscle hypertrophy after aerobic exercise training. Exerc Sport Sci Rev, 2014, 42(2): 53-61
CrossRef Google scholar
[21.]
O’LearyKJ, KillarneyA, HansenLO, JonesS, MalladiM, MarksK, ShahHM. Effect of patient-centred bedside rounds on hospitalised patients’ decision control, activation and satisfaction with care. BMJ Qual Saf, 2016, 25(12): 921-928
CrossRef Google scholar
[22.]
MendesC, CarvalhoM, OliveiraL, RodriguesLM, GregórioJ. Nurse-led intervention for the management of bariatric surgery patients: a systematic review. Obes Rev, 2023
CrossRef Google scholar
[23.]
Santos C, Raimundo A, Carvalho M, Martins S. Effects of exercise on sarcopenia in patients undergoing bariatric surgery: a systematic review, PROSPERO. 2022. https://www.researchgate.net/publication/360902137_Effects_of_exercise_on_sarcopenia_in_patients_undergoing_bariatric_surgery_A_systematic_review. Accessed 28 May 2022.
[24.]
SantosCA, RaimundoA, CarvalhoM, MartinsS. Effects of physical exercise on sarcopenia after bariatric surgery: study protocol of a randomized controlled trial. MethodsX, 2022
CrossRef Google scholar
[25.]
SantosCA, CinzaAM, LaranjeiraÂ, AmaroM, CarvalhoM, BravoJ, MartinsS, RaimundoA. A dataset on skeletal muscle mass index, body composition and strength to determinate sarcopenia in bariatric patients. Data Brief, 2023, 46: 108881
CrossRef Google scholar
[26.]
SantosCA, CinzaAM, LaranjeiraÂ, AmaroM, CarvalhoM, MartinsS, BravoJ, RaimundoA. The impact of exercise on prevention of sarcopenia after bariatric surgery: The study protocol of the EXPOBAR randomized controlled trial. Contemp Clin Trials Commun., 2022, 31: 101048
CrossRef Google scholar
[27.]
PekařM, PekařováA, BužgaM, HoléczyP, SoltesM. The risk of sarcopenia 24 months after bariatric surgery – assessment by dual energy X-ray absorptiometry (DEXA): a prospective study. Videosurg and Other Miniinvas Tech, 2020, 15(4): 583-587
CrossRef Google scholar
[28.]
StineJG, et al. . American College of Sports Medicine (ACSM) International Multidisciplinary Roundtable report on physical activity and nonalcoholic fatty liver disease. Hepatol Commun, 2023, 7(4): 108
CrossRef Google scholar
[29.]
BushmanBA. Determining the i (Intensity) for a FITT-VP aerobic exercise prescription. ACSMs Health Fit J, 2014, 18(3): 4-7
CrossRef Google scholar
[30.]
MoherD, LiberatiA, TetzlaffJ, AltmanDG. Preferred reporting items for systematic reviews and meta-analyses: the PRISMA statement. BMJ, 2009, 339(7716): 332-336
CrossRef Google scholar
[31.]
PageMJ, McKenzieJE, BossuytPM, BoutronI, HoffmannTC, MulrowCD, ShamseerL, TetzlaffJM, AklEA, BrennanSE, ChouR, GlanvilleJ, GrimshawJM, HróbjartssonA, LaluMM, LiT, LoderEW, Mayo-WilsonE, McDonaldS, McGuinnessLA, StewartLA, ThomasJ, TriccoAC, WelchVA, WhitingP, MoherD. The PRISMA 2020 statement: an updated guideline for reporting systematic reviews. BMJ, 2021, 372: n71
CrossRef Google scholar
[32.]
MoherD, HorsleyT, MorganK, TriccoA, TsertsvadzeA. Blinded versus unblinded assessments of risk-of-bias in studies included in a systematic review. Cochrane Database Syst Rev, 2007
CrossRef Google scholar
[33.]
HassannejadA, KhalajA, MansourniaMA, TabeshMR, AlizadehZ. The effect of aerobic or aerobic-strength exercise on body composition and functional capacity in patients with BMI ≥35 after bariatric surgery: a randomized control trial. Obes Surg, 2017, 27(11): 2792-2801
CrossRef Google scholar
[34.]
InG, TaskinHE, AlM, AlptekinHK, ZenginK, YumukV, IkitimurB. Comparison of 12-week fitness protocols following bariatric surgery: aerobic exercise versus aerobic exercise and progressive resistance. Obes Surg, 2021, 31(4): 1475-1484
CrossRef Google scholar
[35.]
Marc-HernándezA, Ruiz-TovarJ, AracilA, GuillénS, Moya-RamónM. Effects of a high-intensity exercise program on weight regain and cardio-metabolic profile after 3 years of bariatric surgery: a randomized trial. Sci Rep, 2020, 10(1): 1-10
CrossRef Google scholar
[36.]
HerringLY, StevinsonC, CarterP, BiddleSJH, BowreyD, SuttonC, DaviesMJ. The effects of supervised exercise training 12–24 months after bariatric surgery on physical function and body composition: a randomised controlled trial. Int J Obes, 2017, 41(6): 909-916
CrossRef Google scholar
[37.]
HuckCJ. Effects of supervised resistance training on fitness and functional strength in patients succeeding bariatric surgery. J Strength Cond Res, 2015, 29(3): 589-595
CrossRef Google scholar
[38.]
ShahM, SnellPG, RaoS, Adams-HuetB, QuittnerC, LivingstonEH, GargA. High-volume exercise program in obese bariatric surgery patients: a randomized, controlled trial. Obesity, 2011, 19(9): 1826-1834
CrossRef Google scholar
[39.]
Noack-SegoviaJP, Sánchez-LópezAM, García-GarcíaI, Rodríguez-BlanqueR, León-RíosXA, Aguilar-CorderoMJ. Physical exercise and grip strength in patients intervened through bariatric surgery. Aquichan, 2019, 19(3): 6
CrossRef Google scholar
[40.]
DanielsP, BurnsRD, BrusseauTA, HallMS, DavidsonL, AdamsTD, EisenmanP. Effect of a randomised 12-week resistance training programme on muscular strength, cross-sectional area and muscle quality in women having undergone Roux-en-Y gastric bypass. J Sports Sci, 2018, 36(5): 529-535
CrossRef Google scholar
[41.]
VassilevG, GalataC, FinzeA, WeissC, OttoM, ReissfelderC, BlankS. Sarcopenia after Roux-en-Y gastric bypass: detection by skeletal muscle mass index vs. bioelectrical impedance analysis. J Clin Med, 2022, 11(6): 1468
CrossRef Google scholar
[42.]
KimKM, JangHC, LimS. Differences among skeletal muscle mass indices derived from height-, weight-, and body mass index-adjusted models in assessing sarcopenia. Korean J Intern Med, 2016, 31(4): 643-650
CrossRef Google scholar
[43.]
BoppreG, Diniz-SousaF, VerasL, OliveiraJ, FonsecaH. Can exercise promote additional benefits on body composition in patients with obesity after bariatric surgery? A systematic review and meta-analysis of randomized controlled trials. Obes Sci Pract, 2022, 8(1): 112
CrossRef Google scholar
[44.]
NuijtenMAH, EijsvogelsTMH, MonpellierVM, JanssenIMC, HazebroekEJ, HopmanMTE. The magnitude and progress of lean body mass, fat-free mass, and skeletal muscle mass loss following bariatric surgery: a systematic review and meta-analysis. Obes Rev, 2022, 23(1)
CrossRef Google scholar
[45.]
CastelloV, SimõesRP, BassiD, CataiAM, ArenaR, Borghi-SilvaA. Impact of aerobic exercise training on heart rate variability and functional capacity in obese women after gastric bypass surgery. Obes Surg, 2011, 21(11): 1739-1749
CrossRef Google scholar
[46.]
AminianA, ChangJ, BrethauerSA, KimJJ. ASMBS updated position statement on bariatric surgery in class I obesity (BMI 30–35 kg/m2). Surg Obes Relat Dis, 2018, 14(8): 1071-1087
CrossRef Google scholar
[47.]
EisenbergD, et al. . 2022 ASMBS and IFSO: Indications for metabolic and bariatric surgery. Surg Obes Relat Dis, 2022, 18(12): 134-156
[48.]
BlumeCA, BoniCC, CasagrandeDS, RizzolliJ, PadoinAV, MottinCC. Nutritional profile of patients before and after Roux-en-Y gastric bypass: 3-year follow-up. Obes Surg, 2012, 22(11): 1676-1685
CrossRef Google scholar
[49.]
ShahM, SimhaV, GargA. Long-term impact of bariatric surgery on body weight, comorbidities, and nutritional status. J Clin Endocrinol Metab, 2006, 91(11): 4223-4231
CrossRef Google scholar
Funding
Faculdade de Ciências e Tecnologia, Universidade Nova de Lisboa; Universidade de évora

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