Developing a screening tool for sarcopenia in hospitalized geriatric patients: Estimation of appendicular skeletal muscle mass using bioelectrical impedance

Clinical Nutrition xxx (xxxx) xxx

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Original article

Developing a screening tool for sarcopenia in hospitalized geriatric patients: Estimation of appendicular skeletal muscle mass using bioelectrical impedance Rachel R. Deer a, b, Leyla Akhverdiyeva c, Yong-Fang Kuo a, d, Elena Volpi a, e, * a

Sealy Center on Aging, University of Texas Medical Branch, 301 University Blvd, Galveston, TX, 77555, USA Division of Rehabilitation Sciences, University of Texas Medical Branch, 301 University Blvd, Galveston, TX, 77555, USA School of Medicine, University of Texas Medical Branch, 301 University Blvd, Galveston, TX, 77555, USA d Dept. of Preventive Medicine and Population Health, Office of Biostatistics, University of Texas Medical Branch, 301 University Blvd, Galveston, TX, 77555, USA e Dept. of Internal Medicine, Division of Geriatrics, University of Texas Medical Branch, 301 University Blvd, Galveston, TX, 77555, USA b c

a r t i c l e i n f o

s u m m a r y

Article history: Received 10 December 2018 Accepted 7 October 2019

Background & aims: Sarcopenia is now a billable ICD-10 geriatric condition characterized by low appendicular skeletal muscle mass (ASMM) and low function. There is an increasing need for portable, provider-friendly, cost-effective methods for estimating ASMM. The overall goal of this project was to create and validate a regression model for obtaining ASMM from Bioelectrical Impedance Analysis (BIA) measurements using Dual-energy X-ray Absorptiometry (DXA) as the reference. Methods: Geriatric patients (
65 years of age) were enrolled during an acute hospitalization. Body composition measurements were obtained through DXA and BIA devices. The ASMM prediction model was derived using stepwise multiple regression modeling. The model was 10 fold validated and tested as a screening tool (sensitivity, specificity, positive and negative predictive values) using the Foundation for the NIH Sarcopenia Project (FNIH) definition. Results: The following variables were selected by stepwise regression modeling: sex, body mass index, max grip strength, and fat mass derived by BIA. The model was internally validated with 10 fold cross validation. Using the FNIH definition, the model was found to have a sensitivity of 80%, a specificity of 91%, a positive predictive value of 73% and a negative predictive value of 93%. Conclusions: We have developed a screening tool that can be easily used in geriatric patients to screen for sarcopenia. Once validated with a larger sample, the developed prediction model can be used to estimate ASMM using provider-friendly measurements and can be easily implemented as a sensitive screening tool for identifying patients at risk for sarcopenia. Those identified at risk would undergo further functional testing for diagnosis and treatment of sarcopenia. © 2019 Elsevier Ltd and European Society for Clinical Nutrition and Metabolism. All rights reserved.

Keywords: Sarcopenia Appendicular skeletal muscle mass Bioelectrical impendence analysis Dual-energy X-ray absorptiometry Geriatric patients

1. Introduction

Abbreviations: ASMM, Appendicular Skeletal Muscle Mass; BIA, Bioelectrical Impedance Analysis; BMI, Body Mass Index; BUN, Blood urea nitrogen; DXA, Dual Energy X-ray Absorptiometry; EWGSOP, European Working Group on Sarcopenia in Older Persons; FM, Fat mass; FMBIA, Fat mass measured by Bioelectrical Impedance Analysis; FMDXA, Fat mass measured by DXA; FNIH, Foundation of NIH Sarcopenia Project; IWGS, International Working Group Sarcopenia Initiative. * Corresponding author. Sealy Center on Aging, University of Texas Medical Branch, 301 University Blvd, Galveston, TX 77555-0177, USA. E-mail addresses: [email protected] (R.R. Deer), [email protected] (L. Akhverdiyeva), [email protected] (Y.-F. Kuo), [email protected] (E. Volpi).

Over 20% of hospitalized geriatric patients suffer from sarcopenia [1, 2]. This age-associated loss of skeletal muscle mass and function is exacerbated by catabolic stressors such as hospitalization, illness, or injury [3]. The causes of sarcopenia are multifactorial and associated with malnutrition, endocrine changes, neurodegenerative diseases, disuse and atrophy of the muscles [4]. The ability to prevent, diagnose and treat sarcopenia is important as a substantial loss of muscle can result in functional impairment and disability leading to increased morbidity and mortality [5]. Several international consensus panels including Foundation for the NIH Sarcopenia

https://doi.org/10.1016/j.clnu.2019.10.005 0261-5614/© 2019 Elsevier Ltd and European Society for Clinical Nutrition and Metabolism. All rights reserved.

Please cite this article as: Deer RR et al., Developing a screening tool for sarcopenia in hospitalized geriatric patients: Estimation of appendicular skeletal muscle mass using bioelectrical impedance, Clinical Nutrition, https://doi.org/10.1016/j.clnu.2019.10.005

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Project (FNIH) [6], International Working Group Sarcopenia Initiative (IWGS) [3], and European Working Group on Sarcopenia in Older Persons (EWGSOP2) [4,7] have established operational definitions for sarcopenia. All three definitions utilize a measure of function (gait speed, handgrip strength) plus the measure of appendicular skeletal muscle mass (ASMM). Cross-sectional data show that a larger decrease in ASMM occurs with aging when compared to non-appendicular muscle mass [8], making ASMM a good representation of the extent of lost muscle mass. With the growing awareness of the prevalence of sarcopenia and addition of the syndrome to the ICD-10 coding system [9] there is a need for a portable and cost-effective approach to measuring ASMM and sarcopenia status in elderly patients. ASMM can be measured in multiple ways: dual energy X-ray absorptiometry (DXA), magnetic resonance imaging, computerized tomography (CT), anthropometry, ultrasound, and bioelectrical impedance analysis (BIA) [10,11]. DXA radiologic scans provide precise regional assessments of appendicular muscle mass and are often considered to be the reference standard for the measurement of ASMM[13]. BIA devices are commonly used to estimate body composition because they are portable, non-invasive, inexpensive, safe, and require minimal maintenance and training [13]. BIA devices estimate body composition by measuring tissue impedance to an alternating current passed through the body. Devices come in various complexities with all devices measuring electrical properties of the body, reactance and resistance. However, not all devices report these measures. Some models, mostly more affordable ones, implement proprietary computations based on prediction models to report only estimations of body composition. The prediction models are formulated based on studied populations and are the most accurate in these specific populations. When compared to DXA, the reference standard, BIA has been reported to be less accurate in the estimation of body composition [14]. Earlier studies have validated the use of BIA estimates against DXA in determining ASMM through prediction models [15, 16]. Previous models implemented measures of reactance and resistance obtained through “hand to foot” BIA devices that required the application of electrodes. Such devices increase the exam cost, require additional steps, and decrease the overall applicability of BIA devices in the acute hospital settings. Currently, there are no BIA-determined prediction models for estimating ASMM in acutely ill and hospitalized geriatric patients. Moreover, there is limited research completed on determining ASMM from BIA derived fat mass (FMBIA), measured by a single frequency “foot to foot” device (resembling bathroom weight scales). Prediction models that use single frequency BIA derived measurements could provide useful data for evaluating acutely ill geriatric patients' sarcopenic status. The overall goal of this project is to create a regression model for obtaining ASMM from a “foot to foot” BIA measurements using DXA as the reference. Our long-term goal is to develop a tool to help physicians screen for and diagnose sarcopenia in their acutely ill geriatric patients with simple and cost-effective devices. 2. Methods 2.1. Research design All data was collected from a single university hospital from January 2013 to January 2018. Data was pooled from three ongoing studies to establish the model. All studies were approved by the University of Texas Medical Branch (UTMB) Institutional Review Board (IRB # 13e038, 14e0527, and 16e0146). Patients eligible for inclusion met the following criteria: 65 years or older, English speaking, able to provide consent, ability to stand upright, and testing could be completed within 72 h of admission. Written

informed consent was obtained from each subject prior to any study procedure. 2.2. Testing Testing occurring during acute hospitalization. Testing measures included [1]: demographics (age, gender, race; collected from electronic medical records) [2], body composition measures of fat mass (FM) and ASMM of legs and arm dual-energy X-ray absorptiometry (GE Lunar iDXA) and estimated %FM by bioimpedance (Tanita; BF-350) [3], anthropometric measures (height, weight, mid-arm circumference, triceps skinfold thickness, calf circumference) [4], laboratory measures (creatinine, albumin, blood urea nitrogen; collected from electronic medical records) [5], physical function tests (usual gait speed and bilateral hand grip strength) [6], questionnaires (activities of daily living; ADL, and instrumental activities of daily living; IADL), and [7] chart review (admission history). Detailed protocols of baseline testing have been published previously [17]. 2.3. Statistical analysis Data were analyzed using IBM SPSS Version 24 and Stata Version 14. A p-value <0.05 was considered statistically significant. Subjects Characteristics: Descriptive statistics were reported for age, sex, ethnicity, race, grip strength and body composition measures. ASMM was calculated as the sum of lean mass of the arms and legs measured by DXA (ASMMDXA) [12]. Grip strength was established as the maximum obtained from left or right-hand attempts. Significant differences in subject characteristics between females and males were explored using unpaired t-test. Derivation of the prediction regression: Scatterplots for linearity were run to determine variables associated with ASMM. FMBIA, age, gender, max grip strength, gait speed, body mass index (BMI), creatinine, albumin, blood urea nitrogen, triceps skinfold, mid arm and calf circumference were selected as potential model variables. Stepwise multiple regression modeling was chosen to derive the ASMM prediction model with the following selection criteria: p value for inclusion of 0.05 and exclusion of
0.10. The statistics assumptions of regression model including normality of error distribution, homoscedasticity of the errors, and collinearity were checked by residual plots and variance inflation factor. We also assessed whether there were outliers or influential cases by leverage statistics, Cook's distance, and DFFITS. Comparison of ASMM measured by DXA and regression model: BlandeAltman analysis was used to determine the level of agreement between ASMM obtained through the regression model (ASMMBIA) and DXA (ASMMDXA). The mean difference, standard deviation and the 95% confidence interval were reported. The performance of the predictive model was assessed using 10 fold cross validation [18, 19]. The 10 group R2, mean absolute error and root mean square error were reported. We used BlandeAltman plots to visually present the agreement between the prediction of ASMM from our model and ASMM measured by DXA. Since our sample is not large, we used 10-fold cross-validation to estimate the prediction error of our model. Testing the model as a screening tool for Sarcopenia using Foundation for the NIH Sarcopenia and European Working Group on Sarcopenia in Older People Definitions: The Foundation of NIH Sarcopenia Project (FNIH) definition for weakness (hand grip: male<26 kg; female<16 kg) and low lean mass (ASMM: male<19.75 kg; female<15.02 kg) and the European Working Group on Sarcopenia in Older People (EWGSOP2) definition for weakness (hand grip: male<27 kg; female<16 kg) and low lean mass (ASMM:/ht2 male<7 kg; female<6 kg) was used to determine

Please cite this article as: Deer RR et al., Developing a screening tool for sarcopenia in hospitalized geriatric patients: Estimation of appendicular skeletal muscle mass using bioelectrical impedance, Clinical Nutrition, https://doi.org/10.1016/j.clnu.2019.10.005

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the test subject's sarcopenia status. The ASMM measure used in the definition was determined through the study's prediction model (ASMMBIA) and then compared to DXA derived measure of ASMM (ASMMDXA). The sensitivity, specificity, positive and negative predictive values were calculated.

ASMMDXA. There were no violations of statistics assumptions in our prediction model. We also did not detect any outliers or influential cases in our model.

3. Results

The BlandeAltman plot showed the regression model to underestimate ASMM with a mean difference of 0.0036 ± 2.407 kg (p > 0.05) when compared to the mean difference of zero (Fig. 1). The 10 Fold Validation revealed a 10 group R2 of 0.690 ± 0.008, mean absolute error of 2.065 ± 0.3279 and root mean square error of 2.559 ± 0.047. Testing the model as a screening tool for Sarcopenia using Foundation for the NIH Sarcopenia and European Working Group on Sarcopenia in Older People Definitions: Prevalence of sarcopenia was 24% when using FNIH or EWGSOP2 cutpoints as the standard, with no differences between the two standards. The prevalence of sarcopenia in the study population determined by the prediction model was 26%. Our model had a sensitivity of 80%, a specificity of 91%, a positive predictive value of 73% and a negative predictive value of 93% (Table 3).

3.3. Comparison of ASMM measured by DXA and regression model

3.1. Subjects Characteristics From January 2013 to January 2019, 229 subjects were enrolled in the study. 65 patients were excluded because the patient was discharged prior to completion of the measurements. 25 were excluded because they were unable to stand. Of the 139 patients that met the inclusion/exclusion criteria, 14 were excluded due to missing BIA, DXA, and/or max grip data. The final sample size consisted of 125 subjects and their characteristics are shown in Table 1. The sample included 85 females and 40 males, with average age of 77 ± 7 years. Similar to our previous work in this population [20], discharge diagnosis for the sample was primarily cardiovascular (26%), pulmonary (23%) or gastrointestinal (19%). On average the subjects had a FMBIA of 35.55%, FMDXA of 39.50% and ASMMDXA of 18.35 kg. Height, weight, FMBIA, FMDXA, ASMMBIA, and ASMMDXA, did differ significantly between males and females.

4. Discussion In this study we established a new equation to estimate appendicular skeletal muscle mass in acutely ill hospitalized patients. Using either the FNIH or the EWGSOP2 definitions of sarcopenia, the model had a sensitivity of 80% and a specificity of 91% for diagnosing patients with sarcopenia. The addition of sarcopenia into the ICD-10-CM codes, M62.84, has established this geriatric syndrome as a reportable medical disease. The growing awareness of the prevalence of sarcopenia among health professionals has resulted in the need for a screening tool. The diagnosis of sarcopenia is made using ASMM and a measure of function (handgrip strength or gait speed). Estimating ASMM and diagnosing sarcopenia at hospital admission in acutely ill geriatric patients is important because hospitalization can rapidly accelerate muscle loss and lead to functional

3.2. Derivation of the prediction regression Scatterplot analysis revealed FMBIA, max grip strength and BMI had a linear relationship with ASMMDXA. A stepwise multiple regression model was used to derive the ASMMBIA. The prediction model included the following variables: gender, BIA measured FM%, max grip strength, and BMI (Table 2). The following model was calculated: ASMMBIA ¼ 7.1 þ (2.8  Gender) [male ¼ 0; female ¼ 1] þ (0.5  BMI) þ (0.1  Max Grip Strength) þ (0.1  FMBIA2). R2 and root mean square deviation (RMSD) for the equation was 0.69 and 2.56, respectively. Table 2 demonstrates that gender, the main contributor in our model, explained 40.4% of the variance. FMBIA explained an additional 1.3% of the variance seen in

Table 1 Characteristics of study participants expressed as frequencies or means. Minimum and maximum values are given in brackets.

Age, yrs Female, % White, % Hispanic, % Body Composition Height, cm Weight, kg BMI, kg/m2 FMBIA, % FMDXA, % ASMMDXA, kg ASMMBIA, kg Physical Function Grip strength, kg Gait Speed, m/s Anthropometric Measures Tricep Skinfold, mm Mid Arm Circumference, cm Calf Circumference, cm Laboratory Results BUN, mg/dL Creatinine, mg/dL Albumin g/dL

N

Whole Sample

N

Male

40

78.98 ± 6.28

125

78.72 ± 7.60 68.00% 85.60% 8.80%

(65e98)

125 125 125 125 125 125 125

163.94 ± 8.85 75.84 ± 17.08 28.16 ± 5.69 35.55 ± 8.81 39.50 ± 7.55 18.35 ± 4.60 17.63 ± 3.56

(142.40e190.50) (43.80e124.30) (16.73e44.28) (14.70e53.70) (18.52e58.48) (9.41e33.53) (11.71e27.11)

40 40 40 40 40 40 40

171.77 ± 8.25 86.31 ± 16.54 29.25 ± 5.19 29.52 ± 7.90 35.51 ± 6.84 22.61 ± 3.86 21.46 ± 2.33

(152.10e190.50) (62.30e124.30) (19.44e40.87) (14.70e46.50) (18.52e49.05) (15.30e33.53) (17.62e27.11)

85 85 85 85 85 85 85

125 123

19.08 ± 8.82 0.65 ± 0.27

(1e38.5) (0.14e1.55)

40 40

26.88 ± 8.21 0.69 ± 0.30

(10e38.5) (0.18e1.55)

75 75 75

14.78 ± 10.79 26.43 ± 5.41 34.64 ± 3.77

(2.00e45.00) (15.92e43.13) (26.40e44.53)

23 23 23

12.54 ± 10.21 28.18 ± 4.76 35.54 ± 3.91

123 123 79

23.15 ± 13.82 1.19 ± 0.95 3.73 ± 0.49

(5e78) (0.32e9.90) (2.10e5.00)

40 40 26

25.75 ± 13.90 1.46 ± 1.43 3.61 ± 0.38

(70e93)

N

Female

85

78.60 ± 8.18

p-valuea (65e98)

ns

160.25 ± 6.41 70.91 ± 15.07 27.65 ± 5.86 38.39 ± 7.75 41.38 ± 7.15 16.34 ± 3.40 15.83 ± 2.43

(142.40e177.80) (43.80e122.80) (16.73e44.28) (16.90e53.70) (19.74e58.47) (9.41e26.76) (11.71e23.27)

<0.001 <0.001 ns <0.001 <0.001 <0.001 <0.001

85 83

15.41 ± 6.40 0.63 ± 0.26

(1e33.7) (0.14e1.26)

<0.001 ns

(2.33e45.00) (19.36e35.18) (30.93e43.13)

52 52 52

15.77 ± 10.99 25.65 ± 5.54 34.23 ± 3.68

(2.00e41.67) (15.92e43.13) (26.40e44.53)

ns ns ns

(5e78) (0.63e9.90) (2.90e4.20)

83 83 53

21.90 ± 13.69 1.06 ± 0.55 3.79 ± 0.53

(7e78) (0.32e3.60) (2.10e5.00)

ns ns ns

87.50% 5.00%

84.71% 10.59%

ASMMBIA: appendicular skeletal muscle mass derived from the model; ASMMDXA: appendicular skeletal muscle mass measured by DXA; BIA: bioelectrical impedance analysis; BMI: body mass index; BUN: Blood Urea Nitrogen; DXA: dual-x-ray absorptiometry; FMBIA: Fat mass measured by BIA; FMDXA: Fat mass measured by DXA. afor significant differences between women and men, n.s. not significant (p > 0.001).

Please cite this article as: Deer RR et al., Developing a screening tool for sarcopenia in hospitalized geriatric patients: Estimation of appendicular skeletal muscle mass using bioelectrical impedance, Clinical Nutrition, https://doi.org/10.1016/j.clnu.2019.10.005

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Table 2 Multiple linear regression model for predicting ASMMDXA from FMBIA, gender, BMI, and grip strength.

Constant Gender (male ¼ 0; female ¼ 1) BMI, kg/m2 Grip strength, kg FMBIA, %

Coefficient

SE

p-Value

R2 cumulative

RMSD

7.145 0.284 0.504 0.146 0.108

1.555 0.780 0.061 0.033 0.044

<0.001 <0.001 <0.001 <0.001 <0.001

e 0.404 0.631 0.677 0.69

e 3.552 2.795 2.613 2.561

Equation: 7.1 þ (2.8  Gender) þ (0.5  BMI) þ (0.1  Max Grip Strength) þ (0.1  BIAfat). ASMMDXA: appendicular skeletal muscle mass measured by DXA; BIA: bioelectrical impedance analysis; BMI:body mass index; DXA: dual-x-ray absorptiometry; FMBIA: Fat mass measured by BIA; SE: standard error of the coefficient; RMSD: Root mean square deviation.

Fig. 1. Bland Altman of model derived ASMM compared to DXA derived ASMM. The solid line represent the mean difference in ASMM determined by the prediction model and DXA. The dotted line represents the 95% confidence internal of this difference. ASMMDXA: appendicular skeletal muscle mass measured by DXA; ASMMBIA: appendicular skeletal muscle mass derived from prediction model.

impairment if not addressed. ASMM is typically measured by DXA or other imaging method like CT or ultrasound. However, these methods are relatively expensive and difficult to use in the hospital setting due to the need for scheduling instrument time and transporting the patient to the exam room. The portability and cost-effectiveness of single frequency ‘foot to foot’ BIA devices make them a suitable tool for use in a hospital setting to quantify body composition. The use of our prediction equation allows for early diagnosis of sarcopenia.

BIA scales report body composition measures of fat free mass, fat mass and electrical resistance (resistance and reactance). The single frequency ‘foot-to-foot’ device used in the study reports FM% obtained through patented device calculations. Thus, the model presented in this study incorporated the FM% measure in the estimation of ASMM. The variance of 69% seen with our prediction model was lower than in previous ASMM models developed by Kyle et al. [15] and Sergei et al. [16]: 95% and 92% respectively. Both studies

Table 3 Sarcopenia Status determined using FNIH or EWGSOP2 Definitions. DXA Determined ASMM

Model Determined ASMM

Sensitivity Specificity

(þ) Sarcopenia

() Sarcopenia

(þ) Sarcopenia

24

9

() Sarcopenia

6

86

80% 91%

Positive Predictive Value Negative Predictive Value

73% 93%

FNIH: Foundation for the NIH Sarcopenia Project; EWGSOP2: European Working Group on Sarcopenia in Older People.

Please cite this article as: Deer RR et al., Developing a screening tool for sarcopenia in hospitalized geriatric patients: Estimation of appendicular skeletal muscle mass using bioelectrical impedance, Clinical Nutrition, https://doi.org/10.1016/j.clnu.2019.10.005

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implemented the raw measures of resistance and reactance obtained through “hand to foot” BIA devices that required the application of electrodes. However, these devices increase the exam cost due to being more technologically complex, requiring the use of electrode pads and specialized personnel training. The decrease in variance seen in our study can be attributed to the extra proprietary computations done by “foot to foot” BIA devices in specific patient populations to determine FM as opposed to reporting the raw measurements of electrical properties of the body such resistance and reactance. This resulted in an decrease in the error seen in our model. In addition, the ‘foot to foot’ single frequency device used in our study only requires a patient to stand on it allowing for rapid screening in the acute hospital settings. The model we proposed in this study is also clinically valuable as it does include patients with chronic comorbidities comparable to the modeling done by Sergi et al. [16], Reiss et al. [21], and Reiter et al. [22]. Geriatric patients with chronic conditions have a higher incidence of sarcopenia [3]. Catabolic stress induced by chronic conditions contribute to the high prevalence of sarcopenia seen in the geriatric population [3]. The main limitation of our study was the exclusion of patients who could not stand unsupported on the BIA device. This criterion excluded about 10% of our sample. The exclusion of these patients likely resulted in an underestimation of the prevalence of sarcopenia in our sample. In order to determine the sarcopenic status of hospitalized patients that are unable to stand different methods would have to be considered (e.g. electrode bioimpedance instruments, ultrasound or CT scan). However, the potential to quickly and easily screen 90% of the hospitalized patients would provide clinical evidence for the implementation of specific interventions. The study also did not control for patients' total body water, which could have altered the electrical conductance analysis done by the device. Variability of the patients’ water content could be due to use of diuretics, edema, consumption of water prior to testing, or fullness of the bladder [23]. We purposely limited the exclusion criteria of this study to increase the clinical generalizability of our results, enrolling patients whose diet, exercise, and hydration status were not controlled for and could have been affected by the underlying diseases. However, the aim of this study was not to determine the prevalence of sarcopenia in hospitalized patients but to develop a model that could be broadly applied in hospitalized geriatric patients. In conclusion, our model allows for the estimation of ASMM in acutely ill geriatric patients using simple and cost effective ‘foot to foot’ BIA device. The clinical benefit of implementing this equation in hospitals would be to diagnose patients with sarcopenia, which is the first step for implementation of targeted interventions to reduce the risk of functional dependence. Longitudinal studies are also warranted to determine the validity of this novel method for monitoring sarcopenia progression or the efficacy of targeted interventions.

Funding sources This work was supported by the National Dairy Council (1229); UTMB Claude D. Pepper OAIC (P30 AG024832) from the National Institute on Aging; and the UTMB Clinical and Translational Science Award (UL1 TR001439 and TL1 TR001440) from the National Center for Advancing Translational Sciences.

Conflict of interest The authors declare that they have no conflicts of interest.

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Acknowledgements We thank Shawn Goodlett, lead clinical coordinator, for her invaluable assistance with patient recruitment and functional testing. References [1] Cerri AP, Bellelli G, Mazzone A, Pittella F, Landi F, Zambon A, et al. Sarcopenia and malnutrition in acutely ill hospitalized elderly: prevalence and outcomes. Edinburgh, Scotland: Clinical nutrition; 2014. https://doi.org/10.1016/ j.clnu.2014.08.015. [2] Smoliner C, Sieber CC, Wirth R. Prevalence of sarcopenia in geriatric hospitalized patients. J Am Med Dir Assoc 2014;15(4):267e72. https://doi.org/ 10.1016/j.jamda.2013.11.027. [3] Fielding RA, Vellas B, Evans WJ, Bhasin S, Morley JE, Newman AB, et al. Sarcopenia: an undiagnosed condition in older adults. Current consensus definition: prevalence, etiology, and consequences. International working group on sarcopenia. J Am Med Dir Assoc 2011;12(4):249e56. https://doi.org/10.1016/j.jamda.2011.01.003. [4] Cruz-Jentoft AJ, Baeyens JP, Bauer JM, Boirie Y, Cederholm T, Landi F, et al. Sarcopenia: European consensus on definition and diagnosis: report of the European working group on sarcopenia in older people. Age Ageing 2010;39(4):412e23. https://doi.org/10.1093/ageing/afq034. [5] Janssen I, Heymsfield SB, Ross R. Low relative skeletal muscle mass (sarcopenia) in older persons is associated with functional impairment and physical disability. J Am Geriatr Soc 2002;50(5):889e96. [6] Studenski SA, Peters KW, Alley DE, Cawthon PM, McLean RR, Harris TB, et al. The FNIH sarcopenia project: rationale, study description, conference recommendations, and final estimates. J Gerontol Ser A Biol Med Sci 2014;69(5): 547e58. https://doi.org/10.1093/gerona/glu010.
re O, Cederholm T, et al. [7] Cruz-Jentoft AJ, Bahat G, Bauer J, Boirie Y, Bruye Sarcopenia: revised European consensus on definition and diagnosis. Age Ageing 2019. https://doi.org/10.1093/ageing/afz046. [8] Kyle UG, Genton L, Hans D, Karsegard L, Slosman DO, Pichard C. Age-related differences in fat-free mass, skeletal muscle, body cell mass and fat mass between 18 and 94 years. Eur J Clin Nutr 2001;55(8):663e72. https://doi.org/ 10.1038/sj.ejcn.1601198. [9] Anker SD, Morley JE, von Haehling S. Welcome to the ICD-10 code for sarcopenia. J Cachexia Sarcopenia Muscle 2016;7(5):512e4. https://doi.org/ 10.1002/jcsm.12147. [10] Pahor M, Manini T, Cesari M. Sarcopenia: clinical evaluation, biological markers and other evaluation tools. J Nutr Health Aging 2009;13(8):724e8. [11] Heymsfield SB, Gonzalez MC, Lu J, Jia G, Zheng J. Skeletal muscle mass and quality: evolution of modern measurement concepts in the context of sarcopenia. Proc Nutr Soc 2015;74(4):355e66. https://doi.org/10.1017/S0029665115000129. [12] Hind K, Oldroyd B. In-vivo precision of the GE Lunar iDXA densitometer for the measurement of appendicular and trunk lean and fat mass. Eur J Clin Nutr 2013;67(12):1331e3. https://doi.org/10.1038/ejcn.2013.210. [13] Chabin X, Taghli-Lamallem O, Mulliez A, Bordachar P, Jean F, Futier E, et al. Bioimpedance analysis is safe in patients with implanted cardiac electronic devices. Clin Nutr 2018. https://doi.org/10.1016/j.clnu.2018.02.029. [14] LaForgia J, Gunn S, Withers RT. Body composition: validity of segmental bioelectrical impedance analysis. Asia Pac J Clin Nutr 2008;17(4):586e91. [15] Kyle UG, Genton L, Hans D, Pichard C. Validation of a bioelectrical impedance analysis equation to predict appendicular skeletal muscle mass (ASMM). Clin Nutr (Edinb) 2003;22(6):537e43. [16] Sergi G, De Rui M, Veronese N, Bolzetta F, Berton L, Carraro S, et al. Assessing appendicular skeletal muscle mass with bioelectrical impedance analysis in free-living Caucasian older adults. Clin Nutr (Edinb) 2015;34(4):667e73. https://doi.org/10.1016/j.clnu.2014.07.010. [17] Deer RR, Dickinson JM, Fisher SR, Ju H, Volpi E. Identifying effective and feasible interventions to accelerate functional recovery from hospitalization in older adults: a randomized controlled pilot trial. Contemp Clin Trials 2016. https://doi.org/10.1016/j.cct.2016.05.001. [18] Hastie T, Tibshirani R, Friedman J. The elements of statistical learning. Springer; 2017. https://web.stanford.edu/~hastie/ElemStatLearn/. [19] Kim J-H. Estimating classification error rate: repeated cross-validation, repeated hold-out and bootstrap. Comput Stat Data Anal 2009;53(11):3735e45. [20] Deer RR, Dickinson JM, Baillargeon J, Fisher SR, Raji M, Volpi E. A phase I randomized clinical trial of evidence-based, pragmatic interventions to improve functional recovery after hospitalization in geriatric patients. J Gerontol Ser A Biol Med Sci 2019. https://doi.org/10.1093/gerona/glz084. €ssmann H, [21] Reiss J, Iglseder B, Kreutzer M, Weilbuchner I, Treschnitzer W, Ka et al. Case finding for sarcopenia in geriatric inpatients: performance of bioimpedance analysis in comparison to dual X-ray absorptiometry. BMC Geriatr 2016;16:52. https://doi.org/10.1186/s12877-016-0228-z. [22] Reiter R, Iglseder B, Treschnitzer W, Alzner R, Mayr-Pirker B, Kreutzer M, et al. Quantifying appendicular muscle mass in geriatric inpatients: performance of different single frequency BIA equations in comparison to dual X-ray absorptiometry. Arch Gerontol Geriatr 2019;80:98e103. https://doi.org/ 10.1016/j.archger.2018.10.010. [23] Kyle UG, Bosaeus I, De Lorenzo AD, Deurenberg P, Elia M, Manuel Gomez J, et al. Bioelectrical impedance analysis-part II: utilization in clinical practice. Clin Nutr (Edinb) 2004;23(6):1430e53. https://doi.org/10.1016/j.clnu.2004.09.012.

Please cite this article as: Deer RR et al., Developing a screening tool for sarcopenia in hospitalized geriatric patients: Estimation of appendicular skeletal muscle mass using bioelectrical impedance, Clinical Nutrition, https://doi.org/10.1016/j.clnu.2019.10.005