PREDICTIVE EQUATION FOR BLOOD FLOW RESTRICTION TRAINING

Cirilo-Sousa, Maria do Socorro; Lemos, Jiddu Bastos; Poderoso, Rodrigo; Araújo, Ravi Cirilo Targino de; Aniceto, Rodrigo Ramalho; Pereira, Piettra Moura Galvão; Araújo, Joamira Pereira; Lucena, Pedro Henriques Marques; Paz, Carlos Renato; Araújo, Adenilson Targino de

doi:10.1590/1517-869220192506186803

ABSTRACT

Introduction

No research has investigated predictive equations for application in blood flow restriction (BFR) training using a cuff with a circumference of 18 cm for the lower limbs, and including age and sex as predictor variables.

Objectives

To develop an equation to predict cuff pressure levels for use in BFR training for the lower limbs.

Methods

A total of 51 adults (age 23.23 ± 5.24 years) of both sexes (males, n= 32; females, n= 19) underwent a series of tests and anthropometric (body mass, height, body mass index – BMI, and thigh circumference – TC) and hemodynamic (brachial systolic – SBP – and diastolic – DBP – blood pressure) measurements. The arterial occlusion pressure (AOP) of the lower limbs was measured using a Doppler probe.

Results

The predictive equation was developed based on a hierarchical linear regression model consisting of six blocks, corresponding to TC (β = 0.380; p = 0.005), SBP (β = 0.091; p = 0.482), age (β = 0.320; p = 0.015), and sex (β = -0.207; p = 0.105), which explained 39.7% of the variation in arterial occlusion pressure. DBP and BMI were not associated with AOP. As a result, the predictive equation is as follows: AOP (mmHg) = 65.290 + 1.110 (TC in cm) + 0.178 (SBP in mmHg) + 1.153 (age in years) – 7.984 (sex, 1 – male and 2 – female), reporting values of r = 0.630, r² = 0.397 and SEE = 15,289.

Conclusion

Cuff pressure for BFR training of the lower limbs may be selected based on TC, SBP, age and sex, and thigh circumference is considered the main predictor. Level of Evidence III, Non-consecutive studies, or studies without consistently applied reference standard.

Blood circulation; Muscle Strength; Strength Training; Rotator Cuff; Lower extremity

RESUMO

Introdução

Nenhuma pesquisa investigou equações preditivas para aplicação no treinamento de restrição do fluxo sanguíneo (RFS) utilizando um manguito de 18 cm de circunferência para os membros inferiores e incluindo a idade e sexo como variáveis preditoras.

Objetivos

Desenvolver uma equação preditiva dos níveis de pressão do manguito para uso no treinamento de RFS para os membros inferiores.

Métodos

Um total de 51 adultos (23,23 ± 5,24 anos) de ambos os sexos (homens, n = 32; mulheres, n = 19) foram submetidos a uma série de testes e medidas antropométricas (massa corporal, altura, índice de massa corporal – IMC e circunferência da coxa – CC) e hemodinâmicas (pressão sistólica braquial – PSB e diastólica – PDB). A pressão de oclusão arterial (POA) dos membros inferiores foi medida com utilização de uma sonda Doppler.

Resultados

A equação preditiva foi desenvolvida a partir de um modelo hierárquico de regressão linear composto de seis blocos, correspondendo a CC (β = 0,380; p = 0,005), PSB (β = ٠,091; p = 0,482), idade (β = 0,320; p = 0,015) e sexo (β = -0,207; p = 0,105), explicando os 39,7% da variação na pressão de oclusão arterial. O IMC e a PDB não foram associados à POA. Como resultado, apresenta-se a seguinte equação: POA (mmHg) = 65,290 + 1,110 (CC em cm) + 0,178 (PSB em mmHg) + 1,153 (idade em anos) – 7,984 (sexo, 1 – masculino e 2 – feminino), com valores de r = 0,630, r² = 0,397 e EPE = 15,289.

Conclusão

A pressão do manguito para utilização no treinamento de RFS dos membros inferiores pode ser selecionada com base nas medidas de CC, PSB, idade e sexo, sendo que, a circunferência da coxa é considerada o principal preditor. Nível de Evidência III, Estudos não consecutivos ou estudos sem padrão de referência consistentemente aplicado.

Circulação sanguínea; Força muscular; Treinamento de resistência; Manguito rotador; Membros inferiores

RESUMEN

Introducción

Ninguna pesquisa investigó las ecuaciones predictivas para aplicación en el entrenamiento de restricción del flujo sanguíneo (RFS) utilizando un manguito de 18 cm de circunferencia para los miembros inferiores e incluyendo la edad y sexo como variables predictoras.

Objetivos

Desarrollar una ecuación predictiva de los niveles de presión del manguito para uso en el entrenamiento de RFS para los miembros inferiores.

Métodos

Un total de 51 adultos (23,23 ± 5,24 años) de ambos sexos (masculino, n = 32, femenino, n = 19) fueron sometidos a una serie de pruebas y mediciones antropométricas (masa corporal, estatura, índice de masa corporal - IMC y circunferencia del muslo - CM) y hemodinámicas (presión sistólica braquial – PSB , y diastólica – PDB). La presión de oclusión arterial (POA) de los miembros inferiores se midió mediante una sonda Doppler.

Resultados

La ecuación predictiva se desarrolló a partir de un modelo jerárquico de regresión lineal compuesto de seis bloques, correspondiendo a CM (β = 0,380; p = 0,005), PSB (β = 0,091; p = 0,482), edad (β = 0,320; p = 0,015), y sexo (β = -0,207; p = 0,105), explicando 39,7% de la variación en la presión de oclusión arterial. El IMC y la PDB no fueron asociadas a la POA. Como resultado, se presenta la siguiente ecuación: POA (mmHg) = 65,290 + 1,110 (CM en cm) + 0,178 (PAS en mmHg) + 1,153 (edad en años) – 7,984 (sexo, 1 – Masculino y 2 – Femenino), con valores de r = 0,630, r² = 0,397 y EEE = 15,289.

Conclusión

La presión del manguito para su uso en el entrenamiento de RFS de los miembros inferiores puede seleccionarse con base en las medidas de CM, PSB, edad y sexo, siendo que la circunferencia del muslo es considerada el principal predictor. Nivel de Evidencia III, Estudios no consecutivos o estudios sin estándar de referencia consistentemente aplicado.

Circulación sanguínea; Fuerza muscular; Entrenamiento de resistencia; Manguito de los rotadores; Miembros inferiores

INTRODUCTION

Blood flow restriction (BFR) combined with low-load strength training (ST), has been widely reported to promote adaptations similar to the ones induced by high-load.¹1. Laurentino GC, Ugrinowitsch C, Roschel H, Aoki MS, Soares AG, Neves Jr M, et al. Strength training with blood flow restriction diminishes myostatin gene expression. Med Sci Sports Exerc. 2012;44(3):406-12.,²2. Takarada Y, Takazawa H, Sato Y, Takebayashi S, Tanaka Y, Ishii N. Effects of resistance exercise combined with moderate vascular occlusion on muscular function in humans. J Appl Physiol. 2000;88(6):2097-106. Despite the countless proven benefits, there is not yet a consensus on the BFR technique that ought to be prescribed, particularly regarding the amount of cuff pressure that should be applied to the body segments.

The studies have generally used 3-3.3 cm², 5 cm³ and 6 cm⁴ wide cuffs for the upper-body, and 5 cm,³3. Loenneke JP, Kim D, Fahs CA, Thiebaud RS, Abe T, Larson RD, et al. Effects of exercise with and without different degrees of blood flow restriction on torque and muscle activation. Muscle Nerve. 2015;51(5):713-21., ⁵5. ahs CA, Rossow LM, Loenneke JP, Thiebaud RS, Kim D, Bemben DA, et al. Effect of different types of lower body resistance training on arterial compliance and calf blood flow. Clin Physiol Funct Imaging. 2012;32(1):45-51.

6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405.

7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12.

8. Rossow LM, Fahs CA, Loenneke JP, Thiebaud RS, Sherk VD, Abe T, et al. Cardiovascular and perceptual responses to blood-flow-restricted resistance exercise with differing restrictive cuffs. Clin Physiol Funct Imaging. 2012;32(5):331-7.-⁹9. Rossow LM, Fahs CA, Sherk VD, Seo DI, Bemben DA, Bemben MG. The effect of acute blood-flow-restricted resistance exercise on postexercise blood pressure. Clin Physiol Funct Imaging. 2011;31(6):429-34. 13.5 cm,⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12., ⁸8. Rossow LM, Fahs CA, Loenneke JP, Thiebaud RS, Sherk VD, Abe T, et al. Cardiovascular and perceptual responses to blood-flow-restricted resistance exercise with differing restrictive cuffs. Clin Physiol Funct Imaging. 2012;32(5):331-7. 18 cm¹1. Laurentino GC, Ugrinowitsch C, Roschel H, Aoki MS, Soares AG, Neves Jr M, et al. Strength training with blood flow restriction diminishes myostatin gene expression. Med Sci Sports Exerc. 2012;44(3):406-12.,¹⁰10. Araujo JP, Silva ED, Silva JC, Souza TS, Lima EO, Guerra I, et al. The acute effect of resistance exercise with blood flow restriction with hemodynamic variables on hypertensive subjects. J Hum Kinet. 2014;43(1):79-85.

11. Gualano B, Ugrinowitsch C, Neves Jr M, Lima FR, Pinto ALS, Laurentino G, et al. Vascular occlusion training for inclusion body myositis: a novel therapeutic approach. J Vis Exp. 2010;40:e1894.

12. Pinto RR, Polito MD. Haemodynamic responses during resistance exercise with blood flow restriction in hypertensive subjects. Clin Physiol Funct Imaging. 2016;36(5):407-13.-¹³13. Poton R, Polito MD. Hemodynamic response to resistance exercise with and without blood flow restriction in healthy subjects. Clin Physiol Funct Imaging. 2016;36(3):231-6. and 18.5²2. Takarada Y, Takazawa H, Sato Y, Takebayashi S, Tanaka Y, Ishii N. Effects of resistance exercise combined with moderate vascular occlusion on muscular function in humans. J Appl Physiol. 2000;88(6):2097-106.,¹⁴14. Suga T, Okita K, Morita N, Yokota T, Hirabayashi K, Horiuchi M, et al. Dose effect on intramuscular metabolic stress during low-intensity resistance exercise with blood flow restriction. J Appl Physiol. 2010;108(6):1563-7. for the lower-body. Additionally, several pressure regimens have been tested, including fixed pressures of 50 mmHg,¹⁵15. Kubota A, Sakuraba K, Koh S, Ogura Y, Tamura Y. Blood flow restriction by low compressive force prevents disuse muscular weakness. J Sci Med Sport. 2011;14(2):95-9. 150 mmHg¹⁶16. Inagaki Y, Madarame H, Neya M, Ishii N. Increase in serum growth hormone induced by electrical stimulation of muscle combined with blood flow restriction. Eur J Appl Physiol. 2011;111(11):2715-21. and 200 mmHg⁹9. Rossow LM, Fahs CA, Sherk VD, Seo DI, Bemben DA, Bemben MG. The effect of acute blood-flow-restricted resistance exercise on postexercise blood pressure. Clin Physiol Funct Imaging. 2011;31(6):429-34. and gradual increasing pressures from 160 to 200 mmHg,⁵5. ahs CA, Rossow LM, Loenneke JP, Thiebaud RS, Kim D, Bemben DA, et al. Effect of different types of lower body resistance training on arterial compliance and calf blood flow. Clin Physiol Funct Imaging. 2012;32(1):45-51. 160 to 230 mmHg.¹⁷17. Abe T, Kearns CF, Sato Y. Muscle size and strength are increased following walk training with restricted venous blood flow from the leg muscle, Kaatsu-walk training. J Appl Physiol. 2006;100(5):1460-6. Pressures calculated using equations, such as the systolic arterial pressure at rest multiplied by 1.3¹⁴14. Suga T, Okita K, Morita N, Yokota T, Hirabayashi K, Horiuchi M, et al. Dose effect on intramuscular metabolic stress during low-intensity resistance exercise with blood flow restriction. J Appl Physiol. 2010;108(6):1563-7.,¹⁸18. Cook SB, Clark BC, Ploutz-Snyder LL. Effects of exercise load and blood-flow restriction on skeletal muscle function. Med Sci Sports Exerc. 2007;39(10):1708-13. or 1.44¹⁹19. Karabulut M, Cramer JT, Abe T, Sato Y, Bemben MG. Neuromuscular fatigue following low-intensity dynamic exercise with externally applied vascular restriction. J Electromyogr Kinesiol. 2010;20(3):440-7.,²⁰20. Karabulut M, Leal JA, Garcia SD, Cavazos C, Bemben M. Tissue oxygenation, strength and lactate response to different blood flow restrictive pressures. Clin Physiol Funct Imaging. 2014;34(4):263-9.; and 50%¹1. Laurentino GC, Ugrinowitsch C, Roschel H, Aoki MS, Soares AG, Neves Jr M, et al. Strength training with blood flow restriction diminishes myostatin gene expression. Med Sci Sports Exerc. 2012;44(3):406-12.,¹¹11. Gualano B, Ugrinowitsch C, Neves Jr M, Lima FR, Pinto ALS, Laurentino G, et al. Vascular occlusion training for inclusion body myositis: a novel therapeutic approach. J Vis Exp. 2010;40:e1894. or 80%⁴4. Neto GR, Sousa MSC, Costa e Silva GV, Gil ALS, Salles BF, Novaes JS. Acute resistance exercise with blood flow restriction effects on heart rate, double product, oxygen saturation and perceived exertion. Clin Physiol Funct Imaging. 2016;36(1):53-9.,¹⁰10. Araujo JP, Silva ED, Silva JC, Souza TS, Lima EO, Guerra I, et al. The acute effect of resistance exercise with blood flow restriction with hemodynamic variables on hypertensive subjects. J Hum Kinet. 2014;43(1):79-85.,²¹21. Neto GR, Sousa MSC, Costa PB, Salles BF, Novaes GS, Novaes JS. Hypotensive effects of resistance exercises with blood flow restriction. J Strength Cond Res. 2015;29(4):1064-70. of the “total” or maximum resting arterial occlusion pressure.

The reason for these variance is that the amount of tissue that surrounds the blood vessels influences the pressure that is applied.⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12. In turn, the cuff pressure selected based on the arterial occlusion pressure at rest measured with a Doppler probe is widely used.¹1. Laurentino GC, Ugrinowitsch C, Roschel H, Aoki MS, Soares AG, Neves Jr M, et al. Strength training with blood flow restriction diminishes myostatin gene expression. Med Sci Sports Exerc. 2012;44(3):406-12.,⁴4. Neto GR, Sousa MSC, Costa e Silva GV, Gil ALS, Salles BF, Novaes JS. Acute resistance exercise with blood flow restriction effects on heart rate, double product, oxygen saturation and perceived exertion. Clin Physiol Funct Imaging. 2016;36(1):53-9.,⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405.,⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12.,¹⁰10. Araujo JP, Silva ED, Silva JC, Souza TS, Lima EO, Guerra I, et al. The acute effect of resistance exercise with blood flow restriction with hemodynamic variables on hypertensive subjects. J Hum Kinet. 2014;43(1):79-85.

11. Gualano B, Ugrinowitsch C, Neves Jr M, Lima FR, Pinto ALS, Laurentino G, et al. Vascular occlusion training for inclusion body myositis: a novel therapeutic approach. J Vis Exp. 2010;40:e1894.

12. Pinto RR, Polito MD. Haemodynamic responses during resistance exercise with blood flow restriction in hypertensive subjects. Clin Physiol Funct Imaging. 2016;36(5):407-13.-¹³13. Poton R, Polito MD. Hemodynamic response to resistance exercise with and without blood flow restriction in healthy subjects. Clin Physiol Funct Imaging. 2016;36(3):231-6.,²¹21. Neto GR, Sousa MSC, Costa PB, Salles BF, Novaes GS, Novaes JS. Hypotensive effects of resistance exercises with blood flow restriction. J Strength Cond Res. 2015;29(4):1064-70. However, Doppler probe are expensive and properly trained technicians to operate. For these reasons, more accessible methods are needed, for instance, regression equations including variables liable to interfere with the cuff pressure, such as sociodemographic (sex, age), anthropometric (body mass index – BMI, thigh circumference – TC) and hemodynamic (systolic and diastolic blood pressures – SBP and DBP) parameters.

Loenneke et al.⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405. formulated various regression equations for the aforementioned purpose, but, they did not include sex,²²22. Drøyvold WB, Midthjell K, Nilsen TI, Holmen J. Change in body mass index and its impact on blood pressure: a prospective population study. Int J Obes (Lond). 2005;29(6):650-5.,²³23. Joyner MJ, Wallin BG, Charkoudian N. Sex differences and blood pressure regulation in humans. Exp Physiol. 2016;101(3):349-55. age,²²22. Drøyvold WB, Midthjell K, Nilsen TI, Holmen J. Change in body mass index and its impact on blood pressure: a prospective population study. Int J Obes (Lond). 2005;29(6):650-5.

23. Joyner MJ, Wallin BG, Charkoudian N. Sex differences and blood pressure regulation in humans. Exp Physiol. 2016;101(3):349-55.-²⁴24. Wei JY. Age and the cardiovascular system. N Engl J Med. 1992;327(24):1735-9. and BMI²²22. Drøyvold WB, Midthjell K, Nilsen TI, Holmen J. Change in body mass index and its impact on blood pressure: a prospective population study. Int J Obes (Lond). 2005;29(6):650-5.,²⁵25. Hunt JEA, Stodart C, Ferguson RA. The influence of participant characteristics on the relationship between cuff pressure and level of blood flow restriction. Eur J Appl Physiol. 2016;116(7):1421-32. in the predictive models. Additionally, one study included sex, race and different widths of cuffs (5 cm, 10 cm and 12 cm) for upper limbs,²⁶26. Jessee MB, Buckner SL, Dankel SJ, Counts BR, Abe T, Loenneke JP. The influence of cuff width, sex, and race on arterial occlusion: implications for blood flow restriction research. Sports Med. 2016;46(6):913-21. and another study included a cuffs of 13 cm,²⁵25. Hunt JEA, Stodart C, Ferguson RA. The influence of participant characteristics on the relationship between cuff pressure and level of blood flow restriction. Eur J Appl Physiol. 2016;116(7):1421-32. but no study has investigated predictive equations using a wider cuff in the lower limbs using together both age and sex as predictor variables.

Therefore, the aim of the present study was to develop an equation to predict the pressure of the 18-cm wide cuff to prescribe BFR training for the lower limbs. It was hypothesized that BFR estimated based on arterial occlusion pressure (AOP) should be determined by sociodemographic, anthropometric and hemodynamic variables.

METHODS

Subjects

The sample consisted of 51 apparently healthy adults (males, n= 32; females, n= 19), Table 1. Individuals with any cardiovascular, metabolic and/or musculoskeletal problems, using dietary supplements, medications and/or nicotine were excluded.

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Table 1
Descriptive characteristics of the subjects (n = 51).

The procedures used in this study were approved by the Institutional Review Board at the Federal University of Paraiba (#0389/11). Written informed consent was obtained from each subject prior to the investigation.

Study design

This investigation examined whether the pressure of BFR can be predicted by the subjects’ sociodemographic, anthropometric and hemodynamic variables. A cross-sectional design was used to observe the relations between the variables and to develop a predictive equation for pressure BFR. The independent (predictor) variables were sex, age (years), body mass index (BMI, kg/m²), thigh circumference (cm), brachial SBP (mmHg) and brachial DBP (mmHg). Arterial occlusion pressure (mmHg) was the dependent (predicted) variable.

The participants were subjected to a series of tests in the laboratory after collecting the data corresponding to the sociodemographic (age and sex) and anthropometric (BM, height and TC) variables. The participants were then asked to rest for 10 minutes on an exam table in dorsal decubitus, with the arms to the sides of the body and the legs uncrossed. Next, the AOP was measured in the lower limbs in a random and counterbalanced manner. The hemodynamic parameters (SBP and DBP) were measured three minutes later.

Data collection was performed in the morning to avoid variations related to the circadian rhythm. The participants arrived at the laboratory with at least two hours of a post absorptive state, having been instructed to hydrate themselves and sleep normally and to abstain from exercise, caffeine and alcohol for at least 24 hours before the tests.

PROCEDURES

Anthropometric measurements

Body mass (BM, kg) and height (cm) were respectively measured using a digital scale (Filizola, Brazil) and stadiometer (Wiso, E210, Brazil). Proximal TC (cm) was measured using an anthropometric tape (Cardiomed, Curitiba, Paraná, Brazil) in the point of the gluteal fold.

Hemodynamic measurements

Brachial SBP (mmHg) and DBP (mmHg) were measured using an automatic blood pressure monitor (Model HEM-705 CP, OMRON, Japan).⁴4. Neto GR, Sousa MSC, Costa e Silva GV, Gil ALS, Salles BF, Novaes JS. Acute resistance exercise with blood flow restriction effects on heart rate, double product, oxygen saturation and perceived exertion. Clin Physiol Funct Imaging. 2016;36(1):53-9.,¹⁰10. Araujo JP, Silva ED, Silva JC, Souza TS, Lima EO, Guerra I, et al. The acute effect of resistance exercise with blood flow restriction with hemodynamic variables on hypertensive subjects. J Hum Kinet. 2014;43(1):79-85.,²¹21. Neto GR, Sousa MSC, Costa PB, Salles BF, Novaes GS, Novaes JS. Hypotensive effects of resistance exercises with blood flow restriction. J Strength Cond Res. 2015;29(4):1064-70. Three measurements were performed at one-minute intervals, and the mean of the last two was calculated.

Measurement of the arterial occlusion pressure

Subjects were asked to lay down in a supine position while resting comfortably for 10 minutes. Then, a vascular Doppler (Medpej DV-2001, Ribeirão Preto, São Paulo, Brazil) probe was placed over the tibial artery to determine the AOP (mmHg) of the subject. A standard blood pressure cuff (80 cm length x 18 cm width)¹1. Laurentino GC, Ugrinowitsch C, Roschel H, Aoki MS, Soares AG, Neves Jr M, et al. Strength training with blood flow restriction diminishes myostatin gene expression. Med Sci Sports Exerc. 2012;44(3):406-12.,¹⁰10. Araujo JP, Silva ED, Silva JC, Souza TS, Lima EO, Guerra I, et al. The acute effect of resistance exercise with blood flow restriction with hemodynamic variables on hypertensive subjects. J Hum Kinet. 2014;43(1):79-85.

11. Gualano B, Ugrinowitsch C, Neves Jr M, Lima FR, Pinto ALS, Laurentino G, et al. Vascular occlusion training for inclusion body myositis: a novel therapeutic approach. J Vis Exp. 2010;40:e1894.

12. Pinto RR, Polito MD. Haemodynamic responses during resistance exercise with blood flow restriction in hypertensive subjects. Clin Physiol Funct Imaging. 2016;36(5):407-13.-¹³13. Poton R, Polito MD. Hemodynamic response to resistance exercise with and without blood flow restriction in healthy subjects. Clin Physiol Funct Imaging. 2016;36(3):231-6. attached to the thigh proximal portion (inguinal fold region) was inflated gradually in increments of 20 mmHg up to the point at which the auscultatory pulse of the tibial artery was interrupted;⁴4. Neto GR, Sousa MSC, Costa e Silva GV, Gil ALS, Salles BF, Novaes JS. Acute resistance exercise with blood flow restriction effects on heart rate, double product, oxygen saturation and perceived exertion. Clin Physiol Funct Imaging. 2016;36(1):53-9.,²¹21. Neto GR, Sousa MSC, Costa PB, Salles BF, Novaes GS, Novaes JS. Hypotensive effects of resistance exercises with blood flow restriction. J Strength Cond Res. 2015;29(4):1064-70. the cuff was inflated an additional 20 mmHg and then deflated at a rate of 5 mmHg every 10 seconds to confirm the AOP value.

Statistical analyses

The sample size was calculated using the program G*Power 3.1.9.2,²⁷27. Faul F, Erdfelder E, Buchner A, Lang AG. Statistical power analyses using G*Power 3.1: tests for correlation and regression analyses. Behav Res Methods. 2009;41(4):1149-60. with an effect size (f²2. Takarada Y, Takazawa H, Sato Y, Takebayashi S, Tanaka Y, Ishii N. Effects of resistance exercise combined with moderate vascular occlusion on muscular function in humans. J Appl Physiol. 2000;88(6):2097-106.) of 0.60, a power of 0.80 (ß = 0.20) and a two-tailed significance level (α) of 0.05, it was established that at least 30 participants were needed to develop a regression equation for the BFR pressure considering the six predictor variables. Statistical analysis was performed using SPSS 16.0 (IBM SPSS, Inc., Chicago, IL, USA). Pearson’s correlation was used to test the bivariate relationship between predictor and predicted variables. The predictive equation was developed by means of a hierarchical linear regression model, which consisted of six individual blocks ranked according to the distal and proximal determinants, as depicted in Figure 1. According to our selected theoretical framework, the variables were hierarchically inserted into the model by their influence on the AOP. In this regard, TC was inserted in the first block, once we believe that it is the main AOP predictor,³3. Loenneke JP, Kim D, Fahs CA, Thiebaud RS, Abe T, Larson RD, et al. Effects of exercise with and without different degrees of blood flow restriction on torque and muscle activation. Muscle Nerve. 2015;51(5):713-21.,⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405.,⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12.,²⁸28. Crenshaw AG, Hargens AR, Gershuni DH, Rydevik B. Wide tourniquet cuffs more effective at lower inflation pressures. Acta Orthop Scand. 1988;59(4):447-51. and following, for the remaining blocks, SBP,⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405.,⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12.,¹⁴14. Suga T, Okita K, Morita N, Yokota T, Hirabayashi K, Horiuchi M, et al. Dose effect on intramuscular metabolic stress during low-intensity resistance exercise with blood flow restriction. J Appl Physiol. 2010;108(6):1563-7.,¹⁸18. Cook SB, Clark BC, Ploutz-Snyder LL. Effects of exercise load and blood-flow restriction on skeletal muscle function. Med Sci Sports Exerc. 2007;39(10):1708-13.

19. Karabulut M, Cramer JT, Abe T, Sato Y, Bemben MG. Neuromuscular fatigue following low-intensity dynamic exercise with externally applied vascular restriction. J Electromyogr Kinesiol. 2010;20(3):440-7.-²⁰20. Karabulut M, Leal JA, Garcia SD, Cavazos C, Bemben M. Tissue oxygenation, strength and lactate response to different blood flow restrictive pressures. Clin Physiol Funct Imaging. 2014;34(4):263-9. DBP,⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405.,⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12.,²⁵25. Hunt JEA, Stodart C, Ferguson RA. The influence of participant characteristics on the relationship between cuff pressure and level of blood flow restriction. Eur J Appl Physiol. 2016;116(7):1421-32. age,²²22. Drøyvold WB, Midthjell K, Nilsen TI, Holmen J. Change in body mass index and its impact on blood pressure: a prospective population study. Int J Obes (Lond). 2005;29(6):650-5.

23. Joyner MJ, Wallin BG, Charkoudian N. Sex differences and blood pressure regulation in humans. Exp Physiol. 2016;101(3):349-55.-²⁴24. Wei JY. Age and the cardiovascular system. N Engl J Med. 1992;327(24):1735-9. BMI,²²22. Drøyvold WB, Midthjell K, Nilsen TI, Holmen J. Change in body mass index and its impact on blood pressure: a prospective population study. Int J Obes (Lond). 2005;29(6):650-5.,²⁵25. Hunt JEA, Stodart C, Ferguson RA. The influence of participant characteristics on the relationship between cuff pressure and level of blood flow restriction. Eur J Appl Physiol. 2016;116(7):1421-32. and sex²²22. Drøyvold WB, Midthjell K, Nilsen TI, Holmen J. Change in body mass index and its impact on blood pressure: a prospective population study. Int J Obes (Lond). 2005;29(6):650-5.,²³23. Joyner MJ, Wallin BG, Charkoudian N. Sex differences and blood pressure regulation in humans. Exp Physiol. 2016;101(3):349-55. were added, respectively. (Figure 1) While all of the variables were considered in the elaboration of the adjusted model, only the ones with p values < 0.20 in input to model were kept. Changes in Pearson correlation, part correlation coefficient (PCC), r²2. Takarada Y, Takazawa H, Sato Y, Takebayashi S, Tanaka Y, Ishii N. Effects of resistance exercise combined with moderate vascular occlusion on muscular function in humans. J Appl Physiol. 2000;88(6):2097-106., standard error of the estimate (SEE), and F-value were determined for each block. Also in each block, collinearity between variables was assessed based on the variance inflation factor (VIF) and tolerance (T) values with cutoff points of less than 5 and greater than 0.1, respectively.²⁹29. Snee RD. Validation of regression models: methods and examples. Technometrics. 1977;19(4):415-28.

Figure 1
Block hierarchical theoretical model used to develop the equation to predict the blood flow restriction pressure in the lower limbs.

RESULTS

The mean ± standard deviation of the lower limb AOP was 166 ± 18 mmHg. (Table 1) Table 2 describes the Pearson’s correlation coefficient values corresponding to the assessed variables. There were positive relationships between some of the predictor (age, TC, sex and SBP) and the predicted variables. DBP and BMI were not associated with AOP (p > 0.05). TC exhibited the highest correlation coefficient (r = 0.506), which corresponds to a moderate relationship with AOP.

Thumbnail

Table 2
Pearson’s correlation coefficients between predictor and predicted variables (n = 51).

The variables TC, SBP, age and sex were included in the first, second, third and fourth blocks, respectively; TC explained 25.6% of the variation in AOP; TC and SBP explained 29.1%; TC, SBP and age explained 36.1%; and TC, SBP, age and sex explained 39.7%. (Table 3) None of the variables met the criteria for collinearity. As a result, the predictive equation as follows:

Thumbnail

Table 3
Hierarchical linear regression model to predict arterial occlusion pressure in the lower limbs (n= 51).

AOP (mmHg) = 65.290 + 1.110 (TC in cm) + 0.178 (SBP in mmHg) + 1.153 (age in years) – 7.984 (sex, 1 – male; 2 – female).
Where = AOP: arterial occlusion pressure; TC: thigh circumference; and SBP: brachial systolic blood pressure.

DISCUSSION

In this study, an equation was developed to predict the cuff pressure to be used in BFR of the lower limbs based on the arterial occlusion pressure (AOP), based on factors such as thigh circumference,³3. Loenneke JP, Kim D, Fahs CA, Thiebaud RS, Abe T, Larson RD, et al. Effects of exercise with and without different degrees of blood flow restriction on torque and muscle activation. Muscle Nerve. 2015;51(5):713-21.,⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405.,⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12.,²⁶26. Jessee MB, Buckner SL, Dankel SJ, Counts BR, Abe T, Loenneke JP. The influence of cuff width, sex, and race on arterial occlusion: implications for blood flow restriction research. Sports Med. 2016;46(6):913-21.,²⁸28. Crenshaw AG, Hargens AR, Gershuni DH, Rydevik B. Wide tourniquet cuffs more effective at lower inflation pressures. Acta Orthop Scand. 1988;59(4):447-51. brachial systolic blood pressure,⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405.,⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12.,¹⁴14. Suga T, Okita K, Morita N, Yokota T, Hirabayashi K, Horiuchi M, et al. Dose effect on intramuscular metabolic stress during low-intensity resistance exercise with blood flow restriction. J Appl Physiol. 2010;108(6):1563-7.,¹⁸18. Cook SB, Clark BC, Ploutz-Snyder LL. Effects of exercise load and blood-flow restriction on skeletal muscle function. Med Sci Sports Exerc. 2007;39(10):1708-13.

19. Karabulut M, Cramer JT, Abe T, Sato Y, Bemben MG. Neuromuscular fatigue following low-intensity dynamic exercise with externally applied vascular restriction. J Electromyogr Kinesiol. 2010;20(3):440-7.-²⁰20. Karabulut M, Leal JA, Garcia SD, Cavazos C, Bemben M. Tissue oxygenation, strength and lactate response to different blood flow restrictive pressures. Clin Physiol Funct Imaging. 2014;34(4):263-9.,²⁶26. Jessee MB, Buckner SL, Dankel SJ, Counts BR, Abe T, Loenneke JP. The influence of cuff width, sex, and race on arterial occlusion: implications for blood flow restriction research. Sports Med. 2016;46(6):913-21. age,²²22. Drøyvold WB, Midthjell K, Nilsen TI, Holmen J. Change in body mass index and its impact on blood pressure: a prospective population study. Int J Obes (Lond). 2005;29(6):650-5.

23. Joyner MJ, Wallin BG, Charkoudian N. Sex differences and blood pressure regulation in humans. Exp Physiol. 2016;101(3):349-55.-²⁴24. Wei JY. Age and the cardiovascular system. N Engl J Med. 1992;327(24):1735-9. and sex.²²22. Drøyvold WB, Midthjell K, Nilsen TI, Holmen J. Change in body mass index and its impact on blood pressure: a prospective population study. Int J Obes (Lond). 2005;29(6):650-5., ²³23. Joyner MJ, Wallin BG, Charkoudian N. Sex differences and blood pressure regulation in humans. Exp Physiol. 2016;101(3):349-55. Established on the crude hierarchical regression model, the explanatory power of the block that included only TC was 25.6%. When the variables TC, SBP, age and sex were included, the explanatory power (39.7%) and the effect size (r = 0.630) increased. These findings indicate that the final adjusted model exhibits high practical applicability for professionals in this field, and that the pressure used for BFR should be more strongly based on TC rather than on other measures mentioned in the literature.⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405.,⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12.,²⁶26. Jessee MB, Buckner SL, Dankel SJ, Counts BR, Abe T, Loenneke JP. The influence of cuff width, sex, and race on arterial occlusion: implications for blood flow restriction research. Sports Med. 2016;46(6):913-21.

To our knowledge, regression equations to predict the cuff pressure for BFR training in lower limbs were developed in two studies⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405.,²⁵25. Hunt JEA, Stodart C, Ferguson RA. The influence of participant characteristics on the relationship between cuff pressure and level of blood flow restriction. Eur J Appl Physiol. 2016;116(7):1421-32. and one to upper limbs.²⁶26. Jessee MB, Buckner SL, Dankel SJ, Counts BR, Abe T, Loenneke JP. The influence of cuff width, sex, and race on arterial occlusion: implications for blood flow restriction research. Sports Med. 2016;46(6):913-21. Loenneke et al.,⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405. based on a hierarchical model to define the AOP of the lower limbs, SBP, and TC were used. It is worthwhile to observe that DBP was the variable that less influenced their model (β = 0.139; p = 0.131), which agrees with the results of the present study, in which DBP and BMI was excluded from the final adjusted model.

One further point that should be stressed is that the SEE in the blocks of our study was lower compared to that reported by Loenneke et al.,⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405. demonstrating that the external validity of the model elaborated in the present study is larger. On the other hand, cuff size was a factor that might have influenced the SEE, was used an 18-cm wide cuff and we found a SEE below 20.0, as found by Loenneke et al.,⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12. which used a 13.5-cm wide cuff. However, when Loenneke et al.⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405.,⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12. used a 5-cm wide cuff, they found SEE values above 20.0. Cuffs with different width may impact the measurement of the AOP.⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12. Crenshaw et al.²⁸28. Crenshaw AG, Hargens AR, Gershuni DH, Rydevik B. Wide tourniquet cuffs more effective at lower inflation pressures. Acta Orthop Scand. 1988;59(4):447-51. demonstrated that the wider the cuff, the lower the pressure required to occlude circulation.

In the present study, another relevant variables, age and sex, was added, which makes it possible to extrapolate the equation to the populations, because the vascular system might change as a function of them,²³23. Joyner MJ, Wallin BG, Charkoudian N. Sex differences and blood pressure regulation in humans. Exp Physiol. 2016;101(3):349-55.,²⁴24. Wei JY. Age and the cardiovascular system. N Engl J Med. 1992;327(24):1735-9. and not considered by previous research⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405., ²⁵25. Hunt JEA, Stodart C, Ferguson RA. The influence of participant characteristics on the relationship between cuff pressure and level of blood flow restriction. Eur J Appl Physiol. 2016;116(7):1421-32., only sex was inserted by Jesse et al.²⁶26. Jessee MB, Buckner SL, Dankel SJ, Counts BR, Abe T, Loenneke JP. The influence of cuff width, sex, and race on arterial occlusion: implications for blood flow restriction research. Sports Med. 2016;46(6):913-21. In this way, it is observed that the standardized beta values of this study (β = -0.207; p = 0.105) and the study of Jesse et al.²⁶26. Jessee MB, Buckner SL, Dankel SJ, Counts BR, Abe T, Loenneke JP. The influence of cuff width, sex, and race on arterial occlusion: implications for blood flow restriction research. Sports Med. 2016;46(6):913-21. (2016) to cuffs of 10 cm and 12 cm (β = 0.227, p < 0.001; β = 0.246, p < 0.001; respectively) are similar, possibly this occurred due the similarity of the anthropometric characteristics.

In the analysis of the correlation between the independent and the dependent variable, TC exhibited a moderate correlation (r = 0.506; p = 0.001) compared to SBP (r = 0.307; p = 0.028), and DBP (r = 0.224; p = 0.115). These findings corroborate those of Loenneke et al.⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12. (2012a), which indicate that the amount of the fat and muscle surrounding the blood vessels may have a more direct effect on the level of pressure needed to block the venous blood flow and to reduce the arterial blood flow compared to the arterial pressure.

In addition to measuring TC, Loenneke et al.⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12. analyzed the muscle and fat areas in the thigh using computed tomography and found that the explanatory power relative to the dependent variable was greater, and that in the heaviest participants exhibited high values or could not be established because it was beyond the device capacity (300 mmHg), which demonstrates the need to use TC as a parameter. The same AOP value applied to limbs with different circumferences will differ at the vascular level because the amount of tissue that surrounds the vessels influences the pressure that is applied to them.⁷7. Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12.

The presents results show that the sample heterogeneity complies with the principle of data variability relative to the sociodemographic, anthropometric and hemodynamic variables. However, one of the limitations is that the equation was developed exclusively for the lower-body and for the 18-cm wide cuffs. Therefore, further studies ought to be performed with both the upper and lower limbs, and also needed to investigate the reproducibility of this model, along with the one developed by Loenneke et al.,⁶6. Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405. Hunt et al.²⁵25. Hunt JEA, Stodart C, Ferguson RA. The influence of participant characteristics on the relationship between cuff pressure and level of blood flow restriction. Eur J Appl Physiol. 2016;116(7):1421-32. and Jesse et al.,²⁶26. Jessee MB, Buckner SL, Dankel SJ, Counts BR, Abe T, Loenneke JP. The influence of cuff width, sex, and race on arterial occlusion: implications for blood flow restriction research. Sports Med. 2016;46(6):913-21. in different populations.

In the end, this study fills a gap in the available knowledge through the development of a new equation to estimate AOP that includes novel variables. The equation presented here might represent a practical and low-cost option to identify the BFR pressure for professionals who perform training with larger cuffs.

CONCLUSION

In conclusion, the cuff pressure for lower limb BFR training may be selected based on thigh circumference (TC), brachial systolic blood pressure (SBP), age and sex, and TC is the best predictor of arterial occlusion pressure (AOP). BFR is being increasingly used in several exercise modalities and by various population groups, thus, need to use a practical and accessible method to select the cuff pressure for the lower limbs under different circumstances.

ACKNOWLEDGMENTS

No financial assistance was obtained for this study.

REFERENCES

¹
Laurentino GC, Ugrinowitsch C, Roschel H, Aoki MS, Soares AG, Neves Jr M, et al. Strength training with blood flow restriction diminishes myostatin gene expression. Med Sci Sports Exerc. 2012;44(3):406-12.
²
Takarada Y, Takazawa H, Sato Y, Takebayashi S, Tanaka Y, Ishii N. Effects of resistance exercise combined with moderate vascular occlusion on muscular function in humans. J Appl Physiol. 2000;88(6):2097-106.
³
Loenneke JP, Kim D, Fahs CA, Thiebaud RS, Abe T, Larson RD, et al. Effects of exercise with and without different degrees of blood flow restriction on torque and muscle activation. Muscle Nerve. 2015;51(5):713-21.
⁴
Neto GR, Sousa MSC, Costa e Silva GV, Gil ALS, Salles BF, Novaes JS. Acute resistance exercise with blood flow restriction effects on heart rate, double product, oxygen saturation and perceived exertion. Clin Physiol Funct Imaging. 2016;36(1):53-9.
⁵
ahs CA, Rossow LM, Loenneke JP, Thiebaud RS, Kim D, Bemben DA, et al. Effect of different types of lower body resistance training on arterial compliance and calf blood flow. Clin Physiol Funct Imaging. 2012;32(1):45-51.
⁶
Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405.
⁷
Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12.
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Suga T, Okita K, Morita N, Yokota T, Hirabayashi K, Horiuchi M, et al. Dose effect on intramuscular metabolic stress during low-intensity resistance exercise with blood flow restriction. J Appl Physiol. 2010;108(6):1563-7.
¹⁵
Kubota A, Sakuraba K, Koh S, Ogura Y, Tamura Y. Blood flow restriction by low compressive force prevents disuse muscular weakness. J Sci Med Sport. 2011;14(2):95-9.
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¹⁸
Cook SB, Clark BC, Ploutz-Snyder LL. Effects of exercise load and blood-flow restriction on skeletal muscle function. Med Sci Sports Exerc. 2007;39(10):1708-13.
¹⁹
Karabulut M, Cramer JT, Abe T, Sato Y, Bemben MG. Neuromuscular fatigue following low-intensity dynamic exercise with externally applied vascular restriction. J Electromyogr Kinesiol. 2010;20(3):440-7.
²⁰
Karabulut M, Leal JA, Garcia SD, Cavazos C, Bemben M. Tissue oxygenation, strength and lactate response to different blood flow restrictive pressures. Clin Physiol Funct Imaging. 2014;34(4):263-9.
²¹
Neto GR, Sousa MSC, Costa PB, Salles BF, Novaes GS, Novaes JS. Hypotensive effects of resistance exercises with blood flow restriction. J Strength Cond Res. 2015;29(4):1064-70.
²²
Drøyvold WB, Midthjell K, Nilsen TI, Holmen J. Change in body mass index and its impact on blood pressure: a prospective population study. Int J Obes (Lond). 2005;29(6):650-5.
²³
Joyner MJ, Wallin BG, Charkoudian N. Sex differences and blood pressure regulation in humans. Exp Physiol. 2016;101(3):349-55.
²⁴
Wei JY. Age and the cardiovascular system. N Engl J Med. 1992;327(24):1735-9.
²⁵
Hunt JEA, Stodart C, Ferguson RA. The influence of participant characteristics on the relationship between cuff pressure and level of blood flow restriction. Eur J Appl Physiol. 2016;116(7):1421-32.
²⁶
Jessee MB, Buckner SL, Dankel SJ, Counts BR, Abe T, Loenneke JP. The influence of cuff width, sex, and race on arterial occlusion: implications for blood flow restriction research. Sports Med. 2016;46(6):913-21.
²⁷
Faul F, Erdfelder E, Buchner A, Lang AG. Statistical power analyses using G*Power 3.1: tests for correlation and regression analyses. Behav Res Methods. 2009;41(4):1149-60.
²⁸
Crenshaw AG, Hargens AR, Gershuni DH, Rydevik B. Wide tourniquet cuffs more effective at lower inflation pressures. Acta Orthop Scand. 1988;59(4):447-51.
²⁹
Snee RD. Validation of regression models: methods and examples. Technometrics. 1977;19(4):415-28.

Publication Dates

Publication in this collection
11 Nov 2019
Date of issue
Nov-Dec 2019

History

Received
19 Oct 2017
Accepted
10 June 2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Laurentino GC, Ugrinowitsch C, Roschel H, Aoki MS, Soares AG, Neves Jr M, et al. Strength training with blood flow restriction diminishes myostatin gene expression. Med Sci Sports Exerc. 2012;44(3):406-12.

[2] ²
Takarada Y, Takazawa H, Sato Y, Takebayashi S, Tanaka Y, Ishii N. Effects of resistance exercise combined with moderate vascular occlusion on muscular function in humans. J Appl Physiol. 2000;88(6):2097-106.

[3] ³
Loenneke JP, Kim D, Fahs CA, Thiebaud RS, Abe T, Larson RD, et al. Effects of exercise with and without different degrees of blood flow restriction on torque and muscle activation. Muscle Nerve. 2015;51(5):713-21.

[4] ⁴
Neto GR, Sousa MSC, Costa e Silva GV, Gil ALS, Salles BF, Novaes JS. Acute resistance exercise with blood flow restriction effects on heart rate, double product, oxygen saturation and perceived exertion. Clin Physiol Funct Imaging. 2016;36(1):53-9.

[5] ⁵
ahs CA, Rossow LM, Loenneke JP, Thiebaud RS, Kim D, Bemben DA, et al. Effect of different types of lower body resistance training on arterial compliance and calf blood flow. Clin Physiol Funct Imaging. 2012;32(1):45-51.

[6] ⁶
Loenneke JP, Allen KM, Mouser JG, Thiebaud RS, Kim D, Abe T, et al. Blood flow restriction in the upper and lower limbs is predicted by limb circumference and systolic blood pressure. Eur J Appl Physiol. 2015;115(2):397-405.

[7] ⁷
Loenneke JP, Fahs CA, Rossow LM, Sherk VD, Thiebaud RS, Abe T, et al. Effects of cuff width on arterial occlusion: implications for blood flow restricted exercise. Eur J Appl Physiol. 2012;112(8):2903-12.

[8] ⁸
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Variables	Mean ± Standard deviation	Minimum-Maximum
Age (years)	28 ± 7	18 – 47
Body mass (kg)	69.58 ± 14.79	48,40 – 106.00
Height (cm)	169.86 ± 9.59	153.20 – 190.20
BMI (kg/m²)	24.02 ± 4.12	16.54 – 34.45
TC (cm)	58.20 ± 6.46	47.00 – 74.00
SBP (mmHg)	119 ± 9	100 – 146
DBP (mmHg)	74 ± 10	50 – 104
AOP (mmHg)	166 ± 18	144 – 237

Blocks	Variables	Stand. β	p	PCC	r	r²	SEE	Sig. F change	T	VIF
1	TC	0.506	<0.001	0.506	0.506	0.256	16.446	<0.001	1.000	1.000
2	TC	0.458	0.001	0.444	0.540	0.291	16.222	<0.001	0.938	1.067
2	SBP	0.193	0.131	0.187	0.540	0.291	16.222	<0.001	0.938	1.067
3	TC	0.353	0.009	0.319	0.601	0.361	15.568	<0.001	0.817	1.224
	SBP	0.170	0.166	0.164					0.931	1.074
	Age	0.287	0.028	0.264					0.846	1.183
4	TC	0.380	0.005	0.341	0.630	0.397	15.289	<0.001	0.804	1.245
	SBP	0.091	0.482	0.081					0.801	1.249
	Age	0.320	0.015	0.291					0.824	1.213
	Sex	-0.207	0.105	-0.189					0.840	1.190

Brasil

Brasil

PREDICTIVE EQUATION FOR BLOOD FLOW RESTRICTION TRAINING

EQUAÇÃO PREDITIVA PARA O TREINAMENTO DE RESTRIÇÃO DO FLUXO SANGUÍNEO

ECUACIÓN PREDICTIVA PARA EL ENTRENAMIENTO DE RESTRICCIÓN DEL FLUJO SANGUÍNEO

ABSTRACT

Introduction

Objectives

Methods

Results

Conclusion

RESUMO

Introdução

Objetivos

Métodos

Resultados

Conclusão

RESUMEN

Introducción

Objetivos

Métodos

Resultados

Conclusión

INTRODUCTION

METHODS

Subjects

Study design

PROCEDURES

Anthropometric measurements

Hemodynamic measurements

Measurement of the arterial occlusion pressure

Statistical analyses

RESULTS

DISCUSSION

CONCLUSION

ACKNOWLEDGMENTS

REFERENCES

Publication Dates

History