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Abstract

The extensive use of wearable sensors in sport medicine, exercise medicine, and health has increased the interest in their study. That is why it is necessary to test these technologies’ efficiency, effectiveness, agreement, and reliability in different settings. Consequently, the purpose of this article was to analyze the magnetic, angular rate, and gravity (MARG) sensor’s test-retest agreement and reliability when assessing multiple body segments’ external loads during off-road running. A total of 18 off-road runners (38.78 ± 10.38 years, 73.24 ± 12.6 kg, 172.17 ± 9.48 cm) ran two laps (1st and 2nd Lap) of a 12 km circuit wearing six MARG sensors. The sensors were attached to six different body segments: left (MP_Left) and right (MP_Right) malleolus peroneus, left (VL_Left) and right (VL_Right) vastus lateralis, lumbar (L₁-L₃), and thorax (T₂-T₄) using a special neoprene suit. After a principal component analysis (PCA) was performed, the total data set variance of all body segments was represented by 44.08%–70.64% for the 1st PCA factor considering two variables, Player Load_RT and Impacts, on L₁-L₃, respectively. These two variables were chosen among three total accelerometry-based external load indicators (ABELIs) to perform the agreement and reliability tests due to their relevance based on PCAs for each body segment. There were no significant differences between laps in the Player Load_RT or Impacts (p > 0.05, trivial). The intraclass correlation and lineal correlation showed a substantial to almost perfect over-time test consistency assessed via reliability in both Player Load_RT and Impacts. Bias and t-test assessments showed good agreement between Laps. It can be concluded that MARGs sensors offer significant test re-test reliability and good agreement when assessing off-road kinematics in the six different body segments.

Keywords

Technology inertial measurement devices external load physical demands endurance

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References

Hoffman

Wegelin

. The western states 100-mile endurance run: participation and performance trends. Med Sci Sports Exerc 2009; 41: 2191–2198.

Rojas-Valverde

. Brief historical review of distance and ultradistance runnig in Costa Rica and the world. Viref:revista de Educación Física 2019; 8: 1–19.

Easthope

Hausswirth

Louis

, et al. Effects of a trail running competition on muscular performance and efficiency in well-trained young and master athletes. Eur J Appl Physiol 2010; 110: 1107–1116.

Rojas-Valverde

Sánchez-Ureña

Pino-Ortega

, et al. External workload indicators of muscle and kidney mechanical injury in endurance trail running. Int J Environ Res Public Health 2019; 16: 3909.

Costa

RJS

Crockford

Moore

, et al. Heat acclimation responses of an ultra-endurance running group preparing for hot desert-based competition. Eur J Sport Sci 2014; 14(Suppl 1): S131–S141.

Hoffman

Ingwerson

Rogers

, et al. Increasing creatine kinase concentrations at the 161-km western states endurance run. Wilderness Environ Med 2012; 23: 56–60.

Cardinale

Varley

. Wearable training-monitoring technology: applications, challenges, and opportunities. Int J Sports Physiol Perform 2017; 12: S2–S55.

Impellizzeri

Marcora

Coutts

. Internal and external training load: 15 years on. Int J Sports Physiol Perform 2019; 14: 270–273.

Madgwick

SOH

Harrison

AJL

Vaidyanathan

. Estimation of IMU and MARG orientation using a gradient descent algorithm. IEEE Int Conf Rehabil Robot 2011; 2011: 5975346.

10.

Gómez-Carmona

Bastida-Castillo

González-Custodio

, et al. Using an inertial device (WIMU PRO^TM) to quantify neuromuscular load in running: reliability, convergent validity and influence of type of surface and device location. J Strength Cond Res 2020; 34: 365–373.

11.

Pino-Ortega

García-Rubio

Ibáñez

. Validity and reliability of the WIMU inertial device for the assessment of the vertical jump. PeerJ 2018; 6: e4709.

12.

Seshadri

Voos

, et al. Wearable sensors for monitoring the internal and external workload of the athlete. NPJ Digit Med 2019; 2: 71.

13.

de Dionisio

Gómez-Carmon

Bastida-Castillo

, et al. Slope influence on the trail runner’s physical load: a case study. Rev int med cienc act fís deporte 2020; In press.

14.

Gómez-Carmona

Bastida-Castillo

García-Rubio

, et al. Static and dynamic reliability of WIMU PROTM accelerometers according to anatomical placement. Proc IMechE, Part P: J Sports Engineering Technology 2019; 233: 238–248.

15.

Strohrmann

Harms

Kappeler-Setz

, et al. Monitoring kinematic changes with fatigue in running using body-worn sensors. IEEE Trans Inf Technol Biomed 2012; 16: 983–990.

16.

Hernández-Belmonte

Bastida-Castillo

Gomez-Carmona

, et al. Validity and reliability of an inertial device (WIMU PRO^TM) to quantify physical activity level through steps measurement. J Sports Med Phys Fitness 2018; 59: 587–592.

17.

Gómez-Carmona

Pino-Ortega

Sánchez-Ureña

, et al. Accelerometry-based external load indicators in sport: too many options, same practical outcome? Int J Environ Res Public Health 2019; 16: 5101.

18.

Rico-González

Los Arcos

Rojas-Valverde

, et al. A survey to assess the quality of the data obtained by radio-frequency technologies and microelectromechanical systems to measure external workload and collective behavior variables in team sports. Sensors 2020; 20: 2271.

19.

Oliva-Lozano

Martín-Fuentes

Muyor

. Validity and reliability of an inertial device for measuring dynamic weight-bearing ankle dorsiflexion. Sensors 2020; 20: 399.

20.

Fong

DT-P

Chan

Y-Y

. The use of wearable inertial motion sensors in human lower limb biomechanics studies: a systematic review. Sensors 2010; 10: 11556–11565.

21.

Riley

Paolini

Della Croce

, et al. A kinematic and kinetic comparison of overground and treadmill walking in healthy subjects. Gait Posture 2007; 26: 17–24.

22.

Barrett

Midgley

Lovell

. PlayerLoad^TM: reliability, convergent validity, and influence of unit position during treadmill running. Int J Sports Physiol Perform 2014; 9: 945–952.

23.

Parshad

McGregor

Busa

, et al. A statistical approach to the use of control entropy identifies differences in constraints of gait in highly trained versus untrained runners. Math Biosci Eng 2012; 9: 123–145.

24.

Silva

Duarte

Esteves

, et al. Application of entropy measures to analysis of performance in team sports. Int J Perform Anal Sport 2016; 16: 753–768.

25.

Tabachnick

Fidell

. Using multivariate statistics. 6th ed. Boston, MA: Pearson Education, 2007.

26.

Hair

Anderson

Tatham

, et al. Multivariate data analysis (4th ed.): with readings. Englewood Cliffs, NJ: Prentice-Hall, Inc., 1995.

27.

Kaiser

. The application of electronic computers to factor analysis. Educ Psychol Meas 1960; 20: 141–151.

28.

Kim

DJ-O

Mueller

. Introduction to factor analysis: what it is and how to do it. 1 ed. Beverly Hills, CA: SAGE Publications Inc, 1978.

29.

Liu

C-W

Lin

K-H

Kuo

Y-M

. Application of factor analysis in the assessment of groundwater quality in a blackfoot disease area in Taiwan. Sci Total Environ 2003; 313: 77–89.

30.

Kramer

Feinstein

. Clinical biostatistics. LIV. The biostatistics of concordance. Clin Pharmacol Ther 1981; 29: 111–123.

31.

Cohen

. Statistical power analysis for the behavioral sciences. 2nd ed. Hillsdale, NJ: L. Erlbaum Associates, 1988.

32.

Hopkins

Marshall

Batterham

, et al. Progressive statistics for studies in sports medicine and exercise science. Med Sci Sports Exerc 2009; 41: 3–13.

33.

Kottner

Streiner

. The difference between reliability and agreement. J Clin Epidemiol 2011; 64: 701–702.

34.

Zaki

Bulgiba

Ismail

, et al. Statistical methods used to test for agreement of medical instruments measuring continuous variables in method comparison studies: a systematic review. PLoS One 2012; 7: e37908.

35.

Minetti

Moia

Roi

, et al. Energy cost of walking and running at extreme uphill and downhill slopes. J Appl Physiol 2002; 93: 1039–1046.

36.

Vernillo

Giandolini

Edwards

, et al. Biomechanics and physiology of uphill and downhill running. Sports Med 2017; 47: 615–629.

37.

Giandolini

Horvais

Rossi

, et al. Effects of the foot strike pattern on muscle activity and neuromuscular fatigue in downhill trail running. Scand J Med Sci Sports 2017; 27: 809–819.

38.

Provot

Chiementin

Oudin

, et al. Validation of a high sampling rate inertial measurement unit for acceleration during running. Sensors 2017; 17: 1958.

39.

Ahamed

Kobsar

Benson

, et al. Using wearable sensors to classify subject-specific running biomechanical gait patterns based on changes in environmental weather conditions. PLoS One; 13: e0203839.

Agreement and reliability of magnetic,angular rate,and gravity (MARG) sensors to assess multiple body segment’s external loads during off-road running

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