The Intra- and Inter-Rater Reliability of a Hip Rotation Range-of-Motion Measurement Using a Smartphone Application in Academy Football (Soccer) Players

P. Spork; J. O’brien; M. Sepoetro; M. Plachel; T. Stöggl

doi:10.3390/sports9110148

The Intra- and Inter-Rater Reliability of a Hip Rotation Range-of-Motion Measurement Using a Smartphone Application in Academy Football (Soccer) Players

P. Spork
, J. O’brien
, M. Sepoetro
, M. Plachel
, T. Stöggl

Health Sciences

Red Bull Athlete Performance Center
The Australian Centre for Research into Injury in Sport and Its Prevention (ACRISP), Edith Cowan University
Department of Sport and Exercise Science, University of Salzburg

Research output: Contribution to journal › Article › peer-review

Abstract

The clinical assessment of hip rotation range-of-motion (ROM) is important for managing hip and groin injuries in footballers. Previously published reliability studies on hip ROM have employed protocols that are difficult to replicate under everyday clinical conditions. This single trial, intra-and inter-rater reliability study included 41 male academy football (soccer) players, aged 14–15 years, from one European football academy. Passive hip internal rotation (IR) and external rotation (ER) ROM were measured in supine with hip and knee flexed to 90◦ . The ROM was determined using a smartphone application, with the smartphone attached to the lower leg. The tests were performed on two separate occasions, one week apart, by two different physiotherapists and on both sides (left and right hips). Reliability was evaluated using Intra-Class Correlation Coefficients (ICCs) and Minimal Detectable Change (MDC). Hip IR and ER ROM displayed moderate to good intra-rater agreement (ICCs 0.54–0.75), with MDCs ranging from 10.9◦ to 16.4◦ . Inter-rater reliability displayed poor to moderate reliability (ICCs 0.33–0.75), with MDCs ranging from 11.7◦ to 16.5◦ . A hip rotation ROM test using a smartphone application and a protocol closely reflecting everyday clinical conditions displayed moderate to good intra-rater reliability and poor to moderate inter-rater reliability. Due to the high MDCs, the practical applicability of this test procedure is limited and further refinement is necessary.

Original language	English
Journal	Sports
Volume	9
Issue number	11
DOIs	https://doi.org/10.3390/sports9110148
Publication status	Published - 26 Oct 2021

Keywords

Groin
Prevention
Sports

Access to Document

10.3390/sports9110148

https://www.scopus.com/inward/record.uri?eid=2-s2.0-85118384775&doi=10.3390%2fsports9110148&partnerID=40&md5=1f7f62baaaee8c326756685a3b092b32

Cite this

@article{2116d6b4e7bf4a4c9bffcda8421f7c53,

title = "The Intra- and Inter-Rater Reliability of a Hip Rotation Range-of-Motion Measurement Using a Smartphone Application in Academy Football (Soccer) Players",

abstract = "The clinical assessment of hip rotation range-of-motion (ROM) is important for managing hip and groin injuries in footballers. Previously published reliability studies on hip ROM have employed protocols that are difficult to replicate under everyday clinical conditions. This single trial, intra-and inter-rater reliability study included 41 male academy football (soccer) players, aged 14–15 years, from one European football academy. Passive hip internal rotation (IR) and external rotation (ER) ROM were measured in supine with hip and knee flexed to 90◦ . The ROM was determined using a smartphone application, with the smartphone attached to the lower leg. The tests were performed on two separate occasions, one week apart, by two different physiotherapists and on both sides (left and right hips). Reliability was evaluated using Intra-Class Correlation Coefficients (ICCs) and Minimal Detectable Change (MDC). Hip IR and ER ROM displayed moderate to good intra-rater agreement (ICCs 0.54–0.75), with MDCs ranging from 10.9◦ to 16.4◦ . Inter-rater reliability displayed poor to moderate reliability (ICCs 0.33–0.75), with MDCs ranging from 11.7◦ to 16.5◦ . A hip rotation ROM test using a smartphone application and a protocol closely reflecting everyday clinical conditions displayed moderate to good intra-rater reliability and poor to moderate inter-rater reliability. Due to the high MDCs, the practical applicability of this test procedure is limited and further refinement is necessary.",

keywords = "Groin, Prevention, Sports",

author = "P. Spork and J. O{\textquoteright}brien and M. Sepoetro and M. Plachel and T. St{\"o}ggl",

note = "Cited By :2 Export Date: 14 December 2023 Correspondence Address: Spork, P.; Physiotherapy, Urstein S{\"u}d 1, Austria; email: [email protected] References: Werner, J., H{\"a}gglund, M., Ekstrand, J., Wald{\'e}n, M., Hip and groin time-loss injuries decreased slightly but injury burden remained constant in men{\textquoteright}s professional football: The 15-year prospective UEFA Elite Club Injury Study (2019) Br. J. Sports Med, 53, pp. 539-546. , [CrossRef] [PubMed]; Jones, S., Almousa, S., Gibb, A., Allamby, N., Mullen, R., Andersen, T.E., Williams, M., Injury Incidence, Prevalence and Severity in High-Level Male Youth Football: A Systematic Review (2019) Sports Med, 49, pp. 1879-1899. , [CrossRef]; Werner, J., H{\"a}gglund, M., Wald{\'e}n, M., Ekstrand, J., UEFA injury study: A prospective study of hip and groin injuries in professional football over seven consecutive seasons (2009) Br. J. Sports Med, 43, pp. 1036-1040. , [CrossRef] [PubMed]; Tak, I., Glasgow, P., Langhout, R., Weir, A., Kerkhoffs, G., Agricola, R., Hip Range of Motion Is Lower in Professional Soccer Players With Hip and Groin Symptoms or Previous Injuries, Independent of Cam Deformities (2016) Am. J. Sports Med, 44, pp. 682-688. , [CrossRef]; Verrall, G.M., Slavotinek, J.P., Barnes, P.G., Esterman, A., Oakeshott, R.D., Spriggins, A.J., Hip joint range of motion restriction precedes athletic chronic groin injury (2007) J. Sci. Med. Sport, 10, pp. 463-466. , [CrossRef] [PubMed]; Ibrahim, A., Murrell, G.A., Knapman, P., Adductor strain and hip range of movement in male professional soccer players (2007) J. Orthop. Surg, 15, pp. 46-49. , [CrossRef] [PubMed]; Mosler, A.B., Agricola, R., Weir, A., Holmich, P., Crossley, K.M., Which factors differentiate athletes with hip/groin pain from those without? A systematic review with meta-analysis (2015) Br. J. Sports Med, 49, p. 810. , [CrossRef] [PubMed]; Tak, I., Engelaar, L., Gouttebarge, V., Barendrecht, M., Van den Heuvel, S., Kerkhoffs, G., Langhout, R., Weir, A., Is lower hip range of motion a risk factor for groin pain in athletes? A systematic review with clinical applications (2017) Br. J. Sports Med, 51, pp. 1611-1621. , [CrossRef]; Gradoz, M.C., Bauer, L.E., Grindstaff, T.L., Bagwell, J.J., Reliability of hip rotation range of motion in supine and seated positions (2018) J. Sport Rehabil, 27. , [CrossRef]; Grazette, N., McAllister, S., Ong, C.W., Sunderland, C., Nevill, M.E., Morris, J.G., Reliability of a musculoskeletal profiling test battery in elite academy soccer players (2020) PLoS ONE, 15, p. e0236341. , [CrossRef] [PubMed]; Poulsen, E., Christensen, H.W., Penny, J., Overgaard, S., Vach, W., Hartvigsen, J., Reproducibility of range of motion and muscle strength measurements in patients with hip osteoarthritis—An inter-rater study (2012) BMC Musculoskelet. Disord, 13, p. 242. , [CrossRef]; Nussbaumer, S., Leunig, M., Glatthorn, J.F., Stauffacher, S., Gerber, H., Maffiuletti, N.A., Validity and test-retest reliability of manual goniometers for measuring passive hip range of motion in femoroacetabular impingement patients (2010) BMC Musculoskelet. Disord, 11, p. 194. , [CrossRef] [PubMed]; Charlton, P.C., Mentiplay, B.F., Pua, Y.H., Clark, R.A., Reliability and concurrent validity of a Smartphone, bubble inclinometer and motion analysis system for measurement of hip joint range of motion (2015) J. Sci. Med. Sport, 18, pp. 262-267. , [CrossRef]; Krause, D.A., Hollman, J.H., Krych, A.J., Kalisvaart, M.M., Levy, B.A., Reliability of hip internal rotation range of motion measurement using a digital inclinometer (2015) Knee Surg. Sports Traumatol. Arthrosc, 23, pp. 2562-2567. , [CrossRef] [PubMed]; Valevicius, A.M., Jun, P.Y., Hebert, J.S., Vette, A.H., Use of optical motion capture for the analysis of normative upper body kinematics during functional upper limb tasks: A systematic review (2018) J. Electromyogr. Kinesiol, 40, pp. 1-15. , [CrossRef]; Tranquilli, C., Bernetti, A., Picerno, P., Ambulatory joint mobility and muscle strength assessment during rehabilitation using a single wearable inertial sensor (2013) Med. Dello Sport, 66, pp. 583-597; Hejdysz, K., Go{\'s}li{\'n}ska, J., WarfDczak, A., DudzjDska, J., Adamczyk, E., Sip, P., Go{\'s}li{\'n}ski, J., LisjDski, P., Manual Therapy Versus Closed Kinematic Exercise“ The Influence on the Range of Movement in Patients with Knee Osteoarthritis: A Pilot Study (2020) Appl. Sci, 10, p. 8605. , [CrossRef]; Bolam, S.M., Batinica, B., Yeung, T.C., Weaver, S., Cantamessa, A., Vanderboor, T.C., Yeung, S., Besier, T.F., Remote Patient Monitoring with Wearable Sensors Following Knee Arthroplasty (2021) Sensors, 21, p. 5143. , [CrossRef] [PubMed]; Sacco, G., Turpin, J.M., Marteu, A., Sakarovitch, C., Teboul, B., Boscher, L., Brocker, P., Guerin, O., Inertial sensors as measurement tools of elbow range of motion in gerontology (2015) Clin. Interv. Aging, 10, pp. 491-497. , [CrossRef] [PubMed]; Gardiner, P.V., Small, D., Mu{\~n}oz-Esquivel, K., Condell, J., Cuesta-Vargas, A., Williams, J., Machado, P.M., Garrido-Castro, J.L., Validity and reliability of a sensor-based electronic spinal mobility index for axial spondyloarthritis (2020) Rheumatology, 59, pp. 3415-3423. , [CrossRef] [PubMed]; Carmona-P{\'e}rez, C., Garrido-Castro, J.L., Torres Vidal, F., Alcaraz-Clariana, S., Garc{\'i}a-Luque, L., Alburquerque-Send{\'i}n, F., Rodrigues-de-Souza, D.P., Concurrent Validity and Reliability of an Inertial Measurement Unit for the Assessment of Craniocervi-cal Range of Motion in Subjects with Cerebral Palsy (2020) Diagnostics, 10, p. 80. , [CrossRef] [PubMed]; Luedtke, K., Schoettker-K{\"o}niger, T., Hall, T., Reimer, C., Grassold, M., Hasselhoff-Styhler, P., Neulinger, C., Sch{\"a}fer, A., Concurrent validity and reliability of measuring range of motion during the cervical flexion rotation test with a novel digital goniometer (2020) BMC Musculoskelet. Disord, 21, p. 535. , [CrossRef]; Keogh, J.W.L., Cox, A., Anderson, S., Liew, B., Olsen, A., Schram, B., Furness, J., Reliability and validity of clinically accessible smartphone applications to measure joint range of motion: A systematic review (2019) PLoS ONE, 14, p. e0215806. , [CrossRef] [PubMed]; Milani, P., Coccetta, C.A., Rabini, A., Sciarra, T., Massazza, G., Ferriero, G., Mobile smartphone applications for body position measurement in rehabilitation: A review of goniometric tools (2014) Phys. Med. Rehabil, 6, pp. 1038-1043. , [CrossRef] [PubMed]; Longoni, L., Brunati, R., Sale, P., Casale, R., Ronconi, G., Ferriero, G., Smartphone applications validated for joint angle measurement: A systematic review (2019) Int. J. Rehabil. Res, 42, pp. 11-19. , [CrossRef] [PubMed]; St-Pierre, M.O., Sobczak, S., Fontaine, N., Saad{\'e}, N., Boivin, K., Quantification and Reliability of Hip Internal Rotation and the FADIR Test in Supine Position Using a Smartphone Application in an Asymptomatic Population (2020) J. Manip. Physiol. Ther, 43, pp. 620-626. , [CrossRef] [PubMed]; Usher-Smith, J.A., Sharp, S.J., Griffin, S.J., The spectrum effect in tests for risk prediction, screening, and diagnosis (2016) Br. Med. J, 353, p. i3139. , [CrossRef] [PubMed]; Ganokroj, P., Sompornpanich, N., Kerdsomnuek, P., Vanadurongwan, B., Lertwanich, P., Validity and reliability of smartphone applications for measurement of hip rotation, compared with three-dimensional motion analysis (2021) BMC Musculoskelet. Disord, 22, p. 166. , [CrossRef]; Hodgson, L., Hignett, T., Edwards, K., Normative adductor squeeze tests scores in rugby (2015) Phys. Ther. Sport, 16, pp. 93-97. , [CrossRef]; O{\textquoteright}Brien, J., Santner, E., Finch, C.F., The inter-tester reliability of the squeeze and bent-knee-fall-out tests in elite academy football players (2018) Phys. Ther. Sport, 34, pp. 8-13. , [CrossRef]; Walter, S.D., Eliasziw, M., Donner, A., Sample size and optimal designs for reliability studies (1998) Stat. Med, 17, pp. 101-110. , [CrossRef]; Weir, J.P., Quantifying test-retest reliability using the intraclass correlation coefficient and the SEM (2005) J. Strength Cond. Res, 19, pp. 231-240. , [CrossRef]; Koo, T.K., Li, M.Y., A guideline of selecting and reporting intraclass correlation coefficients for reliability research (2016) J. Chiro. Med, 15, pp. 155-163. , [CrossRef] [PubMed]; Schober, P., Boer, C., Schwarte, L.A., Correlation Coefficients: Appropriate Use and Interpretation (2018) Anesth. Analg, 126, pp. 1763-1768. , [CrossRef]; Est{\'e}banez-de-Miguel, E., Fort{\'u}n-Agud, M., Jimenez-Del-Barrio, S., Caudevilla-Polo, S., Bueno-Gracia, E., Tric{\'a}s-Moreno, J.M., Comparison of high, medium and low mobilization forces for increasing range of motion in patients with hip osteoarthritis: A randomized controlled trial (2018) Musculoskelet. Sci. Pract, 36, pp. 81-86. , [CrossRef] [PubMed]; Walsh, R., Kinsella, S., The effects of caudal mobilisation with movement (MWM) and caudal self-mobilisation with movement (SMWM) in relation to restricted internal rotation in the hip: A randomised control pilot study (2016) Man. Ther, 22, pp. 9-15. , [CrossRef] [PubMed]; Fourchet, F., Materne, O., Horobeanu, C., Hudacek, T., Buchheit, M., Reliability of a novel procedure to monitor the flexibility of lower limb muscle groups in highly-trained adolescent athletes (2013) Phys. Ther. Sport, 14, pp. 28-34. , [CrossRef] [PubMed]; Brodie, M.A., Walmsley, A., Page, W., The static accuracy and calibration of inertial measurement units for 3D orientation (2008) Comput. Methods Biomech. Biomed. Eng, 11, pp. 641-648. , [CrossRef]; Mourcou, Q., Fleury, A., Franco, C., Klopcic, F., Vuillerme, N., Performance Evaluation of Smartphone Inertial Sensors Measurement for Range of Motion (2015) Sensors, 15, pp. 23168-23187. , [CrossRef] [PubMed]",

year = "2021",

month = oct,

day = "26",

doi = "10.3390/sports9110148",

language = "English",

volume = "9",

journal = "Sports",

issn = "2075-4663",

publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",

number = "11",

}

TY - JOUR

T1 - The Intra- and Inter-Rater Reliability of a Hip Rotation Range-of-Motion Measurement Using a Smartphone Application in Academy Football (Soccer) Players

AU - Spork, P.

AU - O’brien, J.

AU - Sepoetro, M.

AU - Plachel, M.

AU - Stöggl, T.

N1 - Cited By :2 Export Date: 14 December 2023 Correspondence Address: Spork, P.; Physiotherapy, Urstein Süd 1, Austria; email: [email protected] References: Werner, J., Hägglund, M., Ekstrand, J., Waldén, M., Hip and groin time-loss injuries decreased slightly but injury burden remained constant in men’s professional football: The 15-year prospective UEFA Elite Club Injury Study (2019) Br. J. Sports Med, 53, pp. 539-546. , [CrossRef] [PubMed]; Jones, S., Almousa, S., Gibb, A., Allamby, N., Mullen, R., Andersen, T.E., Williams, M., Injury Incidence, Prevalence and Severity in High-Level Male Youth Football: A Systematic Review (2019) Sports Med, 49, pp. 1879-1899. , [CrossRef]; Werner, J., Hägglund, M., Waldén, M., Ekstrand, J., UEFA injury study: A prospective study of hip and groin injuries in professional football over seven consecutive seasons (2009) Br. J. Sports Med, 43, pp. 1036-1040. , [CrossRef] [PubMed]; Tak, I., Glasgow, P., Langhout, R., Weir, A., Kerkhoffs, G., Agricola, R., Hip Range of Motion Is Lower in Professional Soccer Players With Hip and Groin Symptoms or Previous Injuries, Independent of Cam Deformities (2016) Am. J. Sports Med, 44, pp. 682-688. , [CrossRef]; Verrall, G.M., Slavotinek, J.P., Barnes, P.G., Esterman, A., Oakeshott, R.D., Spriggins, A.J., Hip joint range of motion restriction precedes athletic chronic groin injury (2007) J. Sci. Med. Sport, 10, pp. 463-466. , [CrossRef] [PubMed]; Ibrahim, A., Murrell, G.A., Knapman, P., Adductor strain and hip range of movement in male professional soccer players (2007) J. Orthop. Surg, 15, pp. 46-49. , [CrossRef] [PubMed]; Mosler, A.B., Agricola, R., Weir, A., Holmich, P., Crossley, K.M., Which factors differentiate athletes with hip/groin pain from those without? A systematic review with meta-analysis (2015) Br. J. Sports Med, 49, p. 810. , [CrossRef] [PubMed]; Tak, I., Engelaar, L., Gouttebarge, V., Barendrecht, M., Van den Heuvel, S., Kerkhoffs, G., Langhout, R., Weir, A., Is lower hip range of motion a risk factor for groin pain in athletes? A systematic review with clinical applications (2017) Br. J. Sports Med, 51, pp. 1611-1621. , [CrossRef]; Gradoz, M.C., Bauer, L.E., Grindstaff, T.L., Bagwell, J.J., Reliability of hip rotation range of motion in supine and seated positions (2018) J. Sport Rehabil, 27. , [CrossRef]; Grazette, N., McAllister, S., Ong, C.W., Sunderland, C., Nevill, M.E., Morris, J.G., Reliability of a musculoskeletal profiling test battery in elite academy soccer players (2020) PLoS ONE, 15, p. e0236341. , [CrossRef] [PubMed]; Poulsen, E., Christensen, H.W., Penny, J., Overgaard, S., Vach, W., Hartvigsen, J., Reproducibility of range of motion and muscle strength measurements in patients with hip osteoarthritis—An inter-rater study (2012) BMC Musculoskelet. Disord, 13, p. 242. , [CrossRef]; Nussbaumer, S., Leunig, M., Glatthorn, J.F., Stauffacher, S., Gerber, H., Maffiuletti, N.A., Validity and test-retest reliability of manual goniometers for measuring passive hip range of motion in femoroacetabular impingement patients (2010) BMC Musculoskelet. Disord, 11, p. 194. , [CrossRef] [PubMed]; Charlton, P.C., Mentiplay, B.F., Pua, Y.H., Clark, R.A., Reliability and concurrent validity of a Smartphone, bubble inclinometer and motion analysis system for measurement of hip joint range of motion (2015) J. Sci. Med. Sport, 18, pp. 262-267. , [CrossRef]; Krause, D.A., Hollman, J.H., Krych, A.J., Kalisvaart, M.M., Levy, B.A., Reliability of hip internal rotation range of motion measurement using a digital inclinometer (2015) Knee Surg. Sports Traumatol. Arthrosc, 23, pp. 2562-2567. , [CrossRef] [PubMed]; Valevicius, A.M., Jun, P.Y., Hebert, J.S., Vette, A.H., Use of optical motion capture for the analysis of normative upper body kinematics during functional upper limb tasks: A systematic review (2018) J. Electromyogr. Kinesiol, 40, pp. 1-15. , [CrossRef]; Tranquilli, C., Bernetti, A., Picerno, P., Ambulatory joint mobility and muscle strength assessment during rehabilitation using a single wearable inertial sensor (2013) Med. Dello Sport, 66, pp. 583-597; Hejdysz, K., Goślińska, J., WarfDczak, A., DudzjDska, J., Adamczyk, E., Sip, P., Gośliński, J., LisjDski, P., Manual Therapy Versus Closed Kinematic Exercise“ The Influence on the Range of Movement in Patients with Knee Osteoarthritis: A Pilot Study (2020) Appl. Sci, 10, p. 8605. , [CrossRef]; Bolam, S.M., Batinica, B., Yeung, T.C., Weaver, S., Cantamessa, A., Vanderboor, T.C., Yeung, S., Besier, T.F., Remote Patient Monitoring with Wearable Sensors Following Knee Arthroplasty (2021) Sensors, 21, p. 5143. , [CrossRef] [PubMed]; Sacco, G., Turpin, J.M., Marteu, A., Sakarovitch, C., Teboul, B., Boscher, L., Brocker, P., Guerin, O., Inertial sensors as measurement tools of elbow range of motion in gerontology (2015) Clin. Interv. Aging, 10, pp. 491-497. , [CrossRef] [PubMed]; Gardiner, P.V., Small, D., Muñoz-Esquivel, K., Condell, J., Cuesta-Vargas, A., Williams, J., Machado, P.M., Garrido-Castro, J.L., Validity and reliability of a sensor-based electronic spinal mobility index for axial spondyloarthritis (2020) Rheumatology, 59, pp. 3415-3423. , [CrossRef] [PubMed]; Carmona-Pérez, C., Garrido-Castro, J.L., Torres Vidal, F., Alcaraz-Clariana, S., García-Luque, L., Alburquerque-Sendín, F., Rodrigues-de-Souza, D.P., Concurrent Validity and Reliability of an Inertial Measurement Unit for the Assessment of Craniocervi-cal Range of Motion in Subjects with Cerebral Palsy (2020) Diagnostics, 10, p. 80. , [CrossRef] [PubMed]; Luedtke, K., Schoettker-Königer, T., Hall, T., Reimer, C., Grassold, M., Hasselhoff-Styhler, P., Neulinger, C., Schäfer, A., Concurrent validity and reliability of measuring range of motion during the cervical flexion rotation test with a novel digital goniometer (2020) BMC Musculoskelet. Disord, 21, p. 535. , [CrossRef]; Keogh, J.W.L., Cox, A., Anderson, S., Liew, B., Olsen, A., Schram, B., Furness, J., Reliability and validity of clinically accessible smartphone applications to measure joint range of motion: A systematic review (2019) PLoS ONE, 14, p. e0215806. , [CrossRef] [PubMed]; Milani, P., Coccetta, C.A., Rabini, A., Sciarra, T., Massazza, G., Ferriero, G., Mobile smartphone applications for body position measurement in rehabilitation: A review of goniometric tools (2014) Phys. Med. Rehabil, 6, pp. 1038-1043. , [CrossRef] [PubMed]; Longoni, L., Brunati, R., Sale, P., Casale, R., Ronconi, G., Ferriero, G., Smartphone applications validated for joint angle measurement: A systematic review (2019) Int. J. Rehabil. Res, 42, pp. 11-19. , [CrossRef] [PubMed]; St-Pierre, M.O., Sobczak, S., Fontaine, N., Saadé, N., Boivin, K., Quantification and Reliability of Hip Internal Rotation and the FADIR Test in Supine Position Using a Smartphone Application in an Asymptomatic Population (2020) J. Manip. Physiol. Ther, 43, pp. 620-626. , [CrossRef] [PubMed]; Usher-Smith, J.A., Sharp, S.J., Griffin, S.J., The spectrum effect in tests for risk prediction, screening, and diagnosis (2016) Br. Med. J, 353, p. i3139. , [CrossRef] [PubMed]; Ganokroj, P., Sompornpanich, N., Kerdsomnuek, P., Vanadurongwan, B., Lertwanich, P., Validity and reliability of smartphone applications for measurement of hip rotation, compared with three-dimensional motion analysis (2021) BMC Musculoskelet. Disord, 22, p. 166. , [CrossRef]; Hodgson, L., Hignett, T., Edwards, K., Normative adductor squeeze tests scores in rugby (2015) Phys. Ther. Sport, 16, pp. 93-97. , [CrossRef]; O’Brien, J., Santner, E., Finch, C.F., The inter-tester reliability of the squeeze and bent-knee-fall-out tests in elite academy football players (2018) Phys. Ther. Sport, 34, pp. 8-13. , [CrossRef]; Walter, S.D., Eliasziw, M., Donner, A., Sample size and optimal designs for reliability studies (1998) Stat. Med, 17, pp. 101-110. , [CrossRef]; Weir, J.P., Quantifying test-retest reliability using the intraclass correlation coefficient and the SEM (2005) J. Strength Cond. Res, 19, pp. 231-240. , [CrossRef]; Koo, T.K., Li, M.Y., A guideline of selecting and reporting intraclass correlation coefficients for reliability research (2016) J. Chiro. Med, 15, pp. 155-163. , [CrossRef] [PubMed]; Schober, P., Boer, C., Schwarte, L.A., Correlation Coefficients: Appropriate Use and Interpretation (2018) Anesth. Analg, 126, pp. 1763-1768. , [CrossRef]; Estébanez-de-Miguel, E., Fortún-Agud, M., Jimenez-Del-Barrio, S., Caudevilla-Polo, S., Bueno-Gracia, E., Tricás-Moreno, J.M., Comparison of high, medium and low mobilization forces for increasing range of motion in patients with hip osteoarthritis: A randomized controlled trial (2018) Musculoskelet. Sci. Pract, 36, pp. 81-86. , [CrossRef] [PubMed]; Walsh, R., Kinsella, S., The effects of caudal mobilisation with movement (MWM) and caudal self-mobilisation with movement (SMWM) in relation to restricted internal rotation in the hip: A randomised control pilot study (2016) Man. Ther, 22, pp. 9-15. , [CrossRef] [PubMed]; Fourchet, F., Materne, O., Horobeanu, C., Hudacek, T., Buchheit, M., Reliability of a novel procedure to monitor the flexibility of lower limb muscle groups in highly-trained adolescent athletes (2013) Phys. Ther. Sport, 14, pp. 28-34. , [CrossRef] [PubMed]; Brodie, M.A., Walmsley, A., Page, W., The static accuracy and calibration of inertial measurement units for 3D orientation (2008) Comput. Methods Biomech. Biomed. Eng, 11, pp. 641-648. , [CrossRef]; Mourcou, Q., Fleury, A., Franco, C., Klopcic, F., Vuillerme, N., Performance Evaluation of Smartphone Inertial Sensors Measurement for Range of Motion (2015) Sensors, 15, pp. 23168-23187. , [CrossRef] [PubMed]

PY - 2021/10/26

Y1 - 2021/10/26

N2 - The clinical assessment of hip rotation range-of-motion (ROM) is important for managing hip and groin injuries in footballers. Previously published reliability studies on hip ROM have employed protocols that are difficult to replicate under everyday clinical conditions. This single trial, intra-and inter-rater reliability study included 41 male academy football (soccer) players, aged 14–15 years, from one European football academy. Passive hip internal rotation (IR) and external rotation (ER) ROM were measured in supine with hip and knee flexed to 90◦ . The ROM was determined using a smartphone application, with the smartphone attached to the lower leg. The tests were performed on two separate occasions, one week apart, by two different physiotherapists and on both sides (left and right hips). Reliability was evaluated using Intra-Class Correlation Coefficients (ICCs) and Minimal Detectable Change (MDC). Hip IR and ER ROM displayed moderate to good intra-rater agreement (ICCs 0.54–0.75), with MDCs ranging from 10.9◦ to 16.4◦ . Inter-rater reliability displayed poor to moderate reliability (ICCs 0.33–0.75), with MDCs ranging from 11.7◦ to 16.5◦ . A hip rotation ROM test using a smartphone application and a protocol closely reflecting everyday clinical conditions displayed moderate to good intra-rater reliability and poor to moderate inter-rater reliability. Due to the high MDCs, the practical applicability of this test procedure is limited and further refinement is necessary.

AB - The clinical assessment of hip rotation range-of-motion (ROM) is important for managing hip and groin injuries in footballers. Previously published reliability studies on hip ROM have employed protocols that are difficult to replicate under everyday clinical conditions. This single trial, intra-and inter-rater reliability study included 41 male academy football (soccer) players, aged 14–15 years, from one European football academy. Passive hip internal rotation (IR) and external rotation (ER) ROM were measured in supine with hip and knee flexed to 90◦ . The ROM was determined using a smartphone application, with the smartphone attached to the lower leg. The tests were performed on two separate occasions, one week apart, by two different physiotherapists and on both sides (left and right hips). Reliability was evaluated using Intra-Class Correlation Coefficients (ICCs) and Minimal Detectable Change (MDC). Hip IR and ER ROM displayed moderate to good intra-rater agreement (ICCs 0.54–0.75), with MDCs ranging from 10.9◦ to 16.4◦ . Inter-rater reliability displayed poor to moderate reliability (ICCs 0.33–0.75), with MDCs ranging from 11.7◦ to 16.5◦ . A hip rotation ROM test using a smartphone application and a protocol closely reflecting everyday clinical conditions displayed moderate to good intra-rater reliability and poor to moderate inter-rater reliability. Due to the high MDCs, the practical applicability of this test procedure is limited and further refinement is necessary.

KW - Groin

KW - Prevention

KW - Sports

UR - https://www.mendeley.com/catalogue/9da2b069-3038-34f5-9a1b-37b2b5a33eba/

U2 - 10.3390/sports9110148

DO - 10.3390/sports9110148

M3 - Article

C2 - 34822348

SN - 2075-4663

VL - 9

JO - Sports

JF - Sports

IS - 11

ER -

The Intra- and Inter-Rater Reliability of a Hip Rotation Range-of-Motion Measurement Using a Smartphone Application in Academy Football (Soccer) Players

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