Department of Physical Education and Sports, Faculty of Sport Sciences, University of GranadaGranada, Spain
Exercise and Rehabilitation Sciences Laboratory, School of Physical Therapy, Faculty of Rehabilitation Sciences, Universidad Andres BelloSantiago, Chile
Department of Nursing, Physiotherapy and Occupational Therapy, Faculty of Nursing, Group of Preventive Activities in the University Health Sciences Setting, University of Castilla-La Mancha (Universidad de Castilla-La Mancha/UCLM)Albacete, Spain
Exercise and Rehabilitation Sciences Laboratory, School of Physical Therapy, Faculty of Rehabilitation Sciences, Universidad Andres BelloSantiago, Chile
Department of Physical Education and Sports, Faculty of Sport Sciences, University of GranadaGranada, Spain
Exercise and Rehabilitation Sciences Laboratory, School of Physical Therapy, Faculty of Rehabilitation Sciences, Universidad Andres BelloSantiago, Chile
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Alvares T.S., Oliveira G.V. de, Soares R., Murias J.M., Near-infrared spectroscopy-derived total hemoglobin as an indicator of changes in muscle blood flow during exerciseinduced hyperemia, Journal of Sports Sciences, 2020, 38, 751–758.Search in Google Scholar
Bailey C.A., Yoon S.H., Côté J.N., Relative variability in muscle activation amplitude, muscle oxygenation and muscle thickness: Changes with dynamic low-load elbow flexion fatigue and relationships in young and older females, Journal of Electromyography and Kinesiology, 2021, 59.Search in Google Scholar
Barstow T.J., Understanding near infrared spectroscopy and its application to skeletal muscle research, Journal of Applied Physiology, 2019, 126, 1360–1376.Search in Google Scholar
Belardinelli R., Barstow T.J., Porszasz J., Wasserman K., Changes in skeletal muscle oxygenation during incremental exercise measured with near infrared spectroscopy. / Modifications de l ’ oxygenation du muscle squelettique lors d ’ un exercice progressif, mesurees par spectroscopie infrarouge, European Journal of Applied Physiology and Occupational Physiology, 1995, 70, 487–492.Search in Google Scholar
Calaine Inglis E., Iannetta D., Murias J.M., The plateau in the NIRS-derived [HHb] signal near the end of a ramp incremental test does not indicate the upper limit of O2extraction in the vastus lateralis, American Journal of Physiology – Regulatory Integrative and Comparative Physiology, 2017, 313, R723–R729.Search in Google Scholar
Cohen J., Statistical power analysis for the behavioral sciences, 2nd ed., Hillsdale, Lawrence Earlbaum Associates, N.J., 1988.Search in Google Scholar
Crum E.M., O’Connor W.J., Van Loo L., Valckx M., Stannard S.R., Validity and reliability of the Moxy oxygen monitor during incremental cycling exercise, European Journal of Sport Science, 2017, 17, 1037–1043.Search in Google Scholar
Davis P.R., Yakel J.P., Anderson D.J.F., Muscle oxygen demands of the vastus lateralis in back and front squats, International Journal of Exercise Science, 2020, 13, 734–743.Search in Google Scholar
Farzam P., Starkweather Z., Franceschini M.A., Validation of a novel wearable, wireless technology to estimate oxygen levels and lactate threshold power in the exercising muscle, Physiological Reports, 2018, 6, 1–14.Search in Google Scholar
Feldmann A., Schmitz R., Erlacher D., Near-infrared spectroscopy-derived muscle oxygen saturation on a 0% to 100% scale: reliability and validity of the Moxy Monitor, Journal of Biomedical Optics, 2019, 24, 1.Search in Google Scholar
Ferrari M., Mottola L., Quaresima V., Principles, Techniques, and Limitations of Near Infrared Spectroscopy, 2004, 463–487.Search in Google Scholar
Gómez-Carmona C.D., Bastida-Castillo A., Rojas-Valverde D., de la Cruz Sánchez E., García-Rubio J., Ibáñez S.J, et al., Lower-limb Dynamics of Muscle Oxygen Saturation During the Back-squat Exercise: Effects of Training Load and Effort Level, Journal of Strength and Conditioning Research, 2020, 34, 1227–1236.Search in Google Scholar
Guan S., Lin N., Yin Y., Liu H., Liu L., Qi L., The effects of inter-set recovery time on explosive power, electromyography activity and tissue oxygenation during plyometric training, Sensors, 2021, 21, 3015.Search in Google Scholar
Hammer S.M., Alexander A.M., Didier K.D., Huckaby L.M., Barstow T.J., Limb blood flow and muscle oxygenation responses during handgrip exercise above vs. below critical force, Microvascular Research, 2020, 131, 104002.Search in Google Scholar
Hargreaves M., Spriet L.L., Skeletal muscle energy metabolism during exercise, Nature Metabolism 1–12, 2020.Search in Google Scholar
Hearon C.M., Dinenno F.A., Regulation of skeletal muscle blood flow during exercise in ageing humans, Journal of Physiology, 2016, 594, 2261–2273.Search in Google Scholar
Hopker J.G., O’Grady C., Pageaux B., Prolonged constant load cycling exercise is associated with reduced gross efficiency and increased muscle oxygen uptake, Scandinavian Journal of Medicine and Science in Sports, 2017, 27, 408–417.Search in Google Scholar
Hug F., Laplaud D., Lucia A., Grelot L., EMG threshold determination in eight lower limb muscles during cycling exercise: A pilot study, International Journal of Sports Medicine, 2006, 27, 456–462.Search in Google Scholar
Jaén-Carrillo D., Roche-Seruendo L.E., Cartón-Llorente A., García-Pinillos F., Agreement between muscle oxygen saturation from two commercially available systems in endurance running: Moxy Monitor versus Humon Hex, Proceedings of the Institution of Mechanical Engineers, Part P: Journal of Sports Engineering and Technology, 2021, 175433712110157.Search in Google Scholar
Kellawan J.M., Bentley R.F., Bravo M.F., Moynes J.S., Tschakovsky M.E., Does oxygen delivery explain interindividual variation in forearm critical impulse?, Physiological Reports, 2014, 2.Search in Google Scholar
Kirby B.S., Clark D.A., Bradley E.M., Wilkins B.W., The Balance of Muscle Oxygen Supply and Demand Reveals Critical Metabolic Rate and Predicts Time to Exhaustion, Journal of Applied Physiology, japplphysiol.00058.2021, 2021.Search in Google Scholar
Lucero A.A., Addae G., Lawrence W., Neway B., Credeur D.P., Faulkner J. et al., Reliability of muscle blood flow and oxygen consumption response from exercise using near-infrared spectroscopy, Experimental Physiology, 2018, 103, 90–100.Search in Google Scholar
Mancini D.M., Bolinger L., Li H., Kendrick K., Chance B., Wilson J.R., Validation of near-infrared spectroscopy in humans, Journal of Applied Physiology, 1994, 77, 2740–2747.Search in Google Scholar
Manimmanakorn N., Ross J.J., Manimmanakorn A., Lucas S.J., Hamlin M.J., Effect of whole-body vibration therapy on performance recovery, International journal of Sports Physiology and Performance, 2015, 10, 388–395.Search in Google Scholar
Martinez-Garcia D., Rodriguez-Perea A., Barboza P., Ulloa-Díaz D., Jerez-Mayorga D., Chirosa I. et al., Reliability of a standing isokinetic shoulder rotators strength test using a functional electromechanical dynamometer: effects of velocity, PeerJ, 2020, 8, e9951.Search in Google Scholar
Mead A.C., McGlynn M.L., Slivka D.R., Acute effects of functional dry needling on skeletal muscle function, Journal of Bodywork and Movement Therapies, 2021, 26, 123–127.Search in Google Scholar
Miranda-Fuentes C., Chirosa-Ríos L.J., Guisado-Requena I.M., Delgado-Floody P., Jerez-Mayorga D., Changes in muscle oxygen saturation measured using wireless near-infrared spectroscopy in resistance training: A systematic review, International Journal of Environmental Research and Public Health, 2021, 18.Search in Google Scholar
Miranda-Fuentes C., Guisado-Requena I.M., Delgado-Floody P., Arias-Poblete L., Pérez-Castilla A., Jerez-Mayorga D. et al., Reliability of low-cost near-infrared spectroscopy in the determination of muscular oxygen saturation and hemoglobin concentration during rest, isometric and dynamic strength activity, International Journal of Environmental Research and Public Health, 2020, 17, 1–14.Search in Google Scholar
Myers C., Muscle Oxygenation Applications to Endurance Training, Iris Publishers, 2020.Search in Google Scholar
Paradis-Deschênes P., Joanisse D.R., Billaut F., Sex-specific impact of ischemic preconditioning on tissue oxygenation and maximal concentric force, Frontiers in Physiology, 2017, 7.Search in Google Scholar
Peikon E., The Future is NIRS: Muscle Oxygen Saturation as an Estimation of The Power-Duration Relationship, Anat. and Physiol. Open Access J., 2020, 1.Search in Google Scholar
Perrey S., Ferrari M., Muscle Oximetry in Sports Science: A Systematic Review, Sports Medicine (Auckland, NZ), 2018, 48, 597–616.Search in Google Scholar
Poole D.C., Richardson R.S., Determinants of oxygen uptake: Implications for exercise testing, Sports Medicine, 1997, 24, 308–320.Search in Google Scholar
Rodriguez-Perea Á., Jerez-Mayorga D., García-Ramos A., Martínez-García D., Chirosa Ríos L.J., Reliability and concurrent validity of a functional electromechanical dynamometer device for the assessment of movement velocity, Proceedings of the Institution of Mechanical Engineers, Part P: Journal of Sports Engineering and Technology 175433712098488, 2021.Search in Google Scholar
Rodriguez-Perea A., Ríos L.J.C., Martinez-Garcia D., Ulloa-Díaz D., Rojas F.G., Jerez-Mayorga D. et al., Reliability of isometric and isokinetic trunk flexor strength using a functional electromechanical dynamometer, PeerJ, 2019.Search in Google Scholar
Stone K.J., Fryer S.M., Ryan T., Stoner L., The validity and reliability of continuous-wave near-infrared spectroscopy for the assessment of leg blood volume during an orthostatic challenge, Atherosclerosis, 2016, 251, 234–239.Search in Google Scholar
Stringer W., Wasserman K., Casaburi R., Porszasz J., Maehara K., French W., Lactic acidosis as a facilitator of oxyhemoglobin dissociation during exercise, Journal of Applied Physiology, 1994, 76, 1462–1467.Search in Google Scholar
Thornton H.R., Dascombe B., Developing Athlete Monitoring Systems in Team Sports: Data Analysis and Visualization, International Journal of Sports Physiology and Performance, 2019.Search in Google Scholar
