UBC-Nepal Expedition: Motor Unit Characteristics in Lowlanders Acclimatized to High Altitude and Sherpa

ABSTRACT Introduction With acclimatization to high altitude (HA), adaptations occur throughout the nervous system and at the level of the muscle, which may affect motor unit (MU) characteristics. However, despite the importance of MUs as the final common pathway for the control of voluntary movement, little is known about their adaptations with acclimatization. Methods Ten lowlanders and Sherpa participated in this study 7 to 14 d after arrival at HA (5050 m), with seven lowlanders repeating the experiment at sea level (SL), 6 months after the expedition. The maximal compound muscle action potential (Mmax) was recorded from relaxed biceps brachii. During isometric elbow flexions at 10% of maximal torque, a needle electrode recorded the MU discharge rate (MUDR) and MU potential (MUP) characteristics of single biceps brachii MUs. Results Compared with SL, acclimatized lowlanders had ~10% greater MUDR, ~11% longer MUP duration, as well as ~18% lower amplitude and ~6% greater duration of the first phase of the Mmax (all P < 0.05). No differences were noted between SL and HA for variables related to MUP shape (e.g., jitter, jiggle; P > 0.08). Apart from lower near-fiber MUP area for Sherpa than acclimatized lowlanders (P < 0.05), no Mmax or MU data were different between groups (P > 0.10). Conclusions Like other components of the body, MUs in lowlanders adapt with acclimatization to HA. The absence of differences between acclimatized lowlanders and Sherpa suggests that evolutionary adaptations to HA are smaller for MUs than components of the cardiovascular or respiratory systems.

[1]  M. Stembridge,et al.  Highs and Lows of Sympathetic Neuro-cardiovascular Transduction: Influence of Altitude Acclimatization and Adaptation. , 2020, American journal of physiology. Heart and circulatory physiology.

[2]  B. Levine,et al.  The overlooked significance of plasma volume for successful adaptation to high altitude in Sherpa and Andean natives , 2019, Proceedings of the National Academy of Sciences.

[3]  M. Stembridge,et al.  Baroreflex control of sympathetic vasomotor activity and resting arterial pressure at high altitude: insight from Lowlanders and Sherpa , 2019, The Journal of physiology.

[4]  J. Kavanagh,et al.  Reduced blood oxygen levels induce changes in low-threshold motor unit firing that align with the individual's tolerance to hypoxia. , 2019, Journal of neurophysiology.

[5]  P. Ainslie,et al.  UBC‐Nepal expedition: peripheral fatigue recovers faster in Sherpa than lowlanders at high altitude , 2018, The Journal of physiology.

[6]  J. Duchateau,et al.  Acute Effect of Noradrenergic Modulation on Motor Output Adjustment in Men , 2018, Medicine and science in sports and exercise.

[7]  Martin J. MacInnis,et al.  The 2018 Lake Louise Acute Mountain Sickness Score. , 2018, High altitude medicine & biology.

[8]  B. Saltin,et al.  Sustained sympathetic activity in altitude acclimatizing lowlanders and high‐altitude natives , 2018, Scandinavian journal of medicine & science in sports.

[9]  Javier Rodriguez-Falces,et al.  Determinants, analysis and interpretation of the muscle compound action potential (M wave) in humans: implications for the study of muscle fatigue , 2017, European Journal of Applied Physiology.

[10]  J. Rodríguez-Falces,et al.  Muscle excitability during sustained maximal voluntary contractions by a separate analysis of the M‐wave phases , 2017, Scandinavian journal of medicine & science in sports.

[11]  C. McNeil,et al.  UBC‐Nepal expedition: acclimatization to high‐altitude increases spinal motoneurone excitability during fatigue in humans , 2017, The Journal of physiology.

[12]  C. Lundby,et al.  Regulation of blood volume in lowlanders exposed to high altitude. , 2017, Journal of applied physiology.

[13]  C. Rice,et al.  Electrophysiological and neuromuscular stability of persons with chronic inflammatory demyelinating polyneuropathy , 2017, Muscle & nerve.

[14]  J. Griffin,et al.  Metabolic basis to Sherpa altitude adaptation , 2017, Proceedings of the National Academy of Sciences.

[15]  J. Coppel,et al.  Sublingual microcirculatory blood flow and vessel density in Sherpas at high altitude. , 2017, Journal of applied physiology.

[16]  C. Rice,et al.  Motor unit number estimation and neuromuscular fidelity in 3 stages of sarcopenia , 2016, Muscle & nerve.

[17]  T. Simonson,et al.  Altitude Adaptation: A Glimpse Through Various Lenses. , 2015, High altitude medicine & biology.

[18]  D. Stashuk,et al.  Increased neuromuscular transmission instability and motor unit remodelling with diabetic neuropathy as assessed using novel near fibre motor unit potential parameters , 2015, Clinical Neurophysiology.

[19]  E. Gilbert-kawai,et al.  King of the mountains: Tibetan and Sherpa physiological adaptations for life at high altitude. , 2014, Physiology.

[20]  A. Subudhi,et al.  AltitudeOmics: Rapid Hemoglobin Mass Alterations with Early Acclimatization to and De-Acclimatization from 5260 m in Healthy Humans , 2014, PloS one.

[21]  A. Murray,et al.  How wasting is saving: Weight loss at altitude might result from an evolutionary adaptation , 2014, BioEssays : news and reviews in molecular, cellular and developmental biology.

[22]  S. Goodall,et al.  AltitudeOmics: exercise‐induced supraspinal fatigue is attenuated in healthy humans after acclimatization to high altitude , 2014, Acta physiologica.

[23]  S. Goodall,et al.  AltitudeOmics: on the consequences of high-altitude acclimatization for the development of fatigue during locomotor exercise in humans. , 2013, Journal of applied physiology.

[24]  Chris J. McNeil,et al.  Testing the excitability of human motoneurons , 2013, Front. Hum. Neurosci..

[25]  T. Doherty,et al.  Intra- and inter-rater reliability of motor unit number estimation and quantitative motor unit analysis in the upper trapezius , 2012, Clinical Neurophysiology.

[26]  S. Gandevia,et al.  A novel way to test human motoneurone behaviour during muscle fatigue , 2011 .

[27]  J. Jakobi,et al.  Age independent and position-dependent alterations in motor unit activity of the biceps brachii , 2010, European Journal of Applied Physiology.

[28]  S. Gandevia,et al.  The response to paired motor cortical stimuli is abolished at a spinal level during human muscle fatigue , 2009, The Journal of physiology.

[29]  C. Heckman,et al.  Motoneuron excitability: The importance of neuromodulatory inputs , 2009, Clinical Neurophysiology.

[30]  C. Rice,et al.  Inter-rater reliability of motor unit number estimates and quantitative motor unit analysis in the tibialis anterior muscle , 2009, Clinical Neurophysiology.

[31]  A. Oliviero,et al.  Functional involvement of central nervous system at high altitude , 2009, Experimental Brain Research.

[32]  A. Hoffman,et al.  Endocrine responses to acute and chronic high-altitude exposure (4,300 meters): modulating effects of caloric restriction. , 2006, American journal of physiology. Endocrinology and metabolism.

[33]  D. Stashuk,et al.  Decomposition‐based quantitative electromyography: Methods and initial normative data in five muscles , 2003, Muscle & nerve.

[34]  B. Saltin,et al.  The re‐establishment of the normal blood lactate response to exercise in humans after prolonged acclimatization to altitude , 2001, The Journal of physiology.

[35]  H. Hoppeler,et al.  Muscle tissue adaptations to hypoxia. , 2001, The Journal of experimental biology.

[36]  P. Bärtsch,et al.  [High altitude medicine]. , 2001, Anasthesiologie, Intensivmedizin, Notfallmedizin, Schmerztherapie : AINS.

[37]  J. Richalet,et al.  Effects of prolonged hypobaric hypoxia on human skeletal muscle function and electromyographic events. , 2000, Clinical science.

[38]  A. Pipe,et al.  Downregulation in muscle Na(+)-K(+)-ATPase following a 21-day expedition to 6,194 m. , 2000, Journal of applied physiology.

[39]  D W Stashuk,et al.  Decomposition and quantitative analysis of clinical electromyographic signals. , 1999, Medical engineering & physics.

[40]  P. W. Hochachka,et al.  Unifying theory of hypoxia tolerance: molecular/metabolic defense and rescue mechanisms for surviving oxygen lack. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[41]  C Orizio,et al.  Effect of acclimatization to high altitude (5,050 m) on motor unit activation pattern and muscle performance. , 1994, Journal of applied physiology.

[42]  B. Groves,et al.  Arterial catecholamine responses during exercise with acute and chronic high-altitude exposure. , 1991, The American journal of physiology.

[43]  P. Cerretelli,et al.  Muscle structure and performance capacity of Himalayan Sherpas. , 1991, Journal of applied physiology.

[44]  A A Vandervoort,et al.  Contractile changes in opposing muscles of the human ankle joint with aging. , 1986, Journal of applied physiology.

[45]  S. Lahiri,et al.  Blunted hypoxic drive to ventilation in subjects with life-long hypoxemia. , 1969, Federation proceedings.

[46]  H. Rahn,et al.  Man's respiratory response during and after acclimatization to high altitude. , 1949, The American journal of physiology.

[47]  Chris J. McNeil,et al.  Supraspinal Fatigue and Neural-evoked Responses in Lowlanders and Sherpa at 5050 m , 2019, Medicine and science in sports and exercise.

[48]  P. Ainslie,et al.  High-Altitude Acclimatization Improves Recovery from Muscle Fatigue. , 2019, Medicine and science in sports and exercise.

[49]  M. Sander Does the Sympathetic Nervous System Adapt to Chronic Altitude Exposure? , 2016, Advances in experimental medicine and biology.

[50]  T. Binzoni,et al.  Alpha-motoneuron excitability at high altitude , 2004, European Journal of Applied Physiology and Occupational Physiology.