Joseph F. Welch scite author profile

Diaphragmatic fatigue (DF) elicits reflexive increases in sympathetic vasomotor outflow (i.e. metaboreflex). There is some evidence suggesting women may be more resistant to DF compared to men, and therefore may experience an attenuated inspiratory muscle metaboreflex. To this end, we sought to examine the cardiovascular response to inspiratory resistance in healthy young men (n = 9, age = 24 ± 3 years) and women (n = 9, age = 24 ± 3 years). Subjects performed isocapnic inspiratory pressure-threshold loading (PTL, 60% maximal inspiratory mouth pressure) to task failure. Diaphragmatic fatigue was assessed by measuring transdiaphragmatic twitch pressure (P ) using cervical magnetic stimulation. Heart rate (HR) and mean arterial pressure (MAP) were measured beat-by-beat throughout PTL via photoplethysmography, and low-frequency systolic pressure (LF ; a surrogate for sympathetic vasomotor tone) calculated from arterial waveforms using power spectrum analysis. At PTL task failure, the degree of DF was similar between sexes (∼23% reduction in P ; P = 0.33). However, time to task failure was significantly longer in women than in men (27 ± 11 vs. 16 ± 11 min, respectively; P = 0.02). Women exhibited less of an increase in HR (13 ± 8 vs. 19 ± 12 bpm; P = 0.02) and MAP (10 ± 8 vs. 14 ± 9 mmHg; P = 0.01), and significantly lower LF (23 ± 11 vs. 34 ± 8 mmHg ; P = 0.04) during PTL compared to men. An attenuation of the inspiratory muscle metaboreflex may influence limb and respiratory muscle haemodynamics with implications for exercise performance.

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Therapeutic acute intermittent hypoxia: A translational roadmap for spinal cord injury and neuromuscular disease

Vose

Welch

Nair

et al. 2022

Experimental Neurology

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Acute intermittent hypercapnic‐hypoxia elicits central neural respiratory motor plasticity in humans

Welch

Nair

Argento

et al. 2022

The Journal of Physiology

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Acute intermittent hypoxia (AIH) elicits long‐term facilitation (LTF) of respiration. Although LTF is observed when CO2 is elevated during AIH in awake humans, the influence of CO2 on corticospinal respiratory motor plasticity is unknown. Thus, we tested the hypotheses that acute intermittent hypercapnic‐hypoxia (AIHH): (1) enhances cortico‐phrenic neurotransmission (reflecting volitional respiratory control); and (2) elicits ventilatory LTF (reflecting automatic respiratory control). Eighteen healthy adults completed four study visits. Day 1 consisted of anthropometry and pulmonary function testing. On Days 2, 3 and 4, in a balanced alternating sequence, participants received: AIHH, poikilocapnic AIH, and normocapnic‐normoxia (Sham). Protocols consisted of 15, 60 s exposures with 90 s normoxic intervals. Transcranial (TMS) and cervical (CMS) magnetic stimulation were used to induce diaphragmatic motor‐evoked potentials and compound muscle action potentials, respectively. Respiratory drive was assessed via mouth occlusion pressure (P0.1), and minute ventilation measured at rest. Dependent variables were assessed at baseline and 30–60 min after exposures. Increases in TMS‐evoked diaphragm potential amplitudes were observed following AIHH vs. Sham (+28 ± 41%, P = 0.003), but not after AIH. No changes were observed in CMS‐evoked diaphragm potential amplitudes. Mouth occlusion pressure also increased after AIHH (+21 ± 34%, P = 0.033), but not after AIH. Ventilatory LTF was not observed after any treatment. We demonstrate that AIHH elicits central neural mechanisms of respiratory motor plasticity and increases resting respiratory drive in awake humans. These findings may have important implications for neurorehabilitation after spinal cord injury and other neuromuscular disorders compromising breathing. Key points The occurrence of respiratory long‐term facilitation following acute exposure to intermittent hypoxia is believed to be dependent upon CO2 regulation – mechanisms governing the critical role of CO2 have seldom been explored. We tested the hypothesis that acute intermittent hypercapnic‐hypoxia (AIHH) enhances cortico‐phrenic neurotransmission in awake healthy humans. The amplitude of diaphragmatic motor‐evoked potentials induced by transcranial magnetic stimulation was increased after AIHH, but not the amplitude of compound muscle action potentials evoked by cervical magnetic stimulation. Mouth occlusion pressure (P0.1, an indicator of neural respiratory drive) was also increased after AIHH, but not tidal volume or minute ventilation. Thus, moderate AIHH elicits central neural mechanisms of respiratory motor plasticity, without measurable ventilatory long‐term facilitation in awake humans.

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Reliability of the diaphragmatic compound muscle action potential evoked by cervical magnetic stimulation and recorded via chest wall surface EMG

Welch

Mildren

Zaback

et al. 2017

Respiratory Physiology & Neurobiology

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Joseph F. Welch

Sex differences in diaphragmatic fatigue: the cardiovascular response to inspiratory resistance

Therapeutic acute intermittent hypoxia: A translational roadmap for spinal cord injury and neuromuscular disease

Acute intermittent hypercapnic‐hypoxia elicits central neural respiratory motor plasticity in humans

Reliability of the diaphragmatic compound muscle action potential evoked by cervical magnetic stimulation and recorded via chest wall surface EMG

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