about
Regulation of breathing and autonomic outflows by chemoreceptors.Respiratory response to passive limb movement is suppressed by a cognitive task.Group III and IV muscle afferents contribute to ventilatory and cardiovascular response to rhythmic exercise in humans.Differences in muscle strength after ACL reconstruction do not influence cardiorespiratory responses to isometabolic exerciseThe effect of adding CO2 to hypoxic inspired gas on cerebral blood flow velocity and breathing during incremental exerciseRemote control of respiratory neural network by spinal locomotor generatorsAdaptation in the respiratory control system.Specific neural substrate linking respiration to locomotion.Rate dependent influence of arterial desaturation on self-selected exercise intensity during cycling.Homeostasis of exercise hyperpnea and optimal sensorimotor integration: the internal model paradigmExercise during Short-Term and Long-Term Continuous Exposure to Hypoxia Exacerbates Sleep-Related Periodic Breathing.Higher ventilatory responses during and after passive walking-like leg movement in older individuals.Clinical consequences of altered chemoreflex control.Defining the neurocircuitry of exercise hyperpnoea.The fast exercise drive to breathe.Evaluating the importance of the carotid chemoreceptors in controlling breathing during exercise in man.Enhancing neural activity to drive respiratory plasticity following cervical spinal cord injury.Dopamine D1 receptors control exercise hyperpnoea in mice.The control of ventilation during exercise: a lesson in critical thinking.Dopaminergic modulation of exercise hyperpnoea via D(2) receptors in mice."Supraspinal locomotor centers do/do not contribute significantly to the hyperpnea of dynamic exercise in humans".An Improved Dynamic Model for the Respiratory Response to Exercise.An integrated exercise response and muscle fatigue model for performance decrement estimates of workloads in oxygen-limiting environments.Predictive value of ventilatory inflection points determined under field conditions.Development of an anaesthetized-rat model of exercise hyperpnoea: an integrative model of respiratory control using an equilibrium diagram.Eccentric exercise-induced muscle damage dissociates the lactate and gas exchange thresholds
P2860
Q30301264-54712BEE-6F77-4FF5-8155-99A492201427Q33340239-FD7B034B-01FD-42D6-96AF-2628A06A8B3FQ34236432-03A41A71-EFE3-4CEA-B24D-571BB0FB12A3Q34280675-B600B4E2-9DF3-48FC-8479-53B7281CE87EQ35053907-3C5220F5-0237-41D6-8331-7BC43E108B89Q35107871-3CB856D5-8691-4E43-B8FE-80BF833781C8Q35191508-38472D1D-D662-4626-82D7-DECD8C53026CQ35673805-354D2BB5-53AF-48F0-B2CA-5998619211D7Q36296508-9D5A5963-C7A5-4AEC-98A9-02F89A7F88B1Q36426554-A480D9BE-6B0F-4565-882E-631A4B6D817FQ36686474-E28904C9-7E35-489A-A3D8-56377C361990Q37317593-4F73FF8C-C87F-441E-B80F-B0C7E32A8379Q38107387-D151FE12-1801-4F7E-B43F-DC1D9A0B8605Q38126900-07927865-ABD4-4073-A366-A66E0F971B49Q38128559-C99DD146-94BD-49BD-BB8E-A50FACCAD908Q38162846-8BF966DA-DAA9-4C5C-BBB1-E7E13364BB3FQ38942953-2137DFFB-8A18-4C5B-9351-4DFF21AEA6E5Q42670380-F8F99CEE-2CFA-496B-B55A-5B8A31D26271Q47733598-F7694D3C-7D5C-4D56-8DD3-7ED0E3C552FEQ48032861-9DED193A-F139-4058-AA71-A0E5FBCDBE2EQ48616784-1B7A3BA0-5165-4F14-A8C7-C362BA5DD7B3Q50156217-3CEDB0A8-2A06-431F-86CD-561EFE96E3C7Q51547043-B65616A0-7B4D-43A6-A50F-0527C4335026Q51611431-A05FA440-4D25-41D0-B2CA-8245B443CA29Q52671767-C55265F0-D954-4B18-9F7F-B5FD90DE2C74Q57677833-1A985F2F-57F2-4600-B9AC-8395B93EA070
P2860
description
1995 nî lūn-bûn
@nan
1995年の論文
@ja
1995年論文
@yue
1995年論文
@zh-hant
1995年論文
@zh-hk
1995年論文
@zh-mo
1995年論文
@zh-tw
1995年论文
@wuu
1995年论文
@zh
1995年论文
@zh-cn
name
A review of the control of breathing during exercise.
@en
type
label
A review of the control of breathing during exercise.
@en
prefLabel
A review of the control of breathing during exercise.
@en
P2860
P356
P1476
A review of the control of breathing during exercise.
@en
P2093
J H Mateika
P2860
P356
10.1007/BF00511228
P50
P577
1995-01-01T00:00:00Z