| P50 | author | Chung Tin | Q42769370 |
| P2093 | author name string | Chi-Sang Poon | |
| P2860 | cites work | Internal models in sensorimotor integration: perspectives from adaptive control theory | Q24657302 |
| | Alveolar-arterial gas tension differences during graded exercise | Q28256198 |
| | The exercise metaboreflex is maintained in the absence of muscle acidosis: insights from muscle microdialysis in humans with McArdle's disease | Q28365712 |
| | Nonassociative learning as gated neural integrator and differentiator in stimulus-response pathways | Q30540975 |
| | Mechanism of the increased ventilatory response to exercise in patients with chronic heart failure | Q33610840 |
| | Cerebellar internal models: implications for the dexterous use of tools. | Q33779217 |
| | Influence of locomotor muscle metaboreceptor stimulation on the ventilatory response to exercise in heart failure | Q33910535 |
| | Optimal interaction of respiratory and thermal regulation at rest and during exercise: role of a serotonin-gated spinoparabrachial thermoafferent pathway | Q33929094 |
| | Causes of Breathing Inefficiency During Exercise in Heart Failure | Q34191743 |
| | Group III and IV muscle afferents contribute to ventilatory and cardiovascular response to rhythmic exercise in humans | Q34236432 |
| | Transmission of information by the arterial blood stream with particular reference to carbon dioxide | Q34349971 |
| | Skeletal muscle chemoreflex in exercise ventilatory control. | Q34454328 |
| | Experimental pain produced by the submaximum effort tourniquet technique: further evidence of validity | Q69853946 |
| | Differences in overall 'gain' of CO2-feedback system between dead space and CO2 ventilations in man | Q70513000 |
| | Contribution of muscle afferents to the hemodynamic, autonomic, and ventilatory responses to exercise in patients with chronic heart failure: effects of physical training | Q70993117 |
| | Relation between chemosensitivity and the ventilatory response to exercise in chronic heart failure | Q71012876 |
| | Normal values for pulmonary gas exchange during exercise | Q71268598 |
| | Chemical and nonchemical components of ventilation during hypercapnic exercise in man | Q71504704 |
| | Ventilation and gas exchange in the mute swan, Cygnus olor | Q71506141 |
| | The relation of ventilation to metabolic rate during moderate exercise in man | Q71514992 |
| | Oscillations of arterial CO2 tension in a respiratory model: some implications for the control of breathing in exercise | Q71516106 |
| | Muscle metaboreceptors in hemodynamic, autonomic, and ventilatory responses to exercise in men | Q71553299 |
| | Arterial CO2 response to low levels of inspired CO2 in awake beagle dogs | Q71596352 |
| | The ph oscillations in arterial blood during exercise; a potential signal for the ventilatory response in the dog | Q71629905 |
| | Experimental pain stimulates respiration and attenuates morphine-induced respiratory depression: a controlled study in human volunteers | Q71676105 |
| | Ventilatory Responses during Incremental Exercise in Men under Hyperoxic Conditions | Q71998826 |
| | Enhancement of the ventilatory response to carbon dioxide by tube breathing | Q72025361 |
| | Respiratory effects of breathing down a tube | Q72372325 |
| | An experimental pain method sensitive to morphine in man: the submaximum effort tourniquet technique | Q72810233 |
| | Clinical correlates and prognostic significance of the ventilatory response to exercise in chronic heart failure | Q73407528 |
| | Impact of heart failure and exercise capacity on sympathetic response to handgrip exercise | Q73442050 |
| | Gas exchange efficiency in congestive heart failure II | Q73446442 |
| | Enhanced ventilatory response to exercise in patients with chronic heart failure and preserved exercise tolerance: marker of abnormal cardiorespiratory reflex control and predictor of poor prognosis | Q73446461 |
| | Respiratory responses to CO2 inhalation; a theoretical study of a nonlinear biological regulator | Q73659780 |
| | Gas exchange efficiency in congestive heart failure | Q73907416 |
| | Impairment of ventilatory efficiency in heart failure: prognostic impact | Q73907430 |
| | Skeletal muscle ECF pH error signal for exercise ventilatory control | Q74125906 |
| | Skeletal muscle chemoreflex and pHi in exercise ventilatory control | Q74222018 |
| | Physiological dead space and alveolar gas pressures at rest and during muscular exercise | Q74372753 |
| | Alveolar dead space as an index of distribution of blood flow in pulmonary capillaries | Q74527474 |
| | Peripheral muscle ergoreceptors and ventilatory response during exercise recovery in heart failure | Q74591083 |
| | EFFECT OF CO2 ON RESPIRATION USING A NEW METHOD OF ADMINISTERING CO2 | Q76563841 |
| | Possible mechanism of augmented exercise hyperpnea in congestive heart failure | Q77292191 |
| | Enhanced sympathetic and ventilatory responses to central chemoreflex activation in heart failure | Q78017138 |
| | Dead-space ventilation as a determinant in the ventilation-perfusion concept | Q78888799 |
| | Mathematical analysis of the time course of alveolar carbon dioxide | Q79305792 |
| | Parasympathetic reactivation after repeated sprint exercise | Q79873691 |
| | Muscle afferent inputs to cardiovascular control during isometric exercise vary with muscle group in patients with chronic heart failure | Q79943480 |
| | Increased mechanoreceptor stimulation explains the exaggerated exercise pressor reflex seen in heart failure | Q80312577 |
| | Observations in man upon a blood pressure raising reflex arising from the voluntary muscles | Q80329476 |
| | Paradoxical potentiation of exercise hyperpnea in congestive heart failure contradicts Sherrington chemoreflex model and supports a respiratory optimization model | Q83164901 |
| | Arterial H+ regulation during exercise in humans | Q84399904 |
| | Evolving paradigms in H+ control of breathing: from homeostatic regulation to homeostatic competition | Q84817589 |
| | Effects of dead space loading on neuro-muscular and neuro-ventilatory coupling of the respiratory system during exercise in healthy adults: implications for dyspnea and exercise tolerance | Q84882883 |
| | Dead space and tidal volume of the giraffe compared with some other mammals | Q95792980 |
| | Alveolar PCO2 oscillations and ventilation at sea level and at high altitude | Q34584217 |
| | The Mendelian Revolution. The Emergence of Hereditarian Concepts in Modern Science and Society. Peter J. Bowler. Johns Hopkins University Press, Baltimore, 1989. viii, 207 pp., $29.95. | Q34669485 |
| | Control of mental activities by internal models in the cerebellum | Q34758532 |
| | An acid-sensing ion channel that detects ischemic pain | Q36301165 |
| | Homeostasis of exercise hyperpnea and optimal sensorimotor integration: the internal model paradigm | Q36426554 |
| | Acid-sensing ion channels contribute to the metaboreceptor component of the exercise pressor reflex | Q37264418 |
| | Neural basis of sensorimotor learning: modifying internal models | Q37340762 |
| | Internal models of eye movement in the floccular complex of the monkey cerebellum | Q37428279 |
| | Standards for the use of cardiopulmonary exercise testing for the functional evaluation of cardiac patients: a report from the Exercise Physiology Section of the European Association for Cardiovascular Prevention and Rehabilitation. | Q37480687 |
| | Internal models and neural computation in the vestibular system | Q37638424 |
| | Excess ventilation during exercise and prognosis in chronic heart failure | Q37831731 |
| | Measuring the respiratory chemoreflexes in humans. | Q37868207 |
| | Gas exchange consequences of left heart failure | Q38112052 |
| | Changes in arterial K+ and ventilation during exercise in normal subjects and subjects with McArdle's syndrome. | Q38515907 |
| | Exercise-induced muscle pain, soreness, and cramps. | Q38572232 |
| | Effect of carotid body resection on ventilatory and acid-base control during exercise | Q40343069 |
| | Sensing muscle ischemia: coincident detection of acid and ATP via interplay of two ion channels. | Q41126236 |
| | Ventilatory control in hypercapnia and exercise: optimization hypothesis | Q41384653 |
| | Control of exercise hyperpnea during hypercapnia in humans | Q41505548 |
| | Decreased exercise hyperpnea in patients with bilateral carotid chemoreceptor resection | Q41738779 |
| | Muscle mechanoreceptor sensitivity in heart failure | Q42468972 |
| | Cardiovascular and ventilatory responses to dynamic exercise during epidural anaesthesia in man. | Q42484211 |
| | Homeostatic competition: evidence of a serotonin-gated spinoparabrachial pathway for respiratory and thermoregulatory interaction | Q43136149 |
| | Autonomic control of heart rate by metabolically sensitive skeletal muscle afferents in humans | Q43168378 |
| | Physiologic changes following bilateral carotid-body resection in patients with chronic obstructive pulmonary disease | Q43661330 |
| | Relationship of carbon dioxide tension in arterial blood to pulmonary wedge pressure in heart failure | Q43885308 |
| | Opioid-mediated muscle afferents inhibit central motor drive and limit peripheral muscle fatigue development in humans. | Q44340694 |
| | Peripheral chemoreceptor hypersensitivity: an ominous sign in patients with chronic heart failure | Q44578930 |
| | Differential contribution of dead space ventilation and low arterial pCO2 to exercise hyperpnea in patients with chronic heart failure secondary to ischemic or idiopathic dilated cardiomyopathy | Q44753593 |
| | Potentiation of exercise ventilatory response by airway CO2 and dead space loading | Q44983616 |
| | Cardiopulmonary exercise testing (CPET) in pulmonary emphysema | Q44997039 |
| | The physiological legacy of the Fenn, Rahn, and Otis school. | Q45990687 |
| | Effect of arterial occlusion on responses of group III and IV afferents to dynamic exercise | Q46122224 |
| | Ventilatory responses to passive leg motion in children with congenital central hypoventilation syndrome | Q46122347 |
| | Ventilatory efficiency during exercise in healthy subjects | Q46129482 |
| | Ventilatory response to exercise in children with congenital central hypoventilation syndrome | Q46153961 |
| | Dorsal root ganglion neurons innervating skeletal muscle respond to physiological combinations of protons, ATP, and lactate mediated by ASIC, P2X, and TRPV1. | Q46570470 |
| | Cyclooxygenase blockade attenuates responses of group III and IV muscle afferents to dynamic exercise in cats | Q46772581 |
| | Exercise hyperventilation in chronic heart failure is not caused by systemic lactic acidosis | Q46834633 |
| | Central modulation of exercise-induced muscle pain in humans. | Q46954357 |
| | Role of acid-base balance in the chemoreflex control of breathing | Q47743332 |
| | Breathing during Exercise | Q48197044 |
| | Implications of group III and IV muscle afferents for high-intensity endurance exercise performance in humans. | Q48235005 |
| | On the contribution of group III and IV muscle afferents to the circulatory response to rhythmic exercise in humans. | Q48257462 |
| | Identifying cardiorespiratory neurocircuitry involved in central command during exercise in humans. | Q48379966 |
| | Comment on "Universality in the evolution of orientation columns in the visual cortex". | Q48545414 |
| | Ventilatory responses to exercise in humans lacking ventilatory chemosensitivity. | Q48865002 |
| | Identifying cardiovascular neurocircuitry involved in the exercise pressor reflex in humans using functional neurosurgery. | Q50531181 |
| | Coupling of dyspnea perception and tachypneic breathing during hypercapnia. | Q50608607 |
| | Lung function and exercise gas exchange in chronic heart failure. | Q50929116 |
| | Comparison of muscle sympathetic activity in ischemic and nonischemic heart failure. | Q50943923 |
| | Effect of Bilateral Carotid-Body Resection on Ventilatory Control at Rest and during Exercise in Man | Q51118225 |
| | A clinical method for assessing the ventilatory response to carbon dioxide | Q51218996 |
| | The exercise hyperpnea dilemma | Q51281759 |
| | Short-term modulation of the exercise ventilatory response in younger and older women. | Q51418434 |
| | Effects of pain and arousal on the control of breathing. | Q51651563 |
| | Neural control of cardiovascular responses and of ventilation during dynamic exercise in man. | Q51653458 |
| | Lung volumes in giraffes, Giraffa camelopardalis | Q51661760 |
| | Conventional versus slug CO2 loading and the control of breathing in anaesthetized cats | Q51701069 |
| | Exercise hyperpnea in chronic heart failure: relationships to lung stiffness and expiratory flow limitation. | Q51723956 |
| | Ventilatory responses to low levels of CO2 inhalation in the cat. | Q51849616 |
| | The classic potentiation of exercise ventilatory response by increased dead space in humans is more than short-term modulation. | Q51872750 |
| | Reference values for dynamic responses to incremental cycle ergometry in males and females aged 20 to 80. | Q52051757 |
| | Habituation of the early pain-specific respiratory response in sustained pain. | Q52138632 |
| | Ventilatory control during exercise with increased respiratory dead space in goats. | Q52476500 |
| | The ventilatory CO2 sensitivities from Read's rebreathing method and the steady-state method are not equal in man. | Q52536643 |
| | Interaction of series and parallel dead space in the lung | Q52701901 |
| | Ventilatory control during exercise with increased external dead space. | Q52766292 |
| | Control of the exercise hyperpnea: the unanswered question. | Q52852358 |
| | A neural link to explain the "muscle hypothesis" of exercise intolerance in chronic heart failure. | Q54094629 |
| | Increased exercise ventilation in patients with chronic heart failure: intact ventilatory control despite hemodynamic and pulmonary abnormalities. | Q54415835 |
| | Interaction of physiological mechanisms during exercise. | Q54703020 |
| | Contribution of skeletal muscle 'ergoreceptors' in the human leg to respiratory control in chronic heart failure | Q57422766 |
| | Respiratory oscillations in arterial carbon dioxide tension as a control signal in exercise | Q59095064 |
| | Evolution of the concept of ventilatory limitation during exercise. Combining the pneumologist and cardiologist point of view | Q60808161 |
| | The Ergoreflex in patients with chronic stable heart failure | Q61650977 |
| | Ventilatory response to low levels of CO2 | Q67346592 |
| | Skeletal muscle metaboreceptor exercise responses are attenuated in heart failure | Q68033373 |
| | A constant flux of carbon dioxide injected into the airways mimics metabolic carbon dioxide in exercise | Q68383853 |
| | Influence of inspired oxygen concentration on the dynamics of the exercise hyperpnoea in man | Q69148210 |
| | The respiratory effects in man of altering the time profile of alveolar carbon dioxide and oxygen within each respiratory cycle | Q69632199 |
| | Tourniquet pain: a volunteer study | Q69634452 |
| P433 | issue | 1 | |
| P921 | main subject | heart failure | Q181754 |
| | chronic heart failure | Q11829287 |
| P304 | page(s) | 114-130 | |
| P577 | publication date | 2012-12-27 | |
| P1433 | published in | Respiratory Physiology & Neurobiology | Q14256527 |
| P1476 | title | Mechanism of augmented exercise hyperpnea in chronic heart failure and dead space loading | |
| P478 | volume | 186 | |