Tabitha Y. Shen scite author profile

Diseases affecting pulmonary mechanics often result in changes to the coordination of swallow and breathing. We hypothesize that during times of increased intrathoracic pressure, swallow suppresses ongoing expiratory drive to ensure bolus transport through the esophagus. To this end, we sought to determine the effects of swallow on abdominal electromyographic (EMG) activity during expiratory threshold loading in anesthetized cats and in awake-healthy adult humans. Expiratory threshold loads were applied to recruit abdominal motor activity during breathing, and swallow was triggered by infusion of water into the mouth. In both anesthetized cats and humans, expiratory cycles which contained swallows had a significant reduction in abdominal EMG activity, and a greater percentage of swallows were produced during inspiration and/or respiratory phase transitions. These results suggest that: a) spinal expiratory motor pathways play an important role in the execution of swallow, and b) a more complex mechanical relationship exists between breathing and swallow than has previously been envisioned.

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Laparoscopic renal parenchymal hypothermia with novel ice-slush deployment mechanism

Ames¹,

Venkatesh²,

Weld³

et al. 2005

Urology

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Influence of intrathoracic vagotomy on the cough reflex in the anesthetized cat

Shen

Pertzborn

Rose

et al. 2022

Respiratory Physiology & Neurobiology

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Recurrent laryngeal afferent fibers are primarily responsible for cough in response to mechanical or chemical stimulation of the upper trachea and larynx in the guinea pig. Lower airway slowly adapting receptors have been proposed to have a permissive effect on the cough reflex. We hypothesized that vagotomy below the recurrent laryngeal nerve branch would depress mechanically or chemically induced cough. In anesthetized, bilaterally thoracotomized, artificially ventilated cats, thoracic vagotomy nearly eliminated cough induced by mechanical stimulation of the intrathoracic airway, significantly depressed mechanically stimulated laryngeal cough, and eliminated capsaicin-induced cough. These results support an important role of lower airway sensory feedback in the production of tracheobronchial and laryngeal cough in the cat. Further, at least some of this feedback is due to excitation from pulmonary volume-sensitive sensory receptors.

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Upper Airway and Abdominal Motor Output During Sneezing: Is the In Vivo Decererate Rat an Adequate Model?

Ono

Shen

Chun

et al. 2009

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While numerous studies have focused on identifying and characterizing the neural mechanisms mediating upper airway defense reflexes in the anesthetized or decerebrate adult cat, little is known about these behaviors in in vivo rodent models. The current study was undertaken to investigate whether the in vivo decelerate adult rat might serve as an acceptable model for studying these behaviors. To begin to address this possibility, we examined multiple respiratory motor activities in response to mechanical stimulation of the anterior nasal cavity (sufficient to elicit fictive sneezing) in in vivo decerebrate adult rats. We found that the neural activities observed during nasal stimulation were consistent with those previously reported during fictive sneezing in the adult cat model. We suggest that the in vivo decerebrate rat is an acceptable model for studying the sneezing reflex.

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GABA-ergic neurotransmission in the nucleus of the solitary tract modulates cough in the cat

Kotmanova

Simera

Veternik

et al. 2018

Respiratory Physiology & Neurobiology

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GABA, muscimol, and baclofen were microinjected into the rostral (rNTS) and caudal solitary tract nucleus (cNTS) in 24 anesthetized cats. Electromyograms (EMGs) of diaphragm (DIA) and abdominal muscles (ABD), blood pressure and esophageal pressure (EP) were recorded and analysed. Bilateral microinjections of 1 mM GABA (total 66 ± 4 nl), 1 mM baclofen (64 ± 4 nl) and unilateral microinjections of 0.5 mM muscimol (33 ± 1 nl) in the rNTS significantly reduced cough number (CN), amplitudes of ABD EMGs, expiratory EP, and prolonged the duration of the cough inspiratory phase. GABA microinjections decreased the amplitudes of cough-related DIA EMGs and inspiratory EP; muscimol microinjections decreased the cough DIA EMG on the contralateral side. Only microinjections of GABA into the cNTS suppressed CN. In some cases, microinjections prolonged the inspiratory phase, lowered respiratory rate, changed the depth of breathing, and increased blood pressure and heart rate. Our results confirm that GABA-ergic inhibitory mechanisms in the rNTS can regulate coughing in the anesthetized cat.

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Tabitha Y. Shen

Suppression of Abdominal Motor Activity during Swallowing in Cats and Humans

Laparoscopic renal parenchymal hypothermia with novel ice-slush deployment mechanism

Influence of intrathoracic vagotomy on the cough reflex in the anesthetized cat

Upper Airway and Abdominal Motor Output During Sneezing: Is the In Vivo Decererate Rat an Adequate Model?

GABA-ergic neurotransmission in the nucleus of the solitary tract modulates cough in the cat

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