The Role of Ca²⁺ in Central Respiratory Control Neurons of the Locus Coeruleus: Development of the Chemosensitive Brake

Imber, Ann Nicole

13 June 2012

No description available.

Biomedical Research

Biophysics

Cellular Biology

Neurobiology

Neurosciences

Physiology

control of breathing

brainstem

calcium

electrophysiology

potassium currents

calcium currents

neuron

Regulation of Breathing under Different Pulmonary Conditions

Rieger-Fackeldey, Esther

January 2004

<p>The breathing pattern of preterm infants is immature and is associated with a variety of reflexes. In a patient on the ventilator these reflexes interfere with spontaneous breathing. A better understanding of the immature control of breathing could lead to further improvements in ventilatory techniques. This thesis concerns studies of pulmonary stretch receptor (PSR) and phrenic nerve activity as part of the regulation of breathing in an animal model. </p><p>During assist/control ventilation with three different inspiratory pressure waveforms in animals with healthy lungs, squarewave pressure waveform<b> </b>strongly inhibits spontaneous inspiratory activity.</p><p>During partial liquid ventilation (PLV) in animals with healthy lungs, all PSRs studied maintained their phasic character, with increased impulse frequency during inspiration. PSR activity was not higher during PLV than during gas ventilation (GV), indicating that there was no extensive stretching of the lung during PLV.</p><p>During proportional assist ventilation (PAV) the applied airway pressure is servo-controlled proportionally to the ongoing breathing effort, thereby interacting with the activity of PSRs. Peak PSR activity was higher and occurred earlier during PAV than during CPAP. The regulation of breathing is maintained during PAV in surfactant-depleted animals before and early after surfactant instillation, with a higher ventilatory response and a lower breathing effort than during CPAP in both conditions.</p><p>Both lung mechanics and gas exchange influence the regulation of breathing. Inhibition of inspiratory activity occurred at a lower arterial pH and a higher PaCO₂ during PLV than during GV in animals with surfactant-depleted lungs, which might be related to recruitment of a larger number of pulmonary stretch receptors during PLV.</p><p>In summary, selected aspects of the regulation of breathing were studied in an animal model with different ventilatory techniques under different lung conditions similar to those that can occur in infants.</p>

Pediatrics

Control of breathing

Pulmonary Stretch Receptor

Phrenic Nerve Activity

Respiratory Distress Syndrome

Surfactant

Partial Liquid Ventilation

Assisted Ventilation

Pediatrik

Paediatric medicine

Pediatrisk medicin

Regulation of Breathing under Different Pulmonary Conditions

Rieger-Fackeldey, Esther

January 2004

The breathing pattern of preterm infants is immature and is associated with a variety of reflexes. In a patient on the ventilator these reflexes interfere with spontaneous breathing. A better understanding of the immature control of breathing could lead to further improvements in ventilatory techniques. This thesis concerns studies of pulmonary stretch receptor (PSR) and phrenic nerve activity as part of the regulation of breathing in an animal model. During assist/control ventilation with three different inspiratory pressure waveforms in animals with healthy lungs, squarewave pressure waveform strongly inhibits spontaneous inspiratory activity. During partial liquid ventilation (PLV) in animals with healthy lungs, all PSRs studied maintained their phasic character, with increased impulse frequency during inspiration. PSR activity was not higher during PLV than during gas ventilation (GV), indicating that there was no extensive stretching of the lung during PLV. During proportional assist ventilation (PAV) the applied airway pressure is servo-controlled proportionally to the ongoing breathing effort, thereby interacting with the activity of PSRs. Peak PSR activity was higher and occurred earlier during PAV than during CPAP. The regulation of breathing is maintained during PAV in surfactant-depleted animals before and early after surfactant instillation, with a higher ventilatory response and a lower breathing effort than during CPAP in both conditions. Both lung mechanics and gas exchange influence the regulation of breathing. Inhibition of inspiratory activity occurred at a lower arterial pH and a higher PaCO2 during PLV than during GV in animals with surfactant-depleted lungs, which might be related to recruitment of a larger number of pulmonary stretch receptors during PLV. In summary, selected aspects of the regulation of breathing were studied in an animal model with different ventilatory techniques under different lung conditions similar to those that can occur in infants.

Pediatrics

Control of breathing

Pulmonary Stretch Receptor

Phrenic Nerve Activity

Respiratory Distress Syndrome

Surfactant

Partial Liquid Ventilation

Assisted Ventilation

Pediatrik

Paediatric medicine

Pediatrisk medicin

Acute Oxygen-Sensing by the Carotid Bodies: The Thermal Microdomain Model

Rakoczy, Ryan Joseph

26 August 2021

No description available.

Cellular Biology

Neurobiology

Neurosciences

Physiology

Biomedical Research

carotid body

carotid bodies

oxygen sensing

cellular oxygen sensing

oxygen-sensing

hypoxia sensing

thermal sensing

heat sensing

heat-sensing

thermal-sensing

control of breathing

oxygen homeostasis

hypoxia

cellular hypoxia

low oxygen signaling

hypoxia signaling

microdomains

micro domains

thermal imaging

cell temperature