methylatropine and Hypercapnia

methylatropine has been researched along with Hypercapnia* in 2 studies

Other Studies

2 other study(ies) available for methylatropine and Hypercapnia

Article	Year
Central and peripheral mechanisms underlying gastric distention inhibitory reflex responses in hypercapnic-acidotic rats. American journal of physiology. Heart and circulatory physiology, 2011, Volume: 300, Issue:3 We have observed that in chloralose-anesthetized animals, gastric distension (GD) typically increases blood pressure (BP) under normoxic normocapnic conditions. However, we recently noted repeatable decreases in BP and heart rate (HR) in hypercapnic-acidotic rats in response to GD. The neural pathways, central processing, and autonomic effector mechanisms involved in this cardiovascular reflex response are unknown. We hypothesized that GD-induced decrease in BP and HR reflex responses are mediated during both withdrawal of sympathetic tone and increased parasympathetic activity, involving the rostral (rVLM) and caudal ventrolateral medulla (cVLM) and the nucleus ambiguus (NA). Rats anesthetized with ketamine and xylazine or α-chloralose were ventilated and monitored for HR and BP changes. The extent of cardiovascular inhibition was related to the extent of hypercapnia and acidosis. Repeated GD with both anesthetics induced consistent falls in BP and HR. The hemodynamic inhibitory response was reduced after blockade of the celiac ganglia or the intraabdominal vagal nerves with lidocaine, suggesting that the decreased BP and HR responses were mediated by both sympathetic and parasympathetic afferents. Blockade of the NA decreased the bradycardia response. Microinjection of kainic acid into the cVLM reduced the inhibitory BP response, whereas depolarization blockade of the rVLM decreased both BP and HR inhibitory responses. Blockade of GABA(A) receptors in the rVLM also reduced the BP and HR reflex responses. Atropine methyl bromide completely blocked the reflex bradycardia, and atenolol blocked the negative chronotropic response. Finally, α(1)-adrenergic blockade with prazosin reversed the depressor. Thus, in the setting of hypercapnic-acidosis, a sympathoinhibitory cardiovascular response is mediated, in part, by splanchnic nerves and is processed through the rVLM and cVLM. Additionally, a vagal excitatory reflex, which involves the NA, facilitates the GD-induced decreases in BP and HR responses. Efferent chronotropic responses involve both increased parasympathetic and reduced sympathetic activity, whereas the decrease in BP is mediated by reduced α-adrenergic tone. Topics: Acidosis; Adrenergic alpha-1 Receptor Antagonists; Anesthetics; Animals; Atenolol; Atropine Derivatives; Blood Pressure; Bradycardia; Gastric Dilatation; Heart Rate; Hypercapnia; Kainic Acid; Male; Medulla Oblongata; Parasympathetic Nervous System; Parasympatholytics; Prazosin; Rats; Rats, Sprague-Dawley; Receptors, GABA-A; Reflex; Sympathetic Nervous System; Sympatholytics	2011
Neurochemical control of tissue resistance in piglets. Journal of applied physiology (Bethesda, Md. : 1985), 1995, Volume: 79, Issue:3 Lung resistance may be influenced by chemoreceptor activity and modulated by inspiratory neural output; however, it is unknown whether the contractile elements of lung tissue participate in these changes during early development. In anesthetized paralyzed open-chest piglets, we measured phrenic electroneurogram, lung resistance (RL), and tissue resistance utilizing alveolar capsules to partition the hypercapnic and hypoxic responses of RL into tissue (Rti) and airway resistance (Raw) components. Inhalation of 7% CO2 significantly increased RL (7.4 +/- 0.5 to 11.3 +/- 0.6 cmH2O.l-1.s), Rti (5.2 +/- 0.5 to 6.9 +/- 0.5 cmH2O.l-1.s), and Raw (2.2 +/- 0.2 to 4.4 +/- 0.4 cmH2O.l-1.s). Inhalation of 12% O2 caused more modest increases in RL, Rti, and Raw. Oscillations in tracheal and alveolar pressures appeared in synchrony with phrenic activity in response to both chemoreceptor stimuli. Cholinergic blockade eliminated these oscillations and significantly reduced the hypercapnic and hypoxic responses of RL, Rti, and Raw. These data demonstrate for the first time that hypercapnia and hypoxia elicit a cholinergically mediated increase in Rti which, just like the airway component of RL, is modulated by inspiratory neural output and is present during early development. Such coordination in neural function throughout the respiratory system may serve to optimize gas exchange during early postnatal life. Topics: Airway Resistance; Animals; Animals, Newborn; Atropine Derivatives; Blood Gas Analysis; Female; Hypercapnia; Hypoxia; Lung; Male; Parasympatholytics; Phrenic Nerve; Pulmonary Gas Exchange; Swine	1995

Article

Year

Central and peripheral mechanisms underlying gastric distention inhibitory reflex responses in hypercapnic-acidotic rats.

American journal of physiology. Heart and circulatory physiology, 2011, Volume: 300, Issue:3

We have observed that in chloralose-anesthetized animals, gastric distension (GD) typically increases blood pressure (BP) under normoxic normocapnic conditions. However, we recently noted repeatable decreases in BP and heart rate (HR) in hypercapnic-acidotic rats in response to GD. The neural pathways, central processing, and autonomic effector mechanisms involved in this cardiovascular reflex response are unknown. We hypothesized that GD-induced decrease in BP and HR reflex responses are mediated during both withdrawal of sympathetic tone and increased parasympathetic activity, involving the rostral (rVLM) and caudal ventrolateral medulla (cVLM) and the nucleus ambiguus (NA). Rats anesthetized with ketamine and xylazine or α-chloralose were ventilated and monitored for HR and BP changes. The extent of cardiovascular inhibition was related to the extent of hypercapnia and acidosis. Repeated GD with both anesthetics induced consistent falls in BP and HR. The hemodynamic inhibitory response was reduced after blockade of the celiac ganglia or the intraabdominal vagal nerves with lidocaine, suggesting that the decreased BP and HR responses were mediated by both sympathetic and parasympathetic afferents. Blockade of the NA decreased the bradycardia response. Microinjection of kainic acid into the cVLM reduced the inhibitory BP response, whereas depolarization blockade of the rVLM decreased both BP and HR inhibitory responses. Blockade of GABA(A) receptors in the rVLM also reduced the BP and HR reflex responses. Atropine methyl bromide completely blocked the reflex bradycardia, and atenolol blocked the negative chronotropic response. Finally, α(1)-adrenergic blockade with prazosin reversed the depressor. Thus, in the setting of hypercapnic-acidosis, a sympathoinhibitory cardiovascular response is mediated, in part, by splanchnic nerves and is processed through the rVLM and cVLM. Additionally, a vagal excitatory reflex, which involves the NA, facilitates the GD-induced decreases in BP and HR responses. Efferent chronotropic responses involve both increased parasympathetic and reduced sympathetic activity, whereas the decrease in BP is mediated by reduced α-adrenergic tone.

Topics: Acidosis; Adrenergic alpha-1 Receptor Antagonists; Anesthetics; Animals; Atenolol; Atropine Derivatives; Blood Pressure; Bradycardia; Gastric Dilatation; Heart Rate; Hypercapnia; Kainic Acid; Male; Medulla Oblongata; Parasympathetic Nervous System; Parasympatholytics; Prazosin; Rats; Rats, Sprague-Dawley; Receptors, GABA-A; Reflex; Sympathetic Nervous System; Sympatholytics

2011

Neurochemical control of tissue resistance in piglets.

Journal of applied physiology (Bethesda, Md. : 1985), 1995, Volume: 79, Issue:3

Lung resistance may be influenced by chemoreceptor activity and modulated by inspiratory neural output; however, it is unknown whether the contractile elements of lung tissue participate in these changes during early development. In anesthetized paralyzed open-chest piglets, we measured phrenic electroneurogram, lung resistance (RL), and tissue resistance utilizing alveolar capsules to partition the hypercapnic and hypoxic responses of RL into tissue (Rti) and airway resistance (Raw) components. Inhalation of 7% CO2 significantly increased RL (7.4 +/- 0.5 to 11.3 +/- 0.6 cmH2O.l-1.s), Rti (5.2 +/- 0.5 to 6.9 +/- 0.5 cmH2O.l-1.s), and Raw (2.2 +/- 0.2 to 4.4 +/- 0.4 cmH2O.l-1.s). Inhalation of 12% O2 caused more modest increases in RL, Rti, and Raw. Oscillations in tracheal and alveolar pressures appeared in synchrony with phrenic activity in response to both chemoreceptor stimuli. Cholinergic blockade eliminated these oscillations and significantly reduced the hypercapnic and hypoxic responses of RL, Rti, and Raw. These data demonstrate for the first time that hypercapnia and hypoxia elicit a cholinergically mediated increase in Rti which, just like the airway component of RL, is modulated by inspiratory neural output and is present during early development. Such coordination in neural function throughout the respiratory system may serve to optimize gas exchange during early postnatal life.

Topics: Airway Resistance; Animals; Animals, Newborn; Atropine Derivatives; Blood Gas Analysis; Female; Hypercapnia; Hypoxia; Lung; Male; Parasympatholytics; Phrenic Nerve; Pulmonary Gas Exchange; Swine

1995