Chemical modulation of in situ intrinsic cardiac neurones influences myocardial blood flow in the anaesthetised dog

Objective: The aim was to determine whether modulation of intrinsic cardiac neurones influences the distribution of myocardial blood flow in canine anaesthetised open chest experimental preparations. Methods: Intrinsic cardiac neurones were modified by locally applied nicotine (100 μg) or bradykinin...

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Published in:Cardiovascular research 1994-09, Vol.28 (9), p.1403-1406
Main Authors: Kingma, John G, Armour, J Andrew, Rouleau, Jacques R
Format: Article
Language:English
Subjects:
Animals
Biological and medical sciences
bradykinin
Bradykinin - pharmacology
Cardiovascular system
coronary blood flow
Coronary Circulation - drug effects
Dogs
Female
Heart - innervation
intrinsic cardiac neurones
Investigative techniques of hemodynamics
Investigative techniques, diagnostic techniques (general aspects)
Male
Medical sciences
Neurons - drug effects
nicotine
Nicotine - pharmacology
Oxygen Consumption - drug effects
parasympathetic nervous system
Regional Blood Flow - drug effects
sympathetic nervous system
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Summary:Objective: The aim was to determine whether modulation of intrinsic cardiac neurones influences the distribution of myocardial blood flow in canine anaesthetised open chest experimental preparations. Methods: Intrinsic cardiac neurones were modified by locally applied nicotine (100 μg) or bradykinin (50 μg) while changes were recorded in cardiac haemodynamics and myocardial blood flow (radiolabeled microspheres). Right and left ventricular intramyocardial tissue pressures were measured with high fidelity microtip transducers. Results: Control injections of saline (vehicle; 0.1 ml) into active loci did not produce cardiovascular responses. Nicotine modulation of intrinsic cardiac neurones did not change coronary artery conductance, but total myocardial blood flow [116(SEM 17) v 532(97) ml·mirr−1·100 g−1; p = 0.001 v baseline] and oxygen consumption [7.92(1.10) v 20.14(1.86) ml·min−1·100 g−1; p = 0.001] increased in direct relation to heart rate-blood pressure product changes. Locally administered bradykinin increased coronary artery conductance [2.62(0.39) v 4.71(1.07) ml·min−1·100 g·mm Hg−1], total myocardial blood flow, to 263(72) ml·min−1·100 g−1, and oxygen consumption, to 14.9(4.4) ml·min−1100 g−1; however, heart rate-blood pressure product did not change. Conclusions: These results support earlier findings that intrinsic neurones are involved in cardiac regulation. Furthermore, modification of intrinsic cardiac neurones by nicotine or bradykinin significantly alters the distribution of myocardial blood flow, possibly because of increased myocardial metabolism. Cardiovascular Research 1994;28:1403-1406
ISSN:0008-6363
1755-3245
DOI:10.1093/cvr/28.9.1403