BIOMAT Database Logo BIOMAT Database Logo

Biometric approximation of diaphragmatic contractility during sustained hyperpnea. 2011

Hans-Joachim Kabitz, and David Johannes Walker, and Anja Schwoerer, and Daniel Schlager, and Stephan Walterspacher, and Jan Hendrik Storre, and Kai Roecker, and Wolfram Windisch, and Samuel Vergès, and Christina M Spengler
Department of Pneumology, University Hospital Freiburg, Killianstrasse 5 D, 79106, Germany. hans-joachim.kabitz@uniklinik-freiburg.de

Imposing load on respiratory muscles results in a loss of diaphragmatic contractility that develops early, is independent of task failure, and levels off following the initial decrease. This study assessed the progression of diaphragmatic contractility during sustained normocapnic hyperpnea and applied a biometric approximation (hypothesis: non-linear decay). Ten healthy subjects performed three consecutive hyperpnea bouts (I:6 min warm up/II:9 min/III:task failure 28.6 ± 11.5 min; mean ± SD) at maximal voluntary ventilation fractions (I:30-60%/II:70%/III:70%), followed by recovery periods (I:18 min/II:6 min/III:30 min). Twitch transdiaphragmatic pressure (TwPdi) was assessed throughout the protocol. Bouts II and III induced diaphragmatic fatigue (TwPdi baseline vs. Recovery -19 ± 17% and -30 ± 16%, both p < 0.05 RM-ANOVA) while bout I did not. During sustained hyperpnea (II/III), TwPdi followed an exponential decay (r(2) = 0.91). The reduction in diaphragmatic contractility closely follows a non-linear function with an early loss in diaphragmatic contractility during sustained hyperpnea, levels off thereafter, and is independent of task failure. Thus, reasons other than diaphragmatic fatigue are likely to be responsible for task failure during sustained hyperpnea.

UI MeSH Term Description Entries
D006985 Hyperventilation A pulmonary ventilation rate faster than is metabolically necessary for the exchange of gases. It is the result of an increased frequency of breathing, an increased tidal volume, or a combination of both. It causes an excess intake of oxygen and the blowing off of carbon dioxide. Hyperventilations
D008297 Male Males
D009119 Muscle Contraction A process leading to shortening and/or development of tension in muscle tissue. Muscle contraction occurs by a sliding filament mechanism whereby actin filaments slide inward among the myosin filaments. Inotropism,Muscular Contraction,Contraction, Muscle,Contraction, Muscular,Contractions, Muscle,Contractions, Muscular,Inotropisms,Muscle Contractions,Muscular Contractions
D010101 Oxygen Consumption The rate at which oxygen is used by a tissue; microliters of oxygen STPD used per milligram of tissue per hour; the rate at which oxygen enters the blood from alveolar gas, equal in the steady state to the consumption of oxygen by tissue metabolism throughout the body. (Stedman, 25th ed, p346) Consumption, Oxygen,Consumptions, Oxygen,Oxygen Consumptions
D003964 Diaphragm The musculofibrous partition that separates the THORACIC CAVITY from the ABDOMINAL CAVITY. Contraction of the diaphragm increases the volume of the thoracic cavity aiding INHALATION. Respiratory Diaphragm,Diaphragm, Respiratory,Diaphragms,Diaphragms, Respiratory,Respiratory Diaphragms
D006801 Humans Members of the species Homo sapiens. Homo sapiens,Man (Taxonomy),Human,Man, Modern,Modern Man
D000328 Adult A person having attained full growth or maturity. Adults are of 19 through 44 years of age. For a person between 19 and 24 years of age, YOUNG ADULT is available. Adults
D001699 Biometry The use of statistical and mathematical methods to analyze biological observations and phenomena. Biometric Analysis,Biometrics,Analyses, Biometric,Analysis, Biometric,Biometric Analyses
D013997 Time Factors Elements of limited time intervals, contributing to particular results or situations. Time Series,Factor, Time,Time Factor
D015656 Respiratory Mechanics The physical or mechanical action of the LUNGS; DIAPHRAGM; RIBS; and CHEST WALL during respiration. It includes airflow, lung volume, neural and reflex controls, mechanoreceptors, breathing patterns, etc. Breathing Mechanics,Breathing Mechanic,Mechanic, Breathing,Mechanic, Respiratory,Mechanics, Breathing,Mechanics, Respiratory,Respiratory Mechanic

Related Publications

Hans-Joachim Kabitz, and David Johannes Walker, and Anja Schwoerer, and Daniel Schlager, and Stephan Walterspacher, and Jan Hendrik Storre, and Kai Roecker, and Wolfram Windisch, and Samuel Vergès, and Christina M Spengler
Diaphragmatic fatigue following voluntary hyperpnea.
July 1996, American journal of respiratory and critical care medicine,
Hans-Joachim Kabitz, and David Johannes Walker, and Anja Schwoerer, and Daniel Schlager, and Stephan Walterspacher, and Jan Hendrik Storre, and Kai Roecker, and Wolfram Windisch, and Samuel Vergès, and Christina M Spengler
Aminophylline improves diaphragmatic contractility.
July 1981, The New England journal of medicine,
Hans-Joachim Kabitz, and David Johannes Walker, and Anja Schwoerer, and Daniel Schlager, and Stephan Walterspacher, and Jan Hendrik Storre, and Kai Roecker, and Wolfram Windisch, and Samuel Vergès, and Christina M Spengler
Is diaphragmatic contractility important?
July 1981, The New England journal of medicine,
Hans-Joachim Kabitz, and David Johannes Walker, and Anja Schwoerer, and Daniel Schlager, and Stephan Walterspacher, and Jan Hendrik Storre, and Kai Roecker, and Wolfram Windisch, and Samuel Vergès, and Christina M Spengler
Hypophosphatemia and diaphragmatic contractility.
February 1986, The New England journal of medicine,
Hans-Joachim Kabitz, and David Johannes Walker, and Anja Schwoerer, and Daniel Schlager, and Stephan Walterspacher, and Jan Hendrik Storre, and Kai Roecker, and Wolfram Windisch, and Samuel Vergès, and Christina M Spengler
Aminophylline improves diaphragmatic contractility.
November 1981, The New England journal of medicine,
Hans-Joachim Kabitz, and David Johannes Walker, and Anja Schwoerer, and Daniel Schlager, and Stephan Walterspacher, and Jan Hendrik Storre, and Kai Roecker, and Wolfram Windisch, and Samuel Vergès, and Christina M Spengler
The assessment of diaphragmatic contractility.
March 1985, Anesthesiology,
Hans-Joachim Kabitz, and David Johannes Walker, and Anja Schwoerer, and Daniel Schlager, and Stephan Walterspacher, and Jan Hendrik Storre, and Kai Roecker, and Wolfram Windisch, and Samuel Vergès, and Christina M Spengler
Bracing arms increases the capacity for sustained hyperpnea.
July 1988, The American review of respiratory disease,
Hans-Joachim Kabitz, and David Johannes Walker, and Anja Schwoerer, and Daniel Schlager, and Stephan Walterspacher, and Jan Hendrik Storre, and Kai Roecker, and Wolfram Windisch, and Samuel Vergès, and Christina M Spengler
Preferential diaphragmatic weakness during sustained Pseudomonas aeruginosa lung infection.
March 2004, American journal of respiratory and critical care medicine,
Hans-Joachim Kabitz, and David Johannes Walker, and Anja Schwoerer, and Daniel Schlager, and Stephan Walterspacher, and Jan Hendrik Storre, and Kai Roecker, and Wolfram Windisch, and Samuel Vergès, and Christina M Spengler
Ventilatory muscle training and the oxygen cost of sustained hyperpnea.
December 1978, Journal of applied physiology: respiratory, environmental and exercise physiology,
Hans-Joachim Kabitz, and David Johannes Walker, and Anja Schwoerer, and Daniel Schlager, and Stephan Walterspacher, and Jan Hendrik Storre, and Kai Roecker, and Wolfram Windisch, and Samuel Vergès, and Christina M Spengler
Propofol decreases diaphragmatic contractility in dogs.
December 1999, Anesthesia and analgesia,
Copied contents to your clipboard!