L.H. Opie scite author profile

Measurements of flow resistance of various components of the respiratory system were measured in adult male subjects in the sitting position. Nasal resistance is the largest single component being nearly one-half the total and two-thirds of the airway resistance during nose breathing. It is highly nonlinear, and shows much variability. During mouth breathing upper airway resistance (mouth, pharynx, glottis, larynx and upper trachea) is also markedly nonlinear, and accounts for one-third the total airway resistance. Lower airway resistance is approximately linear up to flows of 2 liters/sec. Pulmonary tissue resistance is low as reported in this study. Chest wall resistance is nearly linear up to flow rates of 2 liters/sec and accounts for slightly less than half the total respiratory resistance during mouth breathing and 10–19% during nasal breathing. larynx; airways; chest wall; nose Submitted on December 16, 1963

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Proposed Metabolic Vicious Circle in Patients With Large Myocardial Infarcts and High Plasma-Free-Fatty-Acid Concentrations

Opie

Tansey

Kennelly

1977

The Lancet

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Perinatal Changes in Glycolytic Function in Response to Hypoxia in the Incubated or Perfused Rat Heart

Hoerter

Opie²

1978

Neonatology

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Glycolysis was assessed in the rat heart during the perinatal period: in the fetus of 16.5 days postcoitum (dpc) and 21.5 dpc (term = 22 dpc) and in the newborn of 1 day postpartum (dpp) and 7 dpp. Glucose uptake, lactate production and glucose incorporation into glycogen were much higher in the fetal than in the newborn heart. Measurements were made of tissue contents of high energy phosphate compounds, lactate and hexose phosphates. Unchanged contents of glucose-6-phosphate and fructose-6-phosphate during hypoxia in spite of an increased flux through the enzyme phosphofructokinase (PFK) suggest that PFK has a regulatory role in the glycolysis as early as 16.5 dpc. The isolated fetal heart was more resistant to hypoxia than the newborn heart: glucose uptake and lactate production were much higher and high energy phosphate compounds and glycogen were better maintained in the fetal heart.

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Glucose and the metabolism of ischaemic myocardium

Opie¹

1995

The Lancet

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L.H. Opie

Partitioning of respiratory flow resistance in man

Proposed Metabolic Vicious Circle in Patients With Large Myocardial Infarcts and High Plasma-Free-Fatty-Acid Concentrations

Perinatal Changes in Glycolytic Function in Response to Hypoxia in the Incubated or Perfused Rat Heart

Glucose and the metabolism of ischaemic myocardium

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