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Steady-state diffusing capacity for carbon monoxide in the rat

Turek, Z. ; Frans, A. ; Kreuzer, F.

Amsterdam : Elsevier

Respiration Physiology 12 (1971), S. 346-360

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ISSN: 0034-5687

Keywords: Alveolar ventilation ; Carbon monoxide ; Hypoxia ; Lung diffusing capacity

Source: Elsevier Journal Backfiles on ScienceDirect 1907 - 2002

Topics: Medicine

Type of Medium: Electronic Resource

URL: http://linkinghub.elsevier.com/retrieve/pii/0034-5687(71)90075-2

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Blood gases at several levels of oxygenation in rats with a left-shifted blood oxygen dissociation curve (1978)

Turek, Z. ; Kreuzer, F. ; Ringnalda, B. E. M.

Springer

Pflügers Archiv 376 (1978), S. 7-13

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ISSN: 1432-2013

Keywords: Oxygen dissociation curve ; Oxygen transport ; Blood gases ; Hypoxia ; Rat

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Theoretical deductions have shown that a shift of the blood O2 dissociation curve (ODC) to the right might improve O2 transport to tissues at normoxia and at mild hypoxia whereas at severe hypoxia the organism should be better off with an ODC shifted to the left (Turek et al., 1973b; Turek and Kreuzer, 1976). The present study was performed in order to ascertain this ambiguous effect of an ODC shift depending on the degree of hypoxia in intact animals. A major displacement of the ODC to the left was achieved in rats by chronic administration of sodium cyanate (NaOCN). Control animals received sodium chloride (NaCl) instead. Arterial and mixed-venous $$P_{{\text{O}}_{\text{2}} }$$ , $$P_{{\text{CO}}_{\text{2}} }$$ , and pH were measured at normoxia and during breathing 14.9, 8.0, or 5.6% O2 in N2 in both groups. From $$P_{{\text{O}}_{\text{2}} }$$ , pH, ODC and arterial hematocrit, arterial and mixed-venous O2 contents were estimated and $$({\text{a}} - {\text{v)}}_{{\text{O}}_{\text{2}} }$$ as an index of blood O2 extraction was obtained. At normoxia and during breathing 14.9% O2 the NaOCN rats had a lower mixed-venous $$P_{{\text{O}}_{\text{2}} }$$ than the NaCl rats without any difference in pH. Arterio-venous O2 difference did not differ at normoxia but was lower in NaOCN rats at 14.9% O2. However, at 8.0 and 5.6% O2 the NaOCN rats had a higher mixed-venous $$P_{{\text{O}}_{\text{2}} }$$ , an increased $$({\text{a}} - {\text{v)}}_{{\text{O}}_{\text{2}} }$$ , and a higher pH (arterial and mixed-venous). At 5.6% O2 the NaCl rats developed a severe acidosis concomitant with pronounced hypocapnia. These findings confirm that rats with a left-shifted ODC have an impaired O2 transport to tissues at normoxia and mild hypoxia but a more efficient O2 transport at severe hypoxia as compared with rats with an unshifted ODC, in agreement with our previous theoretical studies.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00585241

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Blood O2 content, cardiac output, and flow to organs at several levels of oxygenation in rats with a left-shifted blood oxygen dissociation curve (1978)

Turek, Z. ; Kreuzer, F. ; Turek-Maischeider, M. ; [et al.]

Springer

Pflügers Archiv 376 (1978), S. 201-207

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ISSN: 1432-2013

Keywords: Oxygen dissociation curve ; Oxygen transport ; Cardiac output ; Coronary blood flow ; Blood flow to organs ; Hypoxia ; Rat

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract A major displacement of the blood O2 dissociation curve (ODC) was achieved in rats by chronic administration of sodium cyanate (NaOCN). Control animals with a normal position of the ODC received NaCl instead. Arterial and mixed-venous O2 content ( $${\text{C}}_{{\text{O}}_{\text{2}} }$$ ) and O2 consumption were measured during breathing room air, 14.9, 8.0, or 5.6% O2 in N2. Cardiac output was obtained by the Fick principle.86RbCl was administered i.v., the rats were killed and the activity of86Rb in heart, spleen, stomach and intestines, liver, kidney, skeletal muscle, and skin was measured. According to Sapirstein (1956, 1958) the fractional uptake of86Rb in these organs corresponds to the fractions of cardiac output supplying these organs, and from the fractional uptake and cardiac output the nutritional blood flow may be calculated. Arterial and mixed-venous $${\text{C}}_{{\text{O}}_{\text{2}} }$$ was larger in the NaOCN than in the NaCl rats at all levels of oxygenation. At normoxia and 14.9% O2 the venous $${\text{C}}_{{\text{O}}_{\text{2}} }$$ was enlarged more than the arterial one, and so the arterio-venous O2 difference [ $$\left( {{\text{a}} - {\text{v}}} \right)_{{\text{O}}_{\text{2}} }$$ ] as an index of the O2 extraction in the body was smaller in the rats with a left-shifted ODC. However, at more severe hypoxia (8.0 and 5.6% O2) the arterial $${\text{C}}_{{\text{O}}_{\text{2}} }$$ in the NaOCN rats was enlarged more than the mixed-venous one, resulting in a larger $$\left( {{\text{a}} - {\text{v}}} \right)_{{\text{O}}_{\text{2}} }$$ (and therefore O2 extraction) when compared with the NaCl animals. Cardiac output was larger in the NaOCN than in the NaCl rats at 14.9 and 5.6% O2, when expressed per kg body weight. At 14.9% O2 the augmented cardiac output compensated for the lower O2 extraction when compared with the NaCl animals. At 5.6% O2 the NaOCN rats had both a larger ( $$\left( {{\text{a}} - {\text{v}}} \right)_{{\text{O}}_{\text{2}} }$$ ) and cardiac output than the NaCl animals. In the NaCl rats the decreased O2 extraction was not compensated for by an augmented cardiac output and therefore their O2 consumption was not only lower than that of the NaOCN rats but decreased even below the normoxic value of the NaCl rats. Coronary blood flow was increased in both NaOCN and NaCl animals at deep hypoxia to about the same extent, but due to a much lower arterial $${\text{C}}_{{\text{O}}_{\text{2}} }$$ of the NaCl animals, their O2 supply to the heart was lower than that of the NaOCN rats. The nutritional blood flow to spleen, kidney, liver, stomach and intestines, and skin in ml/min · g was lower in the rats with a normal position of the ODC than in those with a left-shifted ODC. This, together with the low arterial $${\text{C}}_{{\text{O}}_{\text{2}} }$$ of the NaCl rats, suggests a serious compromising of the O2 supply to these organs. Results of this study support the conclusion of our theoretical studies (Turek et al., 1973; Turek and Kreuzer, 1976) that a shift of the ODC to the left might be disadvantageous for the O2 transport to tissues at mild hypoxia, but advantageous at severe hypoxia.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00584951

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Advantage or disadvantage of a decrease of blood oxygen affinity for tissue oxygen supply at hypoxia (1973)

Turek, Z. ; Kreuzer, F. ; Hoofd, L. J. C.

Springer

Pflügers Archiv 342 (1973), S. 185-197

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ISSN: 1432-2013

Keywords: Oxygen Dissociation Curve ; Tissue Oxygen Supply ; Mixed Venous Oxygen Pressure ; Hypoxia ; Man and Rat

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary A shift of the oxygen dissociation curve to the right is often interpreted as an adaptation to hypoxia favorable for tissue oxygen supply. However, animals native to high altitude tend to show a rather high oxygen affinity. In order to elucidate this apparent discrepancy we investigated by numerical computer studies 1. the effect of a shift of the dissociation curve to the right as reflected in the mixed venous oxygen pressure, and 2. the role of this displacement in pulmonary gas exchange with particular reference to the alveolar-arterial oxygen pressure difference and the pulmonary diffusing capacity for oxygen. A right shift had a favorable effect only in the range of moderate hypoxia (and of normoxia) whereas there was a detrimental effect with severe hypoxia. The most important criterion for this distinction was the direction of the change in steepness of the physiological dissociation curve (straight line between arterial and venous points). A favorable effect was associated with a steeper slope after the shift, an unfavorable effect with a less steep slope. There was only a minor influence of a right shift on the oxygen diffusion gradient in the lung. Comparison between man (higher affinity) and rat (lower affinity) suggests that animals of small size with high metabolic rate (high arteriovenous oxygen difference) living in normoxic or possibly exposed to moderately hypoxic condition only are better served by a relatively low oxygen affinity whereas animals native to high altitude are better adapted to severe hypoxia when having a high oxygen affinity.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00591367

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