M. Roger Fedde

Cardiorespiratory impact of the nitric oxide synthase inhibitor L-NAME in the exercising horse.

To investigate the role of nitric oxide, NO, in facilitating cardiorespiratory function during exercise, five horses ran on a treadmill at speeds that yielded 50, 80 and 100% of peak pulmonary oxygen uptake (V(O(2)) peak) as determined on a maximal incremental test. Each horse underwent one control (C) and one (NO-synthase inhibitor; N(G)-L-nitro-arginine methyl ester (L-NAME), 20 mg/kg) trial in randomized order. Pulmonary gas exchange (open flow system), arterial and mixed-venous blood gases, cardiac output (Fick Principle), and pulmonary and systemic conductances were determined. L-NAME reduced exercise tolerance, as well as cardiac output (C, 291+/-34; L-NAME, 246+/-38 L/min), body O(2) delivery (C, 74.4+/-5. 5; L-NAME, 62.1+/-5.6 L/min), and both pulmonary (C, 3.07+/-0.26; L-NAME, 2.84+/-0.35 L/min per mmHg) and systemic (C, 1.55+/-0.24; L-NAME, 1.17+/-0.16 L/min per mmHg) effective vascular conductances at peak running speeds (all P<0.05). On the 50 and 80% trials, L-NAME increased O(2) extraction, which compensated for the reduced body O(2) delivery and prevented a fall in V(O(2)). However, at peak running speed in the L-NAME trial, an elevated O(2) extraction (P<0. 05) was not sufficient to prevent V(O(2)) from falling consequent to the reduced O(2) delivery. At the 50 and 80% running speeds (as for peak), L-NAME reduced pulmonary and systemic effective conductances. These data demonstrate that the NO synthase inhibitor, L-NAME, induces a profound hemodynamic impairment at submaximal and peak running speeds in the horse thereby unveiling a potentially crucial role for NO in mediating endothelial function during exercise.

Ventilatory response to CO2 in birds. I. Measurements in the unanesthetized duck.

Ventilation and blood gases were measured in unanesthetized ducks at various levels of inspired CO2 partial pressure (PICO2). Ventilation was markedly augmented with increasing PICO2, whereas arterial and mixed venous PCO2 stayed essentially constant up to a PICO2 of about 20 torr and changed only slightly between that and the highest level tested (34 torr). After carbonic anhydrase had been blocked, blood PCO2 was elevated at all levels of PICO2 but the ventilatory response to increases in PICO2 were attenuated. The response to CO2 in the normal bird (before administration of acetazolamide) shows similarities to that in mammals. Qualitative differences between both classes of vertebrates after blockade of carbonic anhydrase may, however, suggest differences in their systems that control ventilation.

Microanatomy of the lung parenchyma of a tegu lizard Tupinambis nigropunctatus

The combined techniques of light microscopy, scanning (SEM) and transmission (TEM) electron microscopy were used for the first time to study the structure of unicameral lungs of a Tegu lizard (Tupinambis nigropunctatus). The lungs are prolate spheroid bags with blood supplied by superficial branches of a dorsal pulmonary artery and returned by diffuse, more deeply located veins. The primary bronchus enters the medial aspect near the apex of the lung. The lung wall is composed of trabeculae: (1) arranged in a faviform pattern, (2) forming individual faveoli (gas exchange chambers) which appear deepest in the cranial one‐half of the lung, (3) all of which have a smooth muscle core overlain by either a ciliated or nonciliated epithelium. A ciliated epithelium lines the luminal surfaces of the large primary trabeculae and parts of smaller secondary trabeculae; it is composed of cone‐shaped cells with ciliated‐microvillous surfaces, and of columnar serous secreting cells. Nonciliated epithelium covers the luminal surface of portions of some secondary trabeculae, abluminal surfaces of primary and secondary trabeculae and all surfaces of the small tertiary trabeculae forming the faveoli. The nonciliated epithelium overlies an extensive superficial capillary network. The blood‐gas barrier (0.7‐1.0 μm thick) is composed of a thin cytoplasmic flange of Type I pneumonocytes, a thick homogeneous basal lamina and an attenuated endothelial cytoplasm. Numerous surfactant‐producing Type II pneumonocytes are closely associated with the Type I pneumonocytes. The nonrespiratory ciliated epithelium may function in humidification of air and clearing of the lungs.

O2 Transport in the Horse During Rest and Exercise

We studied mechanisms of O2 transport in 6 adult (2-5 year old) horses at rest and during steady-state exercise on a treadmill (0% slope) at 12 m/s (a submaximal gallop). Oxygen consumption was measured using an open-flow system. Arterial and mixed venous blood samples were simultaneously obtained for measurement of O2 content and hemoglobin concentration. VO2 increased from 1.5 +/- 0.2 L/min at rest to 46.2 +/- 4.8 L/min during exercise. HR increased from a resting value of 36.9 +/- 2.5 bpm to 196.5 +/- 10.9 bpm and the arterio-venous O2 content difference (a-v O2) increased from 4.2 +/- 0.8 ml O2/100 ml blood to 20.3 +/- 1.6 ml O2/100 ml blood. The 30.4-fold increase in oxygen consumption in the horse at submaximal VO2 versus only a 10-fold increase in man at VO2 max demonstrates the marked ability of the horse to transfer O2 at each step in the O2 transport pathway.

Cardiopulmonary responses of burrowing owls (Athene cunicularia) to acute hypercapnia and hypoxia

Abstract While breathing air, burrowing owls had heart rates and blood gases similar to those of other birds, but had lower blood pressures and higher plasma bicarbonate concentrations. Heart rate, blood pressure, and bicarbonate levels of burrowing owls did not change significantly with inspired CO 2 . However, owls inhaling gases with a P I CO 2 > 20 Torr had significantly elevated PaCO 2 and PaO 2 and were acidotic. Plasma bicarbonate concentration of burrowing owls declined significantly at P, O 2 2 and PaCO 2 declined during hypoxia and birds became alkalotic. The normal in vivo buffer line of burrowing owls represents a buffering capacity (31.5 mMol/l/pH unit) exceeding that of most birds, except divers. The cardiopulmonary responses of burrowing owls to hypercapnia and hypoxia are like those of non-burrow dwellers.