Probable strain differences of rats in susceptibilities and cardiopulmonary responses to chronic hypoxia

A Novel Rat Model of Mild Pulmonary Hypertension Associated with Pulmonary Venous Congestion Induced by Left Pulmonary Vein Banding

Pulmonary hypertension (PH) associated with left heart disease (PH-LHD) is the most common form of PH. In PH-LHD, changes in the pulmonary vasculature are assumed to be mainly caused by pulmonary venous congestion. However, the underlying mechanisms of this form of PH are poorly understood. We aimed to establish a model of PH associated with pulmonary venous congestion. Wistar-Kyoto rats underwent partial occlusion of the left pulmonary vein to induce pulmonary venous congestion or sham surgery and were assessed at various time points post-surgery (3, 6, 9, 12 weeks). In vivo cardiopulmonary phenotyping was performed by using echocardiography along with heart catheterization. Histomorphometry methods were used to assess pulmonary vascular remodeling (e.g., wall thickness, degree of muscularization). Left pulmonary vein banding (PVB) resulted in mildly elevated right ventricular systolic pressure and moderate right ventricular hypertrophy. In PVB rats, small- and medium-sized pulmonary vessels in the left lung were characterized by increased wall thickness and muscularization. Taken together, our data demonstrate that left PVB-induced pulmonary venous congestion is associated with pulmonary vascular remodeling and mild PH.

Influence of chronic hypoxia on the hypoxic ventilatory response of juvenile and adult rats

Chronic hypoxia (CH) from birth attenuates the acute hypoxic ventilatory response (HVR) in rats and other mammals, but CH is often reported to augment the HVR in adult mammals. To test the hypothesis that this transition - from blunting to augmenting the HVR - occurs in the third or fourth postnatal week in rats, juvenile and adult rats were exposed to normobaric CH (12% O2) for 7 days and the HVR was assessed by whole-body plethysmography. No transition was observed, however, and the acute HVR was reduced by 61 - 85% across all ages studied. The failure to observe an augmented HVR in adult rats could not be explained by the substrain of Sprague Dawley rats used, the duration of the CH exposure, the order in which test gases were presented, the level of hypoxia used for CH and to assess the HVR, or the effects of CH on the metabolic response to hypoxia and the hypercapnic ventilatory response. A literature survey revealed several distinct patterns of ventilatory acclimatization to hypoxia (VAH) in adult rats, with most studies (77%) revealing a decrease or no change in the acute HVR after CH. In conclusion, the effects of CH on respiratory control are qualitatively similar across age groups, at least within the populations of Sprague Dawley rats used in the present study, and there does not appear to be one "typical" pattern for VAH in adult rats.

Distinct cardiovascular and respiratory responses to short-term sustained hypoxia in juvenile Sprague Dawley and Wistar Hannover rats

Short-term sustained hypoxia (SH) elicits active expiration, augmented late-expiratory (late-E) sympathetic activity, increased arterial pressure and ventilation, and amplified sympathetic and abdominal expiratory responses to chemoreflex activation in rats of the Wistar-Ribeirão Preto (WRP) strain. Herein, we investigated whether SH can differentially affect the cardiovascular and respiratory outcomes of Sprague-Dawley (SD) and Wistar Hannover (WH) rats and compared the results with previous data using WRP rats. For this, we exposed SD and WH rats to SH (FiO₂ = 0.1) for 24 h and evaluated arterial pressure, sympathetic activity, and respiratory pattern. SD rats presented increased arterial pressure, respiratory rate and tidal volume, as well as augmented late-E expiratory motor output and increased sympathetic outflow due to post-inspiratory and late-E sympathetic overactivity. WH rats presented reduced changes, suggesting lower responsiveness of this strain to this SH protocol. The magnitudes of changes in sympathetic and abdominal expiratory motor activities to chemoreflex activation in SD rats were reduced by SH. Pressor responses to chemoreflex activation were shown to be blunted in SD and WH rats after SH. The data are showing that SD, WH, and WRP rat strains exhibit marked differences in their cardiovascular, autonomic and respiratory responses to 24-h SH and draw attention to the importance of rat strain for studies exploring the underlying mechanisms involved in the neuronal changes induced by the experimental model of SH.

Systemic Oxygen Transport with Rest, Exercise, and Hypoxia: A Comparison of Humans, Rats, and Mice

The objective of this article is to compare and contrast the known characteristics of the systemic O₂ transport of humans, rats, and mice at rest and during exercise in normoxia and hypoxia. This analysis should help understand when rodent O₂ transport findings can-and cannot-be applied to human responses to similar conditions. The O₂ -transport system was analyzed as composed of four linked conductances: ventilation, alveolo-capillary diffusion, circulatory convection, and tissue capillary-cell diffusion. While the mechanisms of O₂ transport are similar in the three species, the quantitative differences are naturally large. There are abundant data on total O₂ consumption and on ventilatory and pulmonary diffusive conductances under resting conditions in the three species; however, there is much less available information on pulmonary gas exchange, circulatory O₂ convection, and tissue O₂ diffusion in mice. The scarcity of data largely derives from the difficulty of obtaining blood samples in these small animals and highlights the need for additional research in this area. In spite of the large quantitative differences in absolute and mass-specific O₂ flux, available evidence indicates that resting alveolar and arterial and venous blood PO₂ values under normoxia are similar in the three species. Additionally, at least in rats, alveolar and arterial blood PO₂ under hypoxia and exercise remain closer to the resting values than those observed in humans. This is achieved by a greater ventilatory response, coupled with a closer value of arterial to alveolar PO₂ , suggesting a greater efficacy of gas exchange in the rats. © 2018 American Physiological Society. Compr Physiol 8:1537-1573, 2018.

Long-Term Chronic Intermittent Hypobaric Hypoxia Induces Glucose Transporter (GLUT4) Translocation Through AMP-Activated Protein Kinase (AMPK) in the Soleus Muscle in Lean Rats

Background: In chronic hypoxia (CH) and short-term chronic intermittent hypoxia (CIH) exposure, glycemia and insulin levels decrease and insulin sensitivity increases, which can be explained by changes in glucose transport at skeletal muscles involving GLUT1, GLUT4, Akt, and AMPK, as well as GLUT4 translocation to cell membranes. However, during long-term CIH, there is no information regarding whether these changes occur similarly or differently than in other types of hypoxia exposure. This study evaluated the levels of AMPK and Akt and the location of GLUT4 in the soleus muscles of lean rats exposed to long-term CIH, CH, and normoxia (NX) and compared the findings.

Methods: Thirty male adult rats were randomly assigned to three groups: a NX (760 Torr) group (n = 10), a CIH group (2 days hypoxia/2 days NX; n = 10) and a CH group (n = 10). Rats were exposed to hypoxia for 30 days in a hypobaric chamber set at 428 Torr (4,600 m). Feeding (10 g daily) and fasting times were accurately controlled. Measurements included food intake (every 4 days), weight, hematocrit, hemoglobin, glycemia, serum insulin (by ELISA), and insulin sensitivity at days 0 and 30. GLUT1, GLUT4, AMPK levels and Akt activation in rat soleus muscles were determined by western blot. GLUT4 translocation was measured with confocal microscopy at day 30.

Results: (1) Weight loss and increases in hematocrit and hemoglobin were found in both hypoxic groups (p < 0.05). (2) A moderate decrease in glycemia and plasma insulin was found. (3) Insulin sensitivity was greater in the CIH group (p < 0.05). (4) There were no changes in GLUT1, GLUT4 levels or in Akt activation. (5) The level of activated AMPK was increased only in the CIH group (p < 0.05). (6) Increased GLUT4 translocation to the plasma membrane of soleus muscle cells was observed in the CIH group (p < 0.05).

Conclusion: In lean rats experiencing long-term CIH, glycemia and insulin levels decrease and insulin sensitivity increases. Interestingly, there is no increase of GLUT1 or GLUT4 levels or in Akt activation. Therefore, cellular regulation of glucose seems to primarily involve GLUT4 translocation to the cell membrane in response to hypoxia-mediated AMPK activation.

Protective effect of total flavonoids of seabuckthorn (Hippophae rhamnoides) in simulated high-altitude polycythemia in rats

Seabuckthorn (Hippophae rhamnoides L.) has been used to treat high altitude diseases. The effects of five-week treatment with total flavonoids of seabuckthorn (35, 70, 140 mg/kg, ig) on cobalt chloride (5.5 mg/kg, ip)- and hypobaric chamber (simulating 5,000 m)-induced high-altitude polycythemia in rats were measured. Total flavonoids decreased red blood cell number, hemoglobin, hematocrit, mean corpuscular hemoglobin levels, span of red blood cell electrophoretic mobility, aggregation index of red blood cell, plasma viscosity, whole blood viscosity, and increased deformation index of red blood cell, erythropoietin level in serum. Total flavonoids increased pH, pO₂, Sp_O2, pCO₂ levels in arterial blood, and increased Na⁺, HCO₃⁻, Cl⁻, but decreased K⁺ concentrations. Total flavonoids increased mean arterial pressure, left ventricular systolic pressure, end-diastolic pressure, maximal rate of rise and decrease, decreased heart rate and protected right ventricle morphology. Changes in hemodynamic, hematologic parameters, and erythropoietin content suggest that administration of total flavonoids from seabuckthorn may be useful in the prevention of high altitude polycythaemia in rats.

Modulatory effects of quercetin on hypobaric hypoxic rats

Quercetin is an active constituent of Hippophae rhamnoides L. and Ginkgo Biloba, which are commonly taken for high altitude sickness. The preventive effect of quercetin on hypobaric hypoxic rats was investigated. Male Wistar rats (180-220 g) were placed into six groups: normoxic group (normal control), a hypoxic group (model control), three quercetin-treated groups (5, 10, 20mg/kg, i.g.), and acetazolamide-treated group (22.5mg/kg, i.g., positive control), 10 animals in each group. Hypoxic rats were raised in a hypobaric hypoxia chamber simulating a high altitude of 5000 m for 23 h per day after a five-day pretreatment. Normoxic control rats were raised at an altitude of 300 m. After the five-day treatment, hemodynamic, arterial blood gas and electrolyte parameters, antioxidants and nitric oxide metabolism were measured. Hypobaric hypoxia enhanced the right ventricular systolic pressure, right ventricular end-diastolic pressure and left ventricular end-diastolic pressure, which were reversed by quercetin. Quercetin increased the declined pH, PO(2), Sp(O2), PCO(2) levels in arterial blood induced by hypobaric hypoxia, and increased Na(+), HCO(3)(-), Cl(-), but decreased K(+) concentrations. Quercetin increased superoxide dismutase, catalase, glutathione peroxidase activities, glutathione levels, and it decreased malondialdehyde levels in serum. Furthermore, quercetin increased nitric oxide levels and inducible nitric oxide synthase activity in serum. Rats failed to gain body weight under hypobaric hypoxia and quercetin had no effect on it. These results suggest that the activities of quercetin on cardiac function, arterial blood gas, antioxidants and nitric oxide metabolism may be related to its protective potential on hypobaric hypoxia-induced damage.

Effects of exposure to a simulated altitude of 5500 m on energy metabolic pathways in rats

We examined the effect of exposure to 5500 m on three closely related metabolic pathways: anaerobic glycolysis, the pentose phosphate shunt (PPS), and fatty acid metabolism. Rats were exposed to simulated altitude of 5500 m for up to 3 months. The maximal rate of lactate production in tissue homogenates, tissue lactic acid dehydrogenase and blood lactate levels were measured to evaluate the capacity for anaerobic glycolysis. The uptake of 14C-1-palmitate, oxidation of 14C-1-palmitate to 14CO2, incorporation of 14C-1-palmitate into tissue lipids, plasma and tissue free fatty acids (FFA) levels and total lipid contents were measured to assess the magnitude of lipid metabolism. Activities of glucose-6-phosphate dehydrogenase (G-6-PD) and 6-phophogluconate dehydrogenase (6-PGD) in the PPS pathway were measured to assess the capacity to generate reducing power. Acute and chronic hypoxia did not affect most of the measurements of anaerobic glycolysis, but depressed lactate production in liver and kidney. Chronic hypoxia enhanced all aspects of lipid metabolism in liver and enhanced the uptake and oxidation to CO2 of palmitate in skeletal muscle. Chronic hypoxia did not alter the activity of the G-6-PD in any tissue studied, but the activity of 6-PGD was depressed in heart, kidney, thymus and adrenal gland. The lack of major changes in the capacities of anaerobic glycolytic pathways and the activities of the PPS dehydrogenases is consistent with the maintenance of normal aerobic metabolism in rats at 5500 m. We found no evidence that anaerobic metabolic processes were upregulated to sustain energy consumption during chronic hypoxia. On the other hand, enhanced fatty acid metabolism may spare carbohydrate for metabolic fuel under conditions of extreme hypoxic limitation.

GREATER HYPERTROPHY IN RIGHT THAN LEFT VENTRICLES IS ASSOCIATED WITH PULMONARY VASCULOPATHY IN SINOAORTIC-DENERVATED WISTAR-KYOTO RATS

1. Biventricular hypertrophy has been described in a high blood pressure variability (BPV) model of sinoaortic-denervated (SAD) rats without systemic hypertension. To explore the possible involvement of the lung in SAD-induced right ventricular hypertrophy (RVH), we examined lung morphology, in addition to systemic haemodynamics and ventricle morphology, in Wistar-Kyoto rats 32 weeks after SAD. 2. In Wistar-Kyoto rats 32 weeks after SAD, there existed a substantial elevation in BPV, with no change in the average level of arterial pressure. Biventricular hypertrophy following SAD was characterized by a greater hypertrophy in right than left ventricles; both absolute and normalized right ventricular weights were significantly increased by 22 and 27%, respectively, and only normalized left ventricular weight was significantly increased by 12%. No infarcts were found in any ventricles examined. 3. In the lung, the most prominent change following SAD was pulmonary vasculopathy, including wall thickening, perivascular fibrosis and cell infiltration. In pulmonary arteries with an internal diameter of 70-130 microm, the external diameter, wall thickness and wall thickness to internal diameter ratio were increased in SAD compared with control rats. 4. There was no correlation between right and left ventricular weights. In contrast with BPV-correlated left ventricular weight, right ventricular weight was correlated with the wall thickness of the pulmonary artery, but not with BPV. 5. These findings suggest that greater RVH following SAD is associated with pulmonary vasculopathy, but is not secondary to the left ventricular problems or high BPV.

Cardiopulmonary Hemodynamics of Blue-Sheep, Pseudois nayaur, as High-Altitude Adapted Mammals

The blue-sheep, pika, and yak live in the Tibetan highlands at an altitude of 6,100 m and are typical mammals adapted to high-altitudes. These animals have a long history of habitation at high-altitudes and are considered to be "animals completely adapted to high-altitudes" because of their physiological and morphological traits that are well adapted to high-altitude environments. To evaluate the physiological characteristics of high-altitude adaptation in the blue-sheep, changes in the pulmonary hemodynamics during exposure to simulated-altitudes at 0, 2,300, and 4,500 m were examined by means of a climatic chamber in Qinghai Province, China (altitude 2,300 m). Seven blue-sheep inhabiting the mountains (3,000 m) of Qinghai Province, China, were compared with 5 pigs raised in the same area as controls. The primary items of measurement were the body weight (BW), systemic arterial pressure (Psa), pulmonary artery pressure (Ppa), hematocrit (Ht), left ventricular weight (LVW), right ventricular weight (RVW), and blood gas profile. The principal findings of this study are: (1) Ht, an index of right ventricular hypertrophy (RVW/LVW), and oxygen consumption (Vdot;O(2)) were significantly lower in the blue sheep compared with the pigs; (2) When the animals were exposed to simulated-altitudes at 0, 2,300, and 4,500 m, Ppa increased significantly in tandem with altitude elevation in both species, but the increases were significantly smaller in the blue-sheep; and (3) Ppa/Psa, an index of the right ventricular load, increased with the altitude in both species, but the increases were smaller in the blue sheep. From these observations, low Ht and RVW/LVW and significant attenuation of hypoxic pulmonary vasoconstriction (HPV) in the blue-sheep is considered to be characteristics of animals completely adapted to high-altitudes, such as the pika.

Targeted disruption of the gene for natriuretic peptide receptor-A worsens hypoxia-induced cardiac hypertrophy

Targeted disruption of the gene for natriuretic peptide receptor-A (NPR-A) worsens pulmonary hypertension and right ventricular hypertrophy during hypoxia, but its effect on left ventricular mass and systemic pressures is not known. We examined the effect of 3 wk of hypobaric hypoxia (0.5 atm) on right and left ventricular pressure and mass in mice with 2 (wild type), 1, or 0 copies of Npr1, the gene that encodes for NPR-A in mice. Under normoxic conditions, right ventricular peak pressure (RVPP) was greater in 0 than in 2 copy mice, but there were no genotype-related differences in carotid artery PP (CAPP). The left ventricular free wall weight-to-body weight (LV/body wt) ratio was greater in 0 than in 2 copy mice and there was a trend toward a greater right ventricular weight-to-body weight (RV/body wt) ratio. Three weeks of hypoxia increased RVPP and RV/body wt in all genotypes. The increase in RVPP was similar in all genotypes (11-14 mmHg), but the hypoxia-induced increase in RV/body wt was more than twice as great in 0 copy mice than in 2 copy mice (1.11 +/- 0.06 to 2.65 +/- 0.46 vs. 0.96 +/- 0.04 to 1.4 +/- 0.09, P < 0.05). Chronic hypoxia had no effect on CAPP in any genotype and did not effect LV/body wt in 1 or 2 copy mice, but increased LV/body wt 41% in 0 copy mice. We conclude that absent expression of NPR-A worsens right ventricular hypertrophy and causes left ventricular hypertrophy during exposure to chronic hypoxia without increasing pulmonary or systemic arterial pressure responses.

The role of endothelin-1 in strain-related susceptibility to develop hypoxic pulmonary hypertension in rats

The Hilltop (H) strain compared to the Madison (M) strain of Sprague-Dawley rats develops severe pulmonary hypertension in response to chronic hypoxia. We tested the hypothesis that endothelin-1 (ET-1) contributes to these strain-related differences. Plasma ET-1 content was not modified by chronic hypoxia in either strain. The lung ET-1 peptide and preproET-1 mRNA content were significantly increased to the same magnitude in both strains at 2 and 3 weeks of hypoxia. The ET(A) receptor mRNA increased more at 3 weeks of hypoxia in the lungs of H rats than in M rats, but not at other time points. The ET(B) receptor mRNA was not modified by hypoxia in either strain. After 3 days of normoxic recovery following 2 weeks of hypoxia, ET-1 protein and mRNA levels decreased to baseline levels in both rat strains. We conclude that ET-1 does not contribute to the development of cardiopulmonary differences between the H and M strains in response to hypoxia.

Phrenic long-term facilitation requires 5-HT receptor activation during but not following episodic hypoxia

Episodic hypoxia evokes a sustained augmentation of respiratory motor output known as long-term facilitation (LTF). Phrenic LTF is prevented by pretreatment with the 5-hydroxytryptamine (5-HT) receptor antagonist ketanserin. We tested the hypothesis that 5-HT receptor activation is necessary for the induction but not maintenance of phrenic LTF. Peak integrated phrenic nerve activity (integralPhr) was monitored for 1 h after three 5-min episodes of isocapnic hypoxia (arterial PO(2) = 40 +/- 2 Torr; 5-min hyperoxic intervals) in four groups of anesthetized, vagotomized, paralyzed, and ventilated Sprague-Dawley rats [1) control (n = 11), 2) ketanserin pretreatment (2 mg/kg iv; n = 7), and ketanserin treatment 0 and 45 min after episodic hypoxia (n = 7 each)]. Ketanserin transiently decreased integralPhr, but it returned to baseline levels within 10 min. One hour after episodic hypoxia, integralPhr was significantly elevated from baseline in control and in the 0- and 45-min posthypoxia ketanserin groups. Conversely, ketanserin pretreatment abolished phrenic LTF. We conclude that 5-HT receptor activation is necessary to initiate (during hypoxia) but not maintain (following hypoxia) phrenic LTF.

EDHF contributes to strain-related differences in pulmonary arterial relaxation in rats

Pulmonary arteries from the Madison (M) strain relax more in response to acetylcholine (ACh) than those from the Hilltop (H) strain of Sprague-Dawley rats. We hypothesized that differences in endothelial nitric oxide (NO) synthase (eNOS) expression and function, metabolism of ACh by cholinesterases, release of prostacyclin, or endothelium-derived hyperpolarizing factor(s) (EDHF) from the endothelium would explain the differences in the relaxation response to ACh in isolated pulmonary arteries. eNOS mRNA and protein levels as well as the NO-dependent relaxation responses to thapsigargin in phenylephrine (10(-6) M)-precontracted pulmonary arteries from the M and H strains were identical. The greater relaxation response to ACh in M compared with H rats was also observed with carbachol, a cholinesterase-resistant analog of ACh, a response that was not modified by pretreatment with meclofenamate (10(-5) M). N(omega)-nitro-L-arginine (10(-4) M) completely abolished carbachol-induced relaxation in H rat pulmonary arteries but not in M rat pulmonary arteries. Precontraction with KCl (20 mM) blunted the relaxation response to carbachol in M rat pulmonary arteries and eliminated differences between the M and H rat pulmonary arteries. NO-independent relaxation present in the M rat pulmonary arteries was significantly reduced by 17-octadecynoic acid (2 microM) and was completely abolished by charybdotoxin plus apamin (100 nM each). These findings suggest that EDHF, but not NO, contributes to the strain-related differences in pulmonary artery reactivity. Also, EDHF may be a metabolite of cytochrome P-450 that activates Ca(2+)-dependent K(+) channels.

Expression of hypoglossal long-term facilitation differs between substrains of Sprague-Dawley rat

Long-term facilitation (LTF) is a prolonged, serotonin-dependent augmentation of respiratory motor output following episodic hypoxia. Previous observations lead us to hypothesize that LTF is subject to genetic influences and, as a result, differs between Sprague-Dawley (SD) rats from two vendors, Harlan (H) and Charles River Laboratories/Sasco (CRL/S). Using a blinded experimental design, we recorded integrated phrenic (integralPhr) and hypoglossal neurograms in anesthetized, vagotomized, paralyzed, and ventilated rats. At 60 min following three 5-min hypoxic episodes (Pa(O(2)) = 40 +/- 1 Torr; 5-min hyperoxic intervals), integralPhr was elevated from baseline in both SD substrains (i.e., LTF; P < 0.05). Conversely, hypoglossal LTF was present in CRL/S but not H rats (P < 0.05 between substrains). Serotonin immunoreactivity within the hypoglossal nucleus was not different between H and CRL/S rats. We conclude that the expression of hypoglossal LTF differs between SD rat substrains, indicating a difference in their genetic predisposition to neural plasticity.

Differences in time-related cardiopulmonary responses to hypoxia in three rat strains

The cardiopulmonary profile of three rat strains (Sprague-Dawley, Wistar and High altitude-sensitive) was compared upon exposure to hypoxia (9% O2) for 0, 7 or 14 days. No differences were observed among the in vitro contractile (ET-1) and relaxant (carbachol) responses of pulmonary artery isolated from the three strains during normoxia. Chronic hypoxia decreased ET-1 contractile responses and diminished relaxant responses to carbachol similarly in all strains. In Sprague-Dawley, Wistar and High altitude-sensitive rats, pulmonary arterial pressure rose time-dependently and was elevated by 108%, 116% and 167%, respectively, after 14 days of hypoxia compared to normoxic controls. Right ventricular hypertrophy was increased by 51%, 93% and 55%, respectively, at 14 days. Hypoxia-induced hypertrophy and medial thickening in the pulmonary vasculature were more pronounced in High altitude-sensitive rats. Sprague-Dawley exhibited hypoxia-induced airway hyperresponsiveness to intravenous methacholine, but there were no hypoxia- or strain-related differences in in vitro tracheal contractility. Although each strain exhibited greater sensitivity for a particular hypoxia-induced parameter, pulmonary vascular functional and structural changes suggest that High altitude-sensitive rats represent a choice model of hypoxia-induced pulmonary hypertension.

Long term facilitation of phrenic motor output

Episodic hypoxia or electrical stimulation of carotid chemoafferent neurons elicits a sustained, serotonin-dependent augmentation of respiratory motor output known as long term facilitation (LTF). The primary objectives of this paper are to provide an updated review of the literature pertaining to LTF, to investigate the influence of selected variables on LTF via meta-analysis of a large data set from LTF experiments on anesthetized rats, and to propose an updated mechanism of LTF. LTF has been demonstrated in anesthetized and awake experimental preparations, and can be evoked in some human subjects during sleep. The mechanism underlying LTF requires episodic chemoafferent stimulation, and is not elicited by similar cumulative durations of sustained hypoxia. Meta-analysis of phrenic nerve responses following episodic hypoxia in 63 experiments on anesthetized rats (conducted by four investigators over a period of several years) indicates that phrenic LTF magnitude correlates with peak phrenic responses during hypoxia and hypercapnia, but not with the level of hypoxia during episodic exposures. Potential mechanisms underlying these relationships are discussed, and currently available data are synthesized into an updated mechanistic model of LTF. In this model, we propose that LTF arises predominantly from episodic activation of serotonergic receptors on phrenic motoneurons, activating intracellular kinases and, thus, phosphorylating and potentiating ionic currents associated with the glutamate receptors that mediate respiratory drive.

Inheritance of ventilatory behavior in rodent models

Studies in mice and rats support the hypothesis that ventilation and its components (frequency and tidal volume) are determined to a significant extent by genetic mechanisms. The question can no longer be 'is there a genetic effect?' but rather 'how strong is the genetic component?' and 'what genes are involved?' The computational analyses of selectively bred animals now offer powerful tools to begin to dissect the genetic factors that track with ventilatory traits. Control of the conditions in the colony and in the laboratory are keys to reducing the environmental 'noise' and increasing the likelihood of detecting gene loci that correlate quantitatively with phenotype values before and during the response to chemosensory challenges. Knowing the chromosomal location of genes for ventilation will then permit the identification of proteins systems responsible for the structural and functional components for respiration.

Contribution of baroreceptors and chemoreceptors to ventricular hypertrophy produced by sino-aortic denervation in rats

1. To test whether sino-aortic denervation (SAD)-induced right ventricular hypertrophy (RVH) is a consequence of baroreceptor or chemoreceptor denervation, we compared the effects of aortic denervation (AD), carotid denervation (CD), SAD and a SAD procedure modified to spare the carotid chemoreceptors (mSAD), 6 weeks after denervation surgery in rats. A sham surgery group served as the control. 2. The blood pressure (BP) level was unaffected by AD, CD or SAD, but increased (9 %) following mSAD. The mean heart rate level was not affected. Short-term BP variability was elevated following AD (81 %), SAD (144 %) and mSAD (146 %), but not after CD. Baroreflex heart rate responses to phenylephrine were attenuated in all denervation groups. 3. Significant RVH occurred only following CD and SAD. These procedures also produced high mortality (CD and SAD) and significant increases in right ventricular pressures and haematocrit (CD). 4. Significant left ventricular hypertrophy occurred following CD, SAD and mSAD. Normalized left ventricular weight was significantly correlated with indices of BP variability. 5. These results suggest that SAD-induced RVH is a consequence of chemoreceptor, not baroreceptor, denervation. Our results also demonstrate that a mSAD procedure designed to spare the carotid chemoreceptors produced profound baroreflex dysfunction and significant left, but not right, ventricular hypertrophy.

Polycythemic responses to hypoxia: molecular and genetic mechanisms of chronic mountain sickness

We examined erythropoietin (EPO) gene expression and EPO production during hypoxia in two Sprague-Dawley rat strains with divergent polycythemic responses to hypoxia. Hilltop (H) rats develop severe polycythemia, severe hypoxemia, and pulmonary artery hypertension. The H rats often die from a syndrome indistinguishable from chronic mountain sickness (CMS) in humans. Madison (M) rats develop polycythemia and pulmonary artery hypertension that is modest and suffer no excess mortality. We tested the hypothesis that these rat strains have different stimulus-response characteristics governing EPO production. Rats of each strain were exposed to hypoxia (0.5 atm, 73 Torr inspired PO2), and renal tissue EPO mRNA and EPO levels, plasma EPO, ventilation, arterial and renal venous blood gases, and indexes of renal function were measured at fixed times during a 30-day hypoxic exposure. During extended hypoxic exposure, H rats had significantly elevated renal EPO mRNA, renal EPO, and plasma EPO levels compared with M rats. Ventilatory responses and indexes of renal function were similar in the strains during the hypoxic exposure. H rats had greater arterial hypoxemia from the onset of hypoxia and more severe renal tissue hypoxemia and greater polycythemia after 14 days of hypoxic exposure. When EPO responses were expressed as functions of renal venous PO2, the two strains appeared to lie on the same dose-response curves, but the responses of H rats were shifted along the curve toward more hypoxic values. We conclude that H rats have significantly greater polycythemia secondary to poorer renal tissue oxygenation, but the stimulus-response characteristics governing EPO gene expression and EPO production do not seem to differ between M and H rats. Finally, the regulation of EPO levels during hypoxia occurs primarily at the transcriptional level.

Hypertension caused by chronic intermittent hypoxia--influence of chemoreceptors and sympathetic nervous system

BACKGROUND

The sleep apnea syndrome (SAS) is a common health problem with a 30% prevalence among patients with so-called essential hypertension.

OBJECTIVE

Prompted by this epidemiologic link we tried to find out whether there is a cause-effect relationship between SAS and systemic hypertension.

DESIGN

We developed an animal model to simulate defined aspects of the SAS. Rats were exposed to chronic repetitive hypoxia for 7 h per day and their blood pressure was measured by invasive methods.

RESULTS

We found that 30 days of intermittent hypoxia sufficed for the development of a significant elevation of blood pressure. The co-exposure to hypoxia and hypercapnia had no additional effect. Surgical denervation of peripheral chemoreceptors prevented the increase in arterial blood pressure. Adrenal demedullation and chemical denervation of the peripheral sympathetic nervous system by 6-hydroxy dopamine also prevented the increase.

CONCLUSIONS

Our data imply that repetitive hypoxemia in SAS is probably the cause of the high prevalence of systemic hypertension in this population and that peripheral chemoreceptors and the sympathetic nervous system play important roles in this pathophysiologic process.

Exaggerated pulmonary hypertension with monocrotaline in rats susceptible to chronic mountain sickness

Hilltop (H) strain Sprague-Dawley rats are more susceptible to chronic mountain sickness than are the Madison (M) strain rats. It is unclear what role pulmonary vascular remodeling, polycythemia, and hypoxia-induced vasoconstriction play in mediating the more severe pulmonary hypertension that develops in the H rats during chronic hypoxia. It is also unclear whether the increased sensitivity of the H rats to chronic mountain sickness is specific for a hypoxia effect or, instead, reflects a general propensity toward the development of pulmonary hypertension. Monocrotaline (MCT) causes pulmonary vascular remodeling and pulmonary hypertension. We hypothesized that the difference in the pulmonary vascular response to chronic hypoxia between H and M rats reflects an increased sensitivity of the H rats to any pulmonary hypertensive stimuli. Consequently, we expected the two strains to also differ in their susceptibility to MCT-induced pulmonary hypertension. Pulmonary arterial pressures in conscious H and M rats were measured 3 wk after a single dose of MCT, exposure to a simulated high altitude of 18,000 ft (barometric pressure = 380 mmHg), and administration of a single dose of saline as a placebo. The H rats had significantly higher pulmonary arterial pressures and right ventricular weights after MCT and chronic hypoxia than did the M rats. The H rats also had more pulmonary vascular remodeling, i.e., greater wall thickness as a percentage of vessel diameter, after MCT and chronic hypoxia than did the M rats. The H rats had significantly lower arterial PO2 than did the M rats after MCT, but the degree of hypoxemia was mild [arterial PO2 of 72.5 +/- 0.8 (SE) Torr for H rats vs. 77.4 +/- 0.8 Torr for M rats after MCT]. The H rats had lower arterial PCO2 and larger minute ventilation values than did the M rats after MCT. These ventilatory differences suggest that MCT caused more severe pulmonary vascular damage in the H rats than in the M rats. These data support the hypothesis that the H rats have a general propensity to develop pulmonary hypertension and suggest that differences in pulmonary vascular remodeling account for the increased susceptibility of H rats, compared with M rats, to both MCT and chronic hypoxia-induced pulmonary hypertension.

Ventilation and metabolism among rat strains

We examined ventilation and metabolism in four rat strains with variation in traits for body weight and/or blood pressure regulation. Sprague-Dawley [SD; 8 males (M), 8 females (F)], Brown Norway (BN; 10 M, 11 F), and Zucker (Z; 11 M, 12 F) rats were compared with Koletsky (K; 11 M, 11 F) rats. With the use of noninvasive plethysmography, frequency, tidal volume, minute ventilation (VE), O2 consumption, and CO2 production were derived at rest during normoxia (room air) and during the 5th minute of exposure to each of the following: hyperoxia (100% O2), hypoxia (10% O2-balance N2), and hypercapnia (7% CO2-balance O2). Statistical methods probed for strain and sex effects, with covariant analysis by body weight, length, and body mass. During resting breathing, strain effects were found with respect to both frequency (BN, Z > K, SD) and tidal volume (SD > BN, Z) but not to VE. Sex influenced frequency (F > M) alone. Z rats had higher values for O2 consumption, CO2 production, and respiratory quotient than the other three strains, with no independent effect by sex. During hyperoxia, frequency was greater in BN and Z than in SD or K rats; SD rats had a larger tidal volume than BN or Z rats; Z rats had a greater VE than K rats; and M had a larger tidal volume than F. Strain differences persisted during hypercapnia, with Z rats exhibiting the highest frequency and VE values. During hypoxic exposure, strain effects were found to influence VE (SD > K, Z), frequency (BN > K), and tidal volume (SD > BN, K, Z). Body mass was only a modest predictor of VE during normoxia, of both VE and tidal volume with hypoxia, hypercapnia, or hyperoxia, and of frequency during hypercapnia. We conclude that strain of rats, more than their body mass or sex, has major and different influences on metabolism, the pattern and level of ventilation during air breathing, and ventilation during acute exposure to hypercapnia or hypoxia.

Morphological alterations in the hippocampus following hypobaric hypoxia

1. The morphological consequences of hypobaric hypoxia, exposure to reduced pressure atmospheres, were examined in the hippocampus of male Fischer 344 rats. Severe chronic hypoxia can produce permanent neuronal damage with hippocampal structures being especially vulnerable. 2. Hippocampal morphology was studied using histological observations after a 4 day exposure to sea level, 3500 m, or 6400 m. Two groups tested at 6400 m were sacrificed at different intervals following exposure, 72 and 144 h, to examine the effect of post-exposure time on neuronal damage. 3. Histological damage was observed in rats' brains following exposure to altitude, with cell degeneration and death increasing as altitude increased. In addition, it was found that the longer the time following exposure before sacrifice, the more noticeable the damage, suggesting delayed neurotoxicity. Increases in the number of damaged cells following altitude were significant for the CA3 region of one 6400 m group; however, other differences did not reach statistical significance. Rats exposed to altitude for 4 days ate less and lost significantly more weight than did animals at sea level. 4. It appears that 4 days of exposure to altitudes less than or equal to 6400 m does produce changes in the CA3 subfield, but the damage is different than that seen with other models of non-transient ischemia.

The relationship between systemic hypertension and obstructive sleep apnea: facts and theory

This article provides an in-depth overview of the relationship between primary hypertension and adult obstructive sleep apnea syndrome. The background data and research are taken from the English-language literature through 1993. Primary hypertension is a common cause of major medical illnesses, including stroke, heart disease, and renal failure, in middle-aged males. Its prevalence in the United States is around 20%, with the rate of newly diagnosed hypertensive patients being about 3% per year. Sleep apnea syndrome is common in the same population. It is estimated that up to 2% of women and 4% of men in the working population meet criteria for sleep apnea syndrome. The prevalence may be much higher in older, non-working men. Many of the factors predisposing to hypertension in middle age, such as obesity and the male sex, are also associated with sleep apnea. Recent publications describe a 30% prevalence of occult sleep apnea among middle-aged males with so called "primary hypertension." Is this association fortuitous, related to a high prevalence of both diseases in the same population, or is it caused by a factor common to both diseases, such as obesity? Should the diagnosis of apnea be actively sought with sleep studies in hypertensive populations? If a diagnosis of "asymptomatic" sleep apnea is made in a hypertensive person, should the apnea be treated? Current research data provide only partial answers to these and other questions regarding the association of apnea and hypertension. Logic dictates that clinically symptomatic patients in hypertensive clinics should receive appropriate evaluation for apnea, but broad populations of hypertensive individuals should not be referred for sleep studies.

Nimodipine prevents the in vivo decrease in hippocampal extracellular acetylcholine produced by hypobaric hypoxia

Hypoxia decreases acetylcholine (ACh) synthesis and release in vitro, and ACh synthesis in vivo; however, its effect on extracellular concentration of ACh in vivo is not known. The calcium channel blocker nimodipine is a cerebrovascular dilator which also increases extracellular ACh in vivo. Therefore, it may provide protection from the effects of hypobaric hypoxia on the cholinergic system either via its effects on vascular function or by direct action on the nervous system. This study examined the effect of hypobaric hypoxia on extracellular ACh and choline levels, as measured by microdialysis, as well as the effects of nimodipine under hypoxia. Microdialysis guide cannulae were implanted into the hippocampal region of male Fischer rats so that probes would sample from the CA1 and DG regions. Animals were then exposed for eight hours to a simulated altitude of 5,500 m (18,000 ft) or tested at sea level for an equivalent duration. HPLC with electrochemical detection was used for analysis of the dialysates. At 5,500 m extracellular ACh levels in the placebo-treated group were significantly lower than the sea level group values. This decrement was reversed by nimodipine administered i.p. immediately preceding altitude ascent (10 mg/kg) and 250 min post-altitude ascent (10 mg/kg). These data suggest that nimodipine may provide protection from the detrimental effects of hypoxia on hippocampal cholinergic function.

Hematologic responses and the early development of hypoxic pulmonary hypertension in rats

We have previously described the development of greater right ventricular hypertrophy after 7 days of hypoxia in the altitude-susceptible H strain compared to the resistant M strain of Sprague-Dawley rat. Greater polycythemia also occurs in the H strain after 2-3 weeks of hypoxia and is characterized by increased mean red cell volume (MCV), reticulocyte count (Retic), and blood viscosity after 4 weeks of hypoxia. In the present study, we determined the time course of development of these hematologic responses, whether differences in MCV are associated with differences in red cell deformability, and whether the hematologic differences might contribute to the early cardiopulmonary differences between the strains. We found that although hematocrit (Hct) did not differ between the strains until 21 days of hypoxia, MCV and Retic were greater in the H strain after only 3 days and whole blood viscosity was greater after 7 days. However, no differences in the viscosity or deformability of reconstituted red cells (Hcts 10% and 25%) were apparent at any time during hypoxic exposure. Furthermore, pressure-flow curves obtained using blood and lungs isolated from 7-day hypoxic rats suggested that the largest component of pressure elevation in the H rats was related to pulmonary vascular rather than hematologic factors. We conclude that although H rats have exaggerated hematologic responses to hypoxia, differences in pulmonary vascular structure and tone are more likely to be responsible for the strain differences in cardiopulmonary responses occurring after 7 days of hypoxia.

Exogenous erythropoietin fails to augment hypoxic pulmonary hypertension in rats

In two rat strains (H and M) with differing susceptibilities to chronic hypoxia we examined the role of polycythemia in the differing hypoxic pulmonary hemodynamic responses. We hypothesized that augmentation of hematocrit (Hct) during hypoxia in the resistant M strain would render cardiopulmonary responses similar to those obtained in the susceptible H strain. Administration of human recombinant erythropoietin (EPO) in doses of 100, 250 and 500 U.kg-1 s.c. thrice weekly for three weeks raised Hct similarly in both strains indicating that normoxic rats had similar sensitivities to EPO. In rats exposed to hypobaric hypoxia (0.5 atm) for 21 days, EPO (500 U.kg-1 thrice weekly) significantly increased Hct and whole blood viscosity as expected. Surprisingly, right ventricular (RV) to body weight (BW) ratio as an index of right ventricular hypertrophy (RVH) and RV peak systolic pressure did not increase in EPO-injected rats of either strain compared to hypoxic controls. Among hypoxic animals, Hct correlated highly with viscosity but not with RV/BW. We conclude, contrary to our hypothesis, that polycythemia does not appear to be responsible for the strain difference in RVH and pulmonary hypertension.

Sympathetic denervation blocks blood pressure elevation in episodic hypoxia

We have previously described a rat model that responds to repetitive episodic hypoxia (FiO2 nadir 3-5% for 12 seconds every 30 seconds for 7 hr/day for 35 days) with chronic increase in arterial blood pressure. The purpose of the current study was to determine if peripheral sympathetic nervous system denervation blocks this persistent blood pressure elevation. Chemical sympathetic denervation was achieved and maintained by three intraperitoneal injections (100 mg/kg 6-hydroxydopamine) on days 1, 3, and 27 of a 47-day experiment in two groups of rats. One denervated group was subjected to episodic hypoxia for 40 consecutive days beginning on day 7 and the other remained unhandled in their usual cages. A third group was injected with vehicle only and subjected to the same episodic hypoxia while a fourth group remained unhandled for 40 days. The vehicle-treated, episodic hypoxia-exposed group showed a 7.7 mm Hg increase in mean arterial blood pressure (conscious, unrestrained) over the 40-day period, whereas all other groups showed a decrease in mean arterial pressure. The left ventricle and septum/whole body weight ratio was higher in both episodic hypoxia-exposed groups at the end of the study. Plasma epinephrine in both groups administered 6-hydroxydopamine was higher on day 6 than in the vehicle-injected rats. Measurement of catecholamines in cardiac muscle homogenate confirmed denervation in 6-hydroxydopamine animals. These results indicate that the peripheral sympathetic nervous system is necessary for the persistent increase in blood pressure in response to repetitive episodic hypoxia.

Repetitive, episodic hypoxia causes diurnal elevation of blood pressure in rats

An association between chronic high blood pressure and obstructive sleep apnea has been described. We hypothesized that repetitive episodic hypoxia patterned after the hypoxia seen in sleep apnea could contribute to diurnal elevation of blood pressure. Using 12-second infusions of nitrogen into daytime sleeping chambers, four groups of male rats (250-375 g) were subjected to intermittent hypoxia (3-5% nadir ambient oxygen) every 30 seconds, 7 hours per day for up to 35 days. In one group, blood pressure was measured weekly by the tail-cuff method in conscious animals during 5 weeks of episodic hypoxia. In the other three groups, blood pressure was measured in conscious animals via femoral artery catheters at baseline and after 20, 30, or 35 days of exposure. Additional groups served as controls: two sham groups housed in identical "hypoxia" chambers received compressed air instead of nitrogen (35 days) while two other groups remained unhandled in their usual cages (35 days). Both groups challenged with 35 days episodic hypoxia showed significant increases in blood pressure compared with controls: the tail-cuff rats showed a 21 mm Hg increase in systolic pressure (p less than 0.05) and the intra-arterially measured rats a 13.7 mm Hg increase in mean arterial pressure (p less than 0.05). The 30-day exposed rats also showed a 5.7 mm Hg increase in mean pressure over baseline (p less than 0.05). Blood pressure did not change significantly from baseline in the control groups. Left ventricle-to-body weight ratio was higher in both 35-day exposed groups than in unhandled or sham controls.(ABSTRACT TRUNCATED AT 250 WORDS)

Lung angiotensin converting enzyme activity in rats with differing susceptibilities to chronic hypoxia

The decrease in lung angiotensin converting enzyme (ACE) activity occurring in rats during chronic hypoxia might be related to the pulmonary haemodynamic response or to the hypoxia. A study in rats was carried out to investigate this question. Rats from the Hilltop (H) strain are known to develop more severe pulmonary hypertension as a result of chronic hypoxia than rats from the Madison (M) strain despite having virtually identical arterial and mixed venous oxygen tensions. Rats from H and M strains were exposed to hypoxia (0.5 atm) for 3-21 days and lung and serum ACE activities were determined. After three days' hypobaria lung ACE activity was significantly lower and serum ACE significantly higher in H than in M rats. Linear regressions for lung ACE activity and right ventricular:body weight ratios showed significant inverse correlations and were similar in the two strains. The results suggest that pulmonary hypertension and not hypoxia determines the reduction in lung ACE activity, possibly by releasing ACE into the blood stream.

Role of erythrocyte deformability in the acute hypoxic pressor response in the pulmonary vasculature

To assess the importance of erythrocyte deformability in the pulmonary hypoxic pressor response (HPR) we examined whether alterations in erythrocyte deformability are related to the differences between the brisk HPR in rats vs the small HPR in hamsters, and between the HPR in low altitude rats vs high altitude rats (10 days in 10% oxygen). Deformability of the erythrocytes (RBC) was assessed by filtering equal volume of RBC suspension through Nucleopore filters (4.7 micron) using the same pressure head across the filter. The results show that during hypoxia, rat RBC become relatively nondeformable compared to hamster's RBC. This finding is consistent with a large HPR in rats but a small HPR in hamsters. Furthermore, the deformability of RBC from high altitude rats became unaffected by hypoxia and was associated with blunting in the HPR in isolated lungs from high altitude rats. The HPR in isolated lungs from low altitude rats was larger when they were perfused with blood from normal rats (= 86% increase in resistance) than when perfused with blood from high altitude rats (= 36% increase in resistance). This finding further supports the possible role of RBC deformability in HPR. Inconsistent with the importance of deformability, however, was the finding that high altitude rat lungs had a blunted HPR whether they were perfused with normal rat blood or high altitude rat blood. This may be due to restructuring of the pulmonary microvascular bed in the lung from high altitude rats. The results favor the idea that changes in erythrocyte deformability may be responsible for the difference between the HPR in low altitude rats and hamsters, and between the HPR in low and high altitude rats. We suggest that 'obstruction' of the capillaries by less deformable erythrocyte is another factor, besides smooth muscle contraction, responsible for the hypoxic pressor response in the pulmonary vasculature.

Time course of cardiopulmonary responses to high altitude in susceptible and resistant rat strains

We have identified two strains (H and M) of Sprague-Dawley rat with distinctly different susceptibilities and cardiopulmonary responses to hypoxia. In this study, we studied the development of cardiopulmonary and hematological responses to hypoxia and the post-hypoxic regression of these responses in the two strains over time. Under sea level conditions, there were no differences between the two strains. On exposure to hypobaric hypoxia (0.5 atm), right ventricular peak systolic pressure (RVPP) and right ventricular hypertrophy (RVH) increased more rapidly in the susceptible (H) than in the resistant (M) strain. In contrast, post-hypoxic reversal of these changes occurred at comparable rates. Hematocrits rose at similar rates in the two strains until after two weeks, when that of the H strain slightly exceeded that of the M strain. With the progression of RVH, left ventricular plus septal to body weight ratio (LV + S) g/100 g bw decreased in M rats but increased in the H rats. As a result, a conspicuous overall cardiac hypertrophy developed in the H rats but only a minimal cardiac hypertrophy occurred in the M strain. The data show that susceptibility to hypoxia in H rats is associated with more rapid development of RV systolic hypertension and biventricular hypertrophy than in M rats. The mechanism for the accelerated cardiopulmonary responses in the H rats most likely involves greater hypoxic pulmonary vasoconstriction or pulmonary vascular remodeling. Differences in hematocrit between the strains do not contribute to the early cardiopulmonary responses.

Reticulocytosis, increased mean red cell volume, and greater blood viscosity in altitude susceptible compared to altitude resistant rats

We have identified two strains (H and M) of Sprague-Dawley rat with markedly different susceptibilities and cardiopulmonary responses to chronic hypobaria. To further characterize factors responsible for these differing cardiopulmonary responses to chronic hypobaria, the present study examined differences in hematologic responses between the strains and assessed the contribution of differences in blood viscosity to differences in pulmonary vascular resistance. Following a 4-5 week exposure to simulated high altitude (0.5 atm), hemoglobin, hematocrit, mean red cell volume, and reticulocyte count were all increased in the susceptible H compared to the resistant M rats, whereas red blood cell counts were similar. Sea level controls manifested no differences. Blood viscosity, measured in a capillary viscometer, was 53% greater in chronically hypoxic H than in M rats, and plasma viscosities were similar. Blood from high altitude H rats increased pulmonary vascular resistance more than blood from high altitude M rats when perfused into lungs isolated from high altitude rats of either strain. In conclusion, high altitude H rats have an increased population of immature red cells, leading to a greater mean red cell volume and hematocrit than in high altitude M rats. These hematologic differences contribute to the the increased blood viscosity and greater pulmonary vascular resistance of H compared to M rats after 4 weeks' high altitude exposure.

Rat platelet aggregation: strain and stock variations

Platelet aggregation induced by ADP, arachidonic acid, and collagen was monitored in rats from two stocks, WSU-SD and CD, and from three strains, Lewis, Holtzman, and NBR. ADP-induced aggregation did not vary between the WSU-SD, CD, Lewis, Holtzman, and NBR rats. In contrast, the response to AA and collagen depended upon the stock or strain of rat. Platelets from the Holtzman and especially the NBR were much more sensitive to AA than were those from the other strains. At 0.25 mM AA, 7 of 8 NBR rats and 5 of 8 Holtzman rats aggregated irreversibly, while only 1 in 8 WSU-SD, CD, and Lewis rats aggregated irreversibly at that concentration. Collagen-induced aggregation reflected that to AA. The possible relationship between the variation in platelet aggregation and sympathoadrenal activity is discussed.

Acute and chronic pulmonary pressor responses to hypoxia: the role of blunting in acclimatization

We studied two strains of Sprague-Dawley rats: the Madison (M) that acclimatizes successfully to high altitude; and the Hilltop (H), that manifests signs of chronic mountain sickness at high altitude and has a high mortality rate. Awake, chronically instrumented animals were tested at sea level, at intervals during 30 days at a simulated altitude of 5500 m, and during 10 to 15 days of recovery at sea level. Mean pulmonary artery pressure (PAP) rose at high altitude to reach 60 mm Hg in H and 40 mm Hg in M, but the acute pressor response to hypoxia at sea level was much more pronounced in M than H. Depression of PAP by normoxic exposures in H rats at high altitude was slightly early in the period of stay but was enhanced with further prolongation of high altitude residence. The M rats, in contrast, had a blunted response (normoxia had very little depressant effect on PAP) after the first 24 h at high altitude, and it remained so for the duration of the stay. On return to sea level the response of H rats remained unchanged for 7 days, but the blunted response of the M rats at high altitude reversed at sea level to become exaggerated. We conclude: that responses of PAP to acute hypoxia do not forecast what the chronic response will be; that the appearance of an unidentified mechanism during chronic hypoxia in the M strain attenuates the vasoreactivity of the pulmonary vessels to hypoxia; and that the absence of such a blunting mechanism in H leads to the higher PAP in this strain and its morbid consequences. The hypothesis is put forward that the existence of such a blunting mechanism is an important factor in the adaptability of species to high altitude.

Responses of blood volume and red cell mass in two strains of rats acclimatized to high altitude

Two strains of rats, one that adapts successfully to high altitude (HA) (Madison = M) and the other that adapts poorly and suffers a high mortality rate at high altitude (Hilltop = H) were studied during 40 days of exposure to a simulated altitude of 18 000 ft (5450 m; PB = 175). The time rate of change of blood volume (TBV), red cell volume (RBCV), plasma volume (PV) and hematocrit (Hct), and the interrelationships of these variables, particularly emphasizing TBV, PV and Hct as functions of RBCV, were compared in the M and H strains. Sea level control values in the two strains were not different, but by the 5th day at HA RBCV and TBV had expanded to a greater extent in H than M - a difference that was maintained throughout the 40 days - but PV decreased similarly in the two strains. By 30 days the inter-strain differences of RBCV, TBV, and Hct became more pronounced but still no difference of PV was noted. The most significant feature was the greater polycythemic response of H, which at the extreme range was not associated with any further decrease of PV and therefore resulted in rapid expansion of TBV. The probable effects of these responses on cardiovascular function and oxygen transport are discussed, comparing the differences of H and M strains, which became maladaptive in H. The similarity of the responses in H to those of man with chronic mountain sickness is noted.

The role of pulmonary vascular responses to chronic hypoxia in the development of chronic mountain sickness in rats

A strain of Sprague-Dawley rat obtained from Hilltop Labs, Scottsdale, PA (H rats), develops more severe pulmonary hypertension, right ventricular hypertrophy, and polycythemia than a strain obtained from Madison, WI (M rats), following exposure to simulated high altitude. We sought to determine whether differences in pulmonary vascular responses to chronic hypoxia could explain the differing high altitude susceptibilities of the two strains. Vasoconstrictor responses to hypoxia and angiotensin II were tested in blood perfused lungs isolated from rats of both groups exposed to stimulated high altitude (4 to 5 weeks, 0.5 atm), or from sea level controls. Pressure-flow curves, serving as an index of 'passive' vascular resistance, were also determined in the isolated lungs. Vasoconstrictor responses to hypoxia were blunted in high altitude rats of both the H and M strains compared to sea level controls, and the H sea level rats had blunted vasoconstrictor responses to hypoxia compared to the M sea level rats. Vasoconstrictor responses to angiotensin II were similar among the groups and were unaffected by chronic high altitude exposure. Pressure-flow curves were greater in both high altitude groups than in the sea level groups, and those of the H high altitude rats were slightly greater than those of the M high altitude rats. Thus, differences in vasoconstrictor responses to hypoxia do not explain the greater pulmonary hypertension of H high altitude rats. However, greater 'passive' vascular resistance, probably due to more extensive structural remodeling of pulmonary vessels, does appear to contribute to the greater pulmonary hypertension of the H rats.

Ventilatory responses and blood gases in susceptible and resistant rats to high altitude

On exposure to a stimulated altitude of 5500 m (18 000 ft), the Hilltop (H) strain of Sprague-Dawley rats develops signs of chronic mountain sickness (CMS) (severe polycythemia, severe pulmonary hypertension and right ventricular hypertrophy) associated with a high mortality rate. In contrast, the Madison (M) strain of Sprague-Dawley rats remains healthy with less severe cardiopulmonary and hematological responses. We tested the hypothesis that hypoventilation in the H rats relative to the M rats, leading to greater alveolar hypoxia or hypoxemia, could account for the different hematological and cardiopulmonary responses between the two strains. Ventilatory responses and blood gases were compared under normoxia and acute and chronic hypoxia in fully awake and unrestrained animals of the two strains. There were no differences in VE, Pao2, PaCO2, pHa, P-vO2, PvCO2 and pH-v under either acute or chronic hypoxia between the two strains of rats. It is concluded that relative hypoventilation does not contribute to altitude susceptibility in H rats.

Threshold of intermittent hypoxia-induced right ventricular hypertrophy in the rat

This study evaluated the threshold for intermittent hypoxia-induced right ventricular hypertrophy in the rat. Three groups of rats purchased from Hilltop Laboratory Animals, Inc., were exposed to air for 2 h, or an FIO2 = 0.1 for 1 h or 2 h daily for 28, 42 or 56 days. Packed cell volume (Hct) was significantly increased in both the 1 and 2 h hypoxic groups by 28 days. The ratios of (right ventricular wt)/(body wt) and the (right ventricular wt)/(left ventricular plus septum wt) significantly increased in the 2 h hypoxic group by 42 days. We conclude that 1 h of hypoxia per day for 28 days results in polycythemia and that 2 h of hypoxia per day for 42 days results in right ventricular hypertrophy in this rat strain.