Quantitative changes in the rat pulmonary vasculature in chronic hypoxia--relation to haemodynamic changes

Optimizing imaging of the rat pulmonary microvasculature by micro-computed tomography

Micro-computed tomography (micro-CT) is used in pre-clinical research to generate high-resolution three-dimensional (3D) images of organs and tissues. When combined with intravascular contrast agents, micro-CT can provide 3D visualization and quantification of vascular networks in many different organs. However, the lungs present a particular challenge for contrast perfusion due to the complexity and fragile nature of the lung microcirculation. The protocol described here has been optimized to achieve consistent lung perfusion of the microvasculature to vessels < 20 microns in both normal and pulmonary arterial hypertension rats. High-resolution 3D micro-CT imaging can be used to better visualize changes in 3D architecture of the lung microcirculation in pulmonary vascular disease and to assess the impact of therapeutic strategies on microvascular structure in animal models of pulmonary arterial hypertension.

Physiological and pathological angiogenesis in the adult pulmonary circulation

Angiogenesis occurs during growth and physiological adaptation in many systemic organs, for example, exercise-induced skeletal and cardiac muscle hypertrophy, ovulation, and tissue repair. Disordered angiogenesis contributes to chronic inflammatory disease processes and to tumor growth and metastasis. Although it was previously thought that the adult pulmonary circulation was incapable of supporting new vessel growth, over that past 10 years new data have shown that angiogenesis within this circulation occurs both during physiological adaptive processes and as part of the pathogenic mechanisms of lung diseases. Here we review the expression of vascular growth factors in the adult lung, their essential role in pulmonary vascular homeostasis and the changes in their expression that occur in response to physiological challenges and in disease. We consider the evidence for adaptive neovascularization in the pulmonary circulation in response to alveolar hypoxia and during lung growth following pneumonectomy in the adult lung. In addition, we review the role of disordered angiogenesis in specific lung diseases including idiopathic pulmonary fibrosis, acute adult distress syndrome and both primary and metastatic tumors of the lung. Finally, we examine recent experimental data showing that therapeutic enhancement of pulmonary angiogenesis has the potential to treat lung diseases characterized by vessel loss.

Fluorescent microangiography (FMA): an improved tool to visualize the pulmonary microvasculature

Visualization of the complex lung microvasculature and resolution of its three-dimensional architecture remains a difficult experimental challenge. We present a novel fluorescent microscopy technique to visualize both the normal and diseased pulmonary microvasculature. Physiologically relevant pulmonary perfusion conditions were applied using a low-viscosity perfusate infused under continuous airway ventilation. Intensely fluorescent polystyrene microspheres, confined to the vascular space, were imaged through confocal optical sectioning of 200 microm-thick lung sections. We applied this technique to rat lungs and the markedly enhanced depth of field in projected images allowed us to follow vascular branching patterns in both normal lungs and lungs from animals with experimentally induced pulmonary arterial hypertension. In addition, this method allowed complementary immunostaining and identification of cellular components surrounding the blood vessels. Fluorescent microangiography is a widely applicable and quantitative tool for the study of vascular changes in animal models of pulmonary disease.

Quantitative models of the rat pulmonary arterial tree morphometry applied to hypoxia-induced arterial remodeling

Little is known about the constituent hemodynamic consequences of structural changes that occur in the pulmonary arteries during the onset and progression of pulmonary arterial remodeling. Many disease processes are known to be responsible for vascular remodeling that leads to pulmonary arterial hypertension, cor pulmonale, and death. Histology has been the primary tool for evaluating pulmonary remodeling, but it does not provide information on intact vascular structure or the vessel mechanical properties. This study is an extension of our previous work in which we developed an alternative imaging technique to evaluate pulmonary arterial structure. The lungs from Sprague-Dawley rats were removed, perfusion analysis was performed on the isolated lungs, and then an X-ray contrast agent was used to fill the arterial network for imaging. The lungs were scanned over a range of intravascular pressures by volumetric micro-computed tomography, and the arterial morphometry was mapped and measured in the reconstructed isotropic volumes. A quantitative assessment of hemodynamic, structural, and biomechanical differences between rats exposed for 21 days to hypoxia (10% O(2)) or normoxia (21.0% O(2)) was performed. One metric, the normalized distensibility of the arteries, is significantly (P < 0.001) larger [0.025 +/- 0.0011 (SE) mmHg(-1)] (n = 9) in normoxic rats compared with hypoxic [0.015 +/- 0.00077 (SE) mmHg(-1)] (n = 9). The results of the study show that these models can be applied to the Sprague-Dawley rat data and, specifically, can be used to differentiate between the hypoxic and the control groups.

Structural basis of hypoxic pulmonary hypertension: the modifying effect of chronic hypercapnia

Exposure to chronic hypoxia causes pulmonary hypertension and pulmonary vascular remodelling. In chronic lung disease, chronic hypercapnia frequently coexists with hypoxia and is associated with worsening of pulmonary hypertension. It is generally stated that pulmonary hypertension in these conditions is secondary to hypoxic vascular remodelling and that hypercapnia augments this remodelling thus worsening the hypertension. We review recent evidence which shows that although chronic hypoxia causes thickening of the walls of pulmonary arterioles, these changes do not lead to structural narrowing of the lumen by encroachment. Moreover, hypoxia leads to new vessel formation within the pulmonary vasculature and not loss of vessels as formerly thought. Such neovascularization may provide a beneficial adaptation by increasing the area of the gas exchange membrane. These novel structural findings are supported by recent reports that inhibitors of the RhoA pathway can acutely reduce pulmonary vascular resistance in chronically hypoxic lungs to near normal values, demonstrating that structural changes are not the dominant mechanisms underling hypoxic pulmonary hypertension. Chronic hypercapnia inhibits the development of hypoxic pulmonary hypertension, pulmonary vascular remodelling and hypoxia-induced angiogenesis. This last effect might be maladaptive, as it would prevent the potentially beneficial increase in gas exchange membrane area. These findings suggest that structural narrowing of the vascular lumen of resistance vessels is not the mechanism by which hypoxia and hypercapnia cause pulmonary hypertension in chronic lung disease.

Flow and pressure distributions in vascular networks consisting of distensible vessels

We examine the influence of vessel distensibility on the fraction of the total network flow passing through each vessel of a model vascular network. An exact computational methodology is developed yielding an analytic proof. For a class of structurally heterogeneous asymmetric vascular networks, if all the individual vessels share a common distensibility relation when the total network flow is changed, this methodology proves that each vessel will continue to receive the same fraction of the total network flow. This constant flow partitioning occurs despite a redistribution of pressures, which may result in a decrease in the diameter of one and an increase in the diameter of the other of two vessels having a common diameter at a common pressure. This theoretical observation, taken along with published experimental observations on pulmonary vessel distensibilities, suggests that vessel diameter-independent distensibility in the pulmonary vasculature may be an evolutionary adaptation for preserving the spatial distribution of pulmonary blood flow in the face of large variations in cardiac output.

Chronic hypoxia causes angiogenesis in addition to remodelling in the adult rat pulmonary circulation

Chronic hypoxia caused by migration of native sea-level dwellers to high altitude or chronic lung disease leads to the development of increased pulmonary vascular resistance and pulmonary hypertension. This altitude-induced hypertension offers no obvious benefit and may indeed be maladaptive. A major mechanism thought to contribute to the development of pulmonary hypertension is hypoxia-induced loss of small blood vessels, sometimes termed rarefaction or pruning. More recent evidence caused us to question this widely accepted concept including the potent angiogenic effect of chronic hypoxia in all other vascular beds and the demonstration that new vessels can form in the pulmonary circulation when stimulated by chronic infection and lung resection. We tested the hypothesis that chronic environmental hypoxia causes angiogenesis in the adult pulmonary circulation by using stereological techniques combined with confocal microscopy to examine the resultant changes in pulmonary vascular structure in rats. We found that chronic hypoxia resulted in increased total pulmonary vessel length, volume, endothelial surface area and number of endothelial cells in vivo. This is the first reported demonstration of hypoxia-induced angiogenesis in the mature pulmonary circulation, a structural adaptation that may have important beneficial consequences for gas exchange. These findings imply that we must revise the widely accepted paradigm that hypoxia-induced loss of small vessels is a key structural change contributing to the development of pulmonary hypertension in high altitude adaptation and chronic lung disease.

Barium sulphate and soft-tissue radiology: allying the old and the new for the investigation of animal cutaneous microcirculation

The study of microcirculation using angiography is essential to the advancement of flap and angiogenesis research in plastic surgery. Until the mid-1980s, barium sulphate was the most commonly used contrast material, although it did not provide optimal visualisation of the vascular tree. In 1986, a new technique using lead oxide was proposed, which permitted very high-quality imaging and rapidly became the technique of choice, despite its high toxicity. We reconsider the former technique of barium-sulphate injection and combine it with soft-tissue radiology using mammographic film to achieve a radiological definition similar to that obtained with lead oxide, and discuss the advantages and disadvantages of the two methods. We conclude that barium sulphate and the use of mammographic film is an accurate, simple and non-toxic method of analysing the cutaneous circulation in small animals.

The structural basis of pulmonary hypertension in chronic lung disease: remodelling, rarefaction or angiogenesis?

Chronic lung disease in humans is frequently complicated by the development of secondary pulmonary hypertension, which is associated with increased morbidity and mortality. Hypoxia, inflammation and increased shear stress are the primary stimuli although the exact pathways through which these initiating events lead to pulmonary hypertension remain to be completely elucidated. The increase in pulmonary vascular resistance is attributed, in part, to remodelling of the walls of resistance vessels. This consists of intimal, medial and adventitial hypertrophy, which can lead to encroachment into and reduction of the vascular lumen. In addition, it has been reported that there is a reduction in the number of blood vessels in the hypertensive lung, which could also contribute to increased vascular resistance. The pulmonary endothelium plays a key role in mediating and modulating these changes. These structural alterations in the pulmonary vasculature contrast sharply with the responses of the systemic vasculature to the same stimuli. In systemic organs, both hypoxia and inflammation cause angiogenesis. Furthermore, remodelling of the walls of resistance vessels is not observed in these conditions. Thus it has been generally stated that, in the adult pulmonary circulation, angiogenesis does not occur. Prompted by previous observations that chronic airway inflammation can lead to pulmonary vascular remodelling without hypertension, we have recently shown, using quantitative stereological techniques, that angiogenesis can occur in the adult pulmonary circulation. Pulmonary angiogenesis has also been reported in some other conditions including post-pneumonectomy lung growth, metastatic disease of the lung and in biliary cirrhosis. Such angiogenesis may serve to prevent or attenuate increased vascular resistance in lung disease. In view of these more recent data, the role of structural alterations in the pulmonary vasculature in the development of pulmonary hypertension should be carefully reconsidered.

Pulmonary vascular remodeling: a target for therapeutic intervention in pulmonary hypertension

Pulmonary vascular remodelling is an important pathological feature of pulmonary hypertension, leading to increased pulmonary vascular resistance and reduced compliance. It involves thickening of all three layers of the blood vessel wall (due to hypertrophy and/or hyperplasia of the predominant cell type within each layer), as well as extracellular matrix deposition. Neomuscularisation of non-muscular arteries and formation of plexiform and neointimal lesions also occur. Stimuli responsible for remodelling involve transmural pressure, stretch, shear stress, hypoxia, various mediators [angiotensin II, endothelin (ET)-1, 5-hydroxytryptamine, growth factors, and inflammatory cytokines], increased serine elastase activity, and tenascin-C. In addition, there are reductions in the endothelium-derived antimitogenic substances, nitric oxide, and prostacyclin. Intracellular signalling mechanisms involved in pulmonary vascular remodelling include elevations in intracellular Ca2+ and activation of the phosphatidylinositol pathway, protein kinase C, and mitogen-activated protein kinase. In animal models of pulmonary hypertension, various drugs have been shown to attenuate pulmonary vascular remodelling. These include angiotensin-converting enzyme inhibitors, angiotensin receptor antagonists, ET receptor antagonists, ET-converting enzyme inhibitors, nitric oxide, phosphodiesterase 5 inhibitors, prostacyclin, Ca2+ -channel antagonists, heparin, and serine elastase inhibitors. Inhibition of remodelling is generally accompanied by reductions in pulmonary artery pressure. The efficacy of some of the drugs varies, depending on the animal model of the disease. In view of the complexity of the remodelling process and the diverse aetiology of pulmonary hypertension in humans, it is to be anticipated that successful anti-remodelling therapy in the clinic will require a range of different drug options.

Specific uptake of 5-hydroxytryptamine is reduced in lungs from hypoxic pulmonary hypertensive rats

In this study, the aim was to determine whether 5-hydroxytryptamine (5-HT) removal by the pulmonary endothelium is reduced in 1-week hypoxic, pulmonary hypertensive rats by directly measuring [3H]5-HT uptake in isolated lungs. In lungs from hypoxic rats, specific 5-HT uptake was reduced. This was due to a 50% decrease in the maximal initial rate of uptake rather than a decrease in affinity of 5-HT for its transporter. It is possible that reduced removal of 5-HT may contribute to the elevation in plasma levels of this vasoactive amine in pulmonary hypertension.

Feldkamp and circle-and-line cone-beam reconstruction for 3D micro-CT of vascular networks

Detailed morphometric knowledge of the microvascular network is needed for studies relating structure to haemodynamic function in organs like the lung. Clinical volumetric CT is limited to millimetre-order spatial resolution. Since evidence suggests that small arterioles (50 to 300 micrometres) dominate pulmonary haemodynamics, we built a micro-CT scanner, capable of imaging excised lungs in 3D with 100 microm resolution, for basic physiology research. The scanner incorporates a micro-focal (3 microm) x-ray source, an xyz theta stage and a CCD-coupled image intensifier detector. We imaged phantoms and contrast-enhanced rat lungs, reconstructing the data with either the Feldkamp or the circle-and-line cone-beam reconstruction algorithm. We present reconstructions using 180 views over 360 degrees for the circular trajectory, augmented with views from a linear scan for the circle-and-line algorithm. Especially for platelike features perpendicular to the rotation axis and remote from the midplane, the circle-and-line algorithm produces superior reconstructions compared with Feldkamp's algorithm. We conclude that the use of nonplanar source trajectories to perform micro-CT on contrast-enhanced, excised lungs can provide data useful for morphometric analysis of vascular trees, currently down to the 130 microm level.

Neutral endopeptidase inhibitors and the pulmonary circulation

1. Neutral endopeptidase (NEP) EC 3.4.24.11 is a zinc-metallopeptidase which is partly responsible for the degradation of atrial natriuretic peptide (ANP) in vivo. 2. ANP inhibits vascular smooth muscle cell proliferation, and elicits vasorelaxation of the systemic and, more potently, the pulmonary vasculature. Plasma ANP levels are elevated in human disease states characterized by pulmonary hypertension, and in animal models of these diseases. 3. However, the short in vivo half-life of ANP suggests that it has limited therapeutic potential. Therefore, it has been hypothesized that inhibition of the metabolism of ANP may prove successful in the treatment of pulmonary hypertension. 4. Several inhibitors of NEP have been shown to reduce the development of pulmonary hypertension secondary to chronic hypoxia in rats. In addition, the inhibitor SCH 42495, partially reversed the established cardio-pulmonary remodelling associated with this disease model, without elevating plasma ANP levels. 5. The physiological actions of ANP are many of the properties desirable in a treatment for pulmonary hypertension. Thus, attenuating the metabolism of this peptide using NEP inhibitors, should potentially enhance the effects of ANP, either by maintaining plasma levels or at a local, tissue level.

Structure function correlates in the pulmonary vasculature during acute lung injury and chronic pulmonary hypertension

Arteries, veins, and capillaries comprise the pulmonary vasculature. Three structural types of artery and vein are identified, the most muscular vessels being the largest. For example, arteries that accompany the preacinar arteries are muscular in structure while those within the acinus may be either, muscular, partially muscular or non-muscular. These small intra-acinar arteries contribute much to the hemodynamic behavior of the lung. Pulmonary edema results from damage to the capillary endothelium while chronic pulmonary hypertension is characterized by structural alterations in the pulmonary arteries. Correlation of the structural and functional changes of chronic pulmonary hypertension suggest that the increases in medial and adventitial thickness of the muscular preacinar arteries are secondary to the onset of this disease, while the changes in the peripheral arteries--appearance of muscle in smaller intra-acinar arteries than normal and reduction in arterial volume--contribute to the rise in pulmonary artery pressure and pulmonary vascular resistance. Such correlations of structure and hemodynamic measurements demand that the lung be fixed in a simple and standardized manner. Available methodology to evaluate the structural changes that occur during the development of pulmonary edema and chronic pulmonary hypertension are described.

Perinatal hypoxia increases hypoxic pulmonary vasoconstriction in adult rats recovering from chronic exposure to hypoxia

The possibility that perinatal exposure to hypoxia influences the pulmonary vasculature in adults was tested. Rats born in a hypoxic environment were kept in hypoxia for an additional week after birth. The rats were then raised in atmospheric air, and when adult, they were compared with the rats born and raised in air. Rats (10 wk old) of both groups were exposed to 10% O2 for 2 wk. They were then studied immediately after the exposure and after 2 wk of recovery from the sojourn in the hypoxic environment. The experience of perinatal hypoxia did not affect mean pulmonary arterial blood pressure, right ventricle weight, or the number of muscularized peripheral pulmonary vessels. During exposure to chronic hypoxia in adulthood, both groups developed pulmonary hypertension, which was not affected by previous perinatal hypoxia. The pulmonary vascular responses to acute hypoxic challenges were studied in the preparation of isolated perfused lungs. In both groups of rats, perinatally hypoxic and normoxic, the acute hypoxic vasoconstriction was attenuated immediately after the exposure of adult animals to chronic hypoxia. However, during the recovery from this hypoxic sojourn, the rats born in hypoxia were significantly more reactive to acute lung hypoxia than all other groups of rats studied. It is concluded that the experience of a short period of perinatal hypoxia did not affect the development of hypoxic pulmonary hypertension induced in adulthood. It increased, however, the pulmonary vascular reactivity to acute hypoxic stimuli during the period of recovery from a sojourn in the hypoxic environment in adulthood.

Effect of chronic in vivo exposure to hypoxia on serotonin uptake by isolated rats lungs

1. Previously, we have shown that exposure to hypoxia stimulates serotonin uptake by cultured bovine pulmonary arterial endothelial cells. 2. In the present study, lungs isolated from rats exposed to 24 h, 48 h or 14 days of hypobaric hypoxia (0.43 or 0.5 atm) manifested no alteration of serotonin uptake in comparison to lungs from normoxic controls. 3. In addition, hypoxic stimulation of serotonin uptake by cultured rat epididymal endothelial cells was much less than that occurring in bovine pulmonary artery endothelial cells. 4. We conclude that chronic hypoxia does not stimulate serotonin uptake by rat lungs exposed in vivo as it does in endothelial cells exposed in vitro.

The sequence of cellular and hemodynamic changes of chronic pulmonary hypertension induced by hypoxia and other stimuli

It has been suggested that the lung has only a narrow range of structural responses to injury. For example, long-term injury results in emphysema, fibrosis, and pulmonary hypertension. Clinical and experimental models of chronic pulmonary hypertension suggest that this disease can be triggered by a number of interventions and that the structural changes in the pulmonary arterial circulation may vary depending on the stimulus. This report briefly reviews the structural changes that accompany the development of pulmonary hypertension in hypoxia- and Crotalaria-induced pulmonary hypertension in the rat and in repeated endotoxemia and continuous air embolization in the sheep. The studies indicate that of the structural changes considered characteristic of chronic pulmonary hypertension, the reduction in peripheral arterial volume as reflected by a loss in number of barium-filled arteries, extension of muscle into smaller intra-acinar arteries than normal, and reduction in external diameter of intra-acinar arteries are the changes that contribute to the sustained rise in pulmonary artery pressure. Increased medial and adventitial thickness of the normally muscular arteries seem to be secondary changes to this disease. Because the severity and range of structural changes differ between the experimental models of pulmonary hypertension, the data suggest that the lung, particularly the pulmonary arterial circulation, may have a more complex response to injury than originally suspected.

Reactivity and site of vasomotion in pulmonary vessels of chronically hypoxic rats: relation to structural changes

The high pressure muscular pulmonary circulation of chronically hypoxic (CH) rats was compared with the low pressure circuit in control (C) rats; differences were found in the effects of lung inflation, in pressure/flow relations during lung inflation, in reactivity to autocoids, and in responses to pulmonary dilator drugs. Isolated blood-perfused lungs of CH rats (2 to 3 wk in 10% O2) were compared with those of C rats kept in air. High inflation (alveolar) pressure (Palv) caused a rise in pulmonary artery pressure (Ppa) close to delta Palv in both groups; in CH rats, Ppa continued to rise, whereas it adapted to a lower level in C rats. Pressure-flow (P/Q) lines were measured at high and low Palv, all in Zone 2 state. In normoxia, high Palv caused a parallel shift in the P/Q line close to delta Palv in both C and CH rats. However, during hypoxic pulmonary vasoconstriction (HPV), high Palv caused a shift in the P/Q line less than delta Palv in C rats and greater than delta Palv in CH rats. Similar differences between C and CH rats were seen during constriction caused by almitrine, a drug that simulates HPV. Thus, these stimuli affect vessels that are functionally "extra-alveolar" in C rats but functionally "alveolar" in CH rats. We consider whether vasoconstriction by hypoxia and almitrine moves peripherally to the newly muscularized alveolar arterioles that are found in CH rats. Reactivity of lung vessels to bradykinin, angiotensin-1, and platelet-activating factor was greater in CH than in C rats, possibly also associated with muscularization of arterioles in the former.(ABSTRACT TRUNCATED AT 250 WORDS)