Vascular Remodeling Versus Vasoconstriction in Chronic Hypoxic Pulmonary Hypertension
2005; Lippincott Williams & Wilkins; Volume: 97; Issue: 2 Linguagem: Inglês
10.1161/01.res.00000175934.68087.29
ISSN1524-4571
AutoresKurt R. Stenmark, Ivan F. McMurtry,
Tópico(s)Neuroscience of respiration and sleep
ResumoHomeCirculation ResearchVol. 97, No. 2Vascular Remodeling Versus Vasoconstriction in Chronic Hypoxic Pulmonary Hypertension Free AccessEditorialPDF/EPUBAboutView PDFView EPUBSections ToolsAdd to favoritesDownload citationsTrack citationsPermissions ShareShare onFacebookTwitterLinked InMendeleyReddit Jump toFree AccessEditorialPDF/EPUBVascular Remodeling Versus Vasoconstriction in Chronic Hypoxic Pulmonary HypertensionA Time for Reappraisal? Kurt R. Stenmark and Ivan F. McMurtry Kurt R. StenmarkKurt R. Stenmark From the University of Colorado Health Sciences Center, Developmental Lung Biology Laboratory (K.R.S.) and Cardiovascular Pulmonary Research Laboratory (I.F.M.), Denver, Colo. and Ivan F. McMurtryIvan F. McMurtry From the University of Colorado Health Sciences Center, Developmental Lung Biology Laboratory (K.R.S.) and Cardiovascular Pulmonary Research Laboratory (I.F.M.), Denver, Colo. Originally published22 Jul 2005https://doi.org/10.1161/01.RES.00000175934.68087.29Circulation Research. 2005;97:95–98Chronic or sustained pulmonary hypertension is a complication of residence at high altitudes and chronic lung diseases such as chronic obstructive pulmonary disease, cystic fibrosis, bronchiectasis, asthma, and sleep apnea. Alveolar hypoxia is an important (though probably not exclusive) contributor to the pulmonary hypertension observed in these conditions. Further, it is widely accepted that secondary hypoxic pulmonary hypertension is strongly associated with increased morbidity and reduced survival.1,2 These facts have led to intense research efforts to identify the underlying mechanisms contributing to this condition, with the ultimate goal of identifying and developing novel therapeutic interventions. This work has relied heavily on the use of animal models, and one of the most commonly used is exposure of rats to chronic-hypoxic conditions by nitrogen dilution or hypobaria. Observations, predominately in this model, have led to the longstanding and widely accepted theory that chronic hypoxic pulmonary hypertension results from a combination of sustained vasoconstriction and vascular remodeling. It is generally believed that the contribution of vasoconstriction is greatest early in the disease process and that structural remodeling of the pulmonary vascular bed becomes progressively more important over time. That structural change is an important determinant of increased resistance and pressure in chronic pulmonary hypertension is supported by observations that over time of exposure to hypoxia, acute reexposure to normal or even high levels of inspired oxygen becomes progressively less effective in reducing the pulmonary arterial pressure. This lack of responsiveness to oxygen, or even to other pulmonary vasodilators such as Ca2+ channel blockers, has led to the concept that chronic hypoxic pulmonary hypertension is associated with a "fixed" structural component responsible for the increased pulmonary vascular resistance. The structural changes thought to contribute to the increased vascular resistance have been broadly characterized into 2 processes: (1) inward remodeling of the pulmonary artery wall and (2) a reduction in the total number of small peripheral pulmonary arteries (a process referred to as rarefaction or pruning of the pulmonary vasculature).The work presented by Hyvel et al challenges, at least in certain ways, both of these concepts.3 Pulmonary vascular remodeling refers to a process that causes thickening of the arterial wall and is thought to increase resistance by physical encroachment of the lumen of small peripheral pulmonary arteries and arterioles. Because intimal thickening is not usually observed in hypoxic pulmonary hypertension, this reduction in luminal area is believed to be attributable largely to constrictive medial and adventitial thickening. However, using different lung preparation techniques than have been used in most other hypoxic studies (ie, the pulmonary vasculature was "maximally" vasodilated by perfusion with calcium-free plus EGTA physiological saline solution before the lungs were fixed by infusing paraformaldehyde into the trachea and pulmonary artery under "no flow" conditions at a defined transmural distending pressure that was constant at all points in the vasculature), the authors in this (and a previous) study have demonstrated that although some medial thickening clearly takes place in response to chronic hypoxia, there is, at least in this rat model, no reduction in the luminal area in vessels between 30 and 200 μm in diameter.3,4 Interestingly, this modest hypoxia-induced pulmonary vascular structural remodeling and absence of luminal narrowing in rats was previously reported by van Suylen et al, who also induced pulmonary vasodilation before lung fixation to abate any potential contribution of vasoconstriction to the observed pathologic changes5 (see Figure). Download figureDownload PowerPointSchematic representation of the apparent exaggeration of medial thickening and inward structural remodeling caused by sustained vasoconstriction of hypertensive small pulmonary arteries in the chronically hypoxic rat whose vessels were not completely vasodilated before fixation (top). Recent studies indicate that a substantial part of the increased pulmonary vascular resistance in chronically hypoxic rats is attributable to Rho kinase–mediated vasoconstriction, and that the distal pulmonary arteries of hypertensive lungs pharmacologically vasodilated before fixation show only modest medial wall thickening and little reduction of lumen area (bottom). Thus, the near complete reversal of chronic hypoxic pulmonary hypertension with Rho kinase inhibitors is attributable to the fact that there is little functionally significant "inward" remodeling.It is important to note that there are instances in the pulmonary circulation where remodeling (medial and adventitial thickening) of pulmonary resistance vessels occurs in the absence of significant pulmonary hypertension. For instance, in chronically-infected rat lungs pulmonary hypertension did not occur and right ventricular hypertrophy was not observed despite the appearance of thickened pulmonary vessel walls.6,7 Similar observations have been made in humans with chronic-obstructive pulmonary disease where marked thickening of the walls of the pulmonary arteries have been observed in the absence of pulmonary hypertension.8 One possible explanation for these findings is that thickening occurred in an outward direction such that it did not reduce the vascular lumen. This type of outward remodeling, called compensatory enlargement, has been well described in the systemic circulation.9,10 In fact, a dissociation between remodeling and pulmonary hypertension has been described. For instance, treatment of chronically hypoxic rats with angiotensin-converting enzyme inhibitors prevented pulmonary artery medial thickening but not the pulmonary hypertension or right-ventricular hypertrophy.5,11 Thus, we need to consider the possibility that under certain circumstances remodeling of the pulmonary vasculature does not cause luminal narrowing and increased vascular resistance, and chronic pulmonary hypertension can develop in the absence of inward or maladaptive vascular remodeling.It has been commonly accepted that the second major structural alteration caused by chronic hypoxia is loss of small peripheral pulmonary arteries, which increases resistance by reducing parallel vascular pathways.12–17 Traditionally, this rarefaction has been detected in barium-gelatin infused lungs as a reduction in the ratio of number of barium-filled blood vessels to number of alveoli in the intraacinar (gas exchange) region of the lung. However, using the techniques of quantitative stereology combined with confocal microscopy the McLaughlin group presents evidence for hypoxia-induced angiogenesis in the pulmonary circulation.3,4 This technique allows statistical inferences about the 3D structural parameters of objects based on 2D information such as that provided by histologic images, and has made it possible to measure the total length of intraacinar resistance vessels in the lung along with the total capillary surface area (parameters which have not traditionally been measured in most previous studies evaluating hypoxic pulmonary hypertension). Using these techniques, and also examining the pulmonary venules and gas exchange capillaries within the alveolar walls, areas again not usually examined in previous studies, the investigators have demonstrated that with chronic hypoxia the total combined length of the intraacinar arteries and venules increases rather than decreases. Stereologic examination also revealed an increase in total capillary lumen volume, total endothelial cell surface area, and total endothelial cell number. Whether these changes are "angiogenic" in the conventional sense is not clear, because absolute increases in vessel density have not been firmly established. However, these observations are certainly in contrast to the majority of previous reports and challenge the concept that the mature pulmonary circulation does not undergo new growth.There is previous experimental support for the idea that chronic hypoxia does not reduce pulmonary blood vessel number. Several studies of pulmonary hypertension in the rat have reported that the number of small pulmonary blood vessels is unaltered after chronic hypoxia18–22 or chronic inflammatory (monocrotaline-induced) lung disease.18 There are also other instances in which angiogenesis of the pulmonary circulation has been described. In adult dogs after pneumonectomy there is growth of new alveolar septa and alveolar capillaries in the residual left lung.23 Schraufnagel et al have reported evidence of pulmonary angiogenesis in the rat lung after induction of biliary cirrhosis.24 Schraufnagel has also suggested there is new vessel formation in the lungs of a patient with pulmonary venoocclusive disease.25 At least some metastatic tumors in the lung receive their blood supply either exclusively or predominately from the pulmonary circulation, again suggesting the ability of the pulmonary circulation to undergo an angiogenic response.26 In further support of the idea that pulmonary angiogenesis may occur in response to chronic hypoxia is the recent report from Pascaud et al, who found that angiostatin, an inhibitor of angiogenesis, aggravated pulmonary hypertension in the hypoxic lung.27 In addition, Beppu and colleagues have demonstrated hypoxia-induced capillary angiogenesis in the adult mouse lung.28 Collectively, these observations certainly raise the possibility that angiogenesis can, and does, occur in the mature pulmonary circulation in response to hypoxia and other pathophysiologic stimuli. This is not necessarily in conflict with evidence that the lung bronchial circulation may undergo even greater angiogenesis in response to similar stimuli.29The functional effects of these changes in capillary structure in the hypoxic lung are not entirely clear. There appears to be an increase in the total membrane diffusing capacity in chronic hypoxia, which could be attributable partly to the observed increase in total capillary volume. In addition, the increased capillary length caused by chronic hypoxia could prolong the time red blood cells spend in the alveolar capillaries at any given cardiac output, allowing more time for oxygen to equilibrate between alveolar gas and blood. However, whether any of these adaptations are real or pertinent to human hypoxic pulmonary hypertension is entirely unclear.Caution must be exercised in interpreting the results regarding pulmonary vascular remodeling and angiogenesis in the rat model. There is great variation in the magnitude of the pulmonary hypertensive response to chronic hypoxia in different species, as well as in individuals within a species. Age and sex also influence the response to stimuli causing pulmonary hypertension, including hypoxia. We have demonstrated, using techniques in which the possibility of vasoconstriction contributing to reduction of vascular luminal area is largely eliminated, that chronic hypoxic exposure in the neonatal calf leads to substantial decreases in the cross-sectional area of the lumen of small pulmonary arteries,30 suggesting that at least under some circumstances hypoxia can indeed lead to inward remodeling and structural encroachment on the vascular lumen. In this neonatal calf model, the proliferative response observed in both the media and adventitia far exceeds that which has been reported in the rat. Thus, in the presence of excessive vascular cell proliferation and extremely high pressures there may be instances where structural luminal narrowing is induced by hypoxia. Whether or not the high vascular resistance and pressure associated with this narrowing in the calf is susceptible to marked acute reversal by Rho kinase inhibitors as has been reported in the hypoxic rat model3,31,32 remains open to question.The current work and that of Nagaoka et al provide strong functional support for the morphological evidence discussed above that there is little, if any, inward structural remodeling and no significant loss of small pulmonary arteries in chronically hypoxic rats.3,31 Thus, both groups show that acute administration of a Rho kinase inhibitor nearly normalizes the increased pulmonary vascular resistance in both intact rats and isolated perfused lungs. The most likely explanation is that the increased pulmonary vascular resistance and pulmonary hypertension induced in adult male rats by up to 4 weeks of hypoxic exposure is attributable to sustained Rho kinase-mediated pulmonary vasoconstriction (Figure). The exact mechanisms of activation of Rho kinase in hypoxic rat lungs remain to be defined; Hyvel et al did not find activation of RhoA in whole lung tissue but Jernigan et al measured increased GTP-RhoA in hypertensive intrapulmonary arteries.33 Nagaoka et al have presented preliminary evidence that both endothelin-1 and serotonin may be involved in the sustained activation of RhoA/Rho kinase signaling in hypoxia-induced hypertensive rat pulmonary arteries.34There is now considerable evidence that activation of the small GTPase RhoA and its downstream effector Rho kinase, RhoA/Rho kinase signaling, is involved in regulation of numerous cellular responses, including actin polymerization, gene transcription, differentiation, growth, migration, and contraction.35 Rho kinase causes inactivation of myosin light-chain phosphatase leading to increased myosin light-chain phosphorylation and thus increased smooth-muscle contraction.36,37 This signaling pathway is particularly important in mediating sustained vasoconstriction by increasing the Ca2+ sensitivity of smooth muscle cell contraction, and its activation has been implicated in the pathogenesis of several systemic vascular diseases.36,37 The current article by Hyvel et al adds to a growing body of evidence that RhoA/Rho kinase signaling is also important in the pathogenesis of pulmonary hypertension, at least in rodents.31–33,38,39 As Fagan et al observed in mice, Hyvel et al show in rats that chronic treatment with a Rho kinase inhibitor attenuates development of hypoxic pulmonary hypertension.3,39 Prevention and reversal of rat monocrotaline-induced pulmonary hypertension by Rho kinase inhibition have also been reported.38The current report indicates RhoA/Rho kinase signaling is also possibly involved in the hypoxia-induced pulmonary capillary angiogenesis the McLoughlin group has previously reported, because treatment of hypoxic rats with the Rho kinase inhibitor attenuated both the pulmonary hypertension and the increases in total capillary length and volume.4 RhoA/Rho kinase signaling is certainly important in regulating endothelial cell morphogenesis, but how it might be involved in mediating the changes in pulmonary capillary structure in chronically hypoxic rats remains to be determined.In summary, the report by Hyvel and colleagues provides further evidence that chronic hypoxia-induced pulmonary hypertension in rats is associated with an increase in total cross-sectional area of the pulmonary microvascular bed rather than with a loss of small pulmonary arteries, and that sustained Rho kinase–mediated vasoconstriction, rather than inward structural remodeling of pulmonary arteries and arterioles, is the primary determinant of the increased pulmonary vascular resistance and pulmonary hypertension. Adventitial and medial thickening of muscular pulmonary arteries and muscularization of the normally nonmuscular pulmonary arterioles occurs, but how this contributes to the increased resistance is unclear. It is apparent that much of the controversy regarding the extent of structural inward remodeling and rarefaction of peripheral pulmonary arteries in chronically hypoxic (and also monocrotaline injected) rats is attributable to the failure to eliminate vasoconstriction (vasospasm) before and during lung fixation (Figure).4,5 In studies of resistance artery remodeling in systemic hypertension, it has long been appreciated that evaluation of the direct contribution of vascular structure to luminal narrowing, and therefore to vascular resistance, should be made only under conditions of complete lack of vascular tone, ie, under maximal vasodilation.40 The work of van Suylen et al and the McLoughlin group emphasizes that similar consideration should be applied to studies of vascular remodeling in pulmonary hypertension.3–5 Still, caution must be exercised in relating the findings obtained from relatively short-term hypoxic exposure of rats and mice to chronic human disease conditions where numerous other factors may play a role in the pulmonary hypertension and vascular remodeling associated with alveolar hypoxia.The opinions expressed in this editorial are not necessarily those of the editors or of the American Heart Association.This work was supported by National Institutes of Health SCOR Grant (HL-57144-09) and PPG Grant (HL-14985-33).FootnotesCorrespondence to Dr Kurt R. Stenmark, Professor of Pediatrics, University of Colorado Health Sciences Center, 4200 E. 9th Ave, Box B131, Denver, CO 80262. E-mail [email protected] References 1 Barbera JA, Peinado VI, Santos S. Pulmonary hypertension in chronic obstructive pulmonary disease. Eur Respir J. 2003; 21: 892–905.CrossrefMedlineGoogle Scholar2 Incalzi RA, Fuso L, De Rosa M, Di Napoli A, Basso S, Pagliari G, Pistelli R. Electrocardiographic signs of chronic cor pulmonale: a negative prognostic finding in chronic obstructive pulmonary disease. Circulation. 1999; 99: 1600–1605.CrossrefMedlineGoogle Scholar3 Hyvelin J-M, Howell K, Nichol A, Cosello CM, Preson RJ, McLoughlin P. Inhibition of Rho kinase attenuates hypoxia-induced angiogenesis in the pulmonary circulation. Circ Res. 2005; 97: 185–191.LinkGoogle Scholar4 Howell K, Preston RJ, McLoughlin P. Chronic hypoxia causes angiogenesis in addition to remodelling in the adult rat pulmonary circulation. J Physiol. 2003; 547: 133–145.CrossrefMedlineGoogle Scholar5 van Suylen RJ, Smits JFM, Daemen MJAP. Pulmonary artery remodeling differes in hypoxia- and monocrotaline-induced pulmonary hypertension. Am J Respir Crit Care Med. 1998; 157: 1423–1428.CrossrefMedlineGoogle Scholar6 Cadogan E, Hopkins N, Giles S, Bannigan J, Moynihan J, McLoughlin P. Enhanced expression of inducible nitric oxide synthase without vasodilator effect in chronically infected lung. Am J Physiol. 1999; 277: L616–L627.CrossrefMedlineGoogle Scholar7 Graham LM, Vasil A, Vasil ML, Voelkel NF, Stenmark KR. Decreased pulmonary vasoreactivity in an animal model of chronic Pseudomonas pneumonia. Am Rev Respir Dis. 1990; 142: 221–229.CrossrefMedlineGoogle Scholar8 Wright JL, Lawson L, Pare PD, Hooper RO, Peretz DI, Nelems JM. Schulzer M, Hogg JC. The structure and function of the pulmonary vasculature in mild chronic obstructive pulmonary disease. The effect of oxygen and exercise. Am Rev Respir Dis. 1983; 128: 702–707.MedlineGoogle Scholar9 Gibbons GH, Dzau VJ. The emerging concept of vascular remodeling. N Engl J Med. 1994; 330: 1431–1438.CrossrefMedlineGoogle Scholar10 Glagov S, Weisenberg E, Zarins CK, Stankunavicius R, Kolettis GJ. Compensatory enlargement of human atherosclerotic coronary arteries. N Engl J Med. 1993; 22: 1371–1375.Google Scholar11 Clozel JP, Saunier C, Hartemann D, Fischli W. Effects of cilazapril, a novel angiotensin converting enzyme inhibitor, on the structure of pulmonary arteries of rats exposed to chronic hypoxia. J Cardiovasc Pharmacol. 1991; 17: 36–40.CrossrefMedlineGoogle Scholar12 Hislop A, Reid L. New findings in pulmonary arteries of rats with hypoxia-induced pulmonary hypertension. Br J Exp Pathol. 1976; 57: 542–554.MedlineGoogle Scholar13 Rabinovitch M, Gamble W, Nadas AS, Miettinen OS, Reid L. Rat pulmonary circulation after chronic hypoxia: hemodynamic and structural features. Am J Physiol. 1979; 236: H818–H827.MedlineGoogle Scholar14 Meyrick B, Brigham KL. Repeated. Escherichia coli endotoxin-induced pulmonary inflammation causes chronic pulmonary hypertension in sheep. Structural and functional changes. Lab Invest. 1986; 55: 164–176.MedlineGoogle Scholar15 Meyrick B, Gamble W, Reid L. Development of Crotalaria pulmonary hypertension: hemodynamic and structural study. Am J Physiol. 1980; 239: H692–H702.CrossrefMedlineGoogle Scholar16 Meyrick B, Reid L. Pulmonary hypertension. Anatomic and physiologic correlates. Clin Ches Med. 1983; 4: 199–217.CrossrefMedlineGoogle Scholar17 Jones R, Reid L. Vascular remodeling in clinical and experimental pulmonary hypertensions. In: Bishop JE, Reeves JT, Laurent GJ, eds. Pulmonary Vascular Remodeling. London: Portland Press Ltd; 1995: 47–116.Google Scholar18 Kay JM, Suyama KL, Keane PM. Failure to show decrease in small pulmonary blood vessels in rats with experimental pulmonary hypertension. Thorax. 1982; 37: 927–930.CrossrefMedlineGoogle Scholar19 Finlay M, Barer GR, Suggett AJ. Quantitative changes in the rat pulmonary vasculature in chronic hypoxia –relation to haemodynamic changes. Quart J Exp Physiol. 1986; 71: 151–163.CrossrefMedlineGoogle Scholar20 Meyrick B, Reid L. Hypoxia and incorporation of 3H-thymidine by cells of the rat pulmonary arteries and alveolar wall. Am J Pathol. 1979b; 96: 51–70.MedlineGoogle Scholar21 Emery CJ, Bee D, Barer GR. Mechanical properties and reactivity of vessels in isolated perfused lungs of chronically hypoxic rats. Clin Sci (Colch). 1981; 61: 569–580.CrossrefGoogle Scholar22 Mooi W, Wagenvoort CA. Decreased numbers of pulmonary blood vessels: reality or artifact? J Pathol. 1983; 141: 441–447.CrossrefMedlineGoogle Scholar23 Hopkins N, Cadogan E, Giles S, McLoughlin P. Chronic airway infection leads to angiogenesis in the pulmonary circulation. J Appl Physiol. 2001; 91: 919–928.CrossrefMedlineGoogle Scholar24 Schraufnagel DE, Malik R, Goel V, Ohara N, Chang SW. Lung capillary changes in hepatic cirrhosis in rats. Am J Physiol. 1997; 272: L139–147.MedlineGoogle Scholar25 Schraufnagel DE, Sekosan M, McGee T, Thakkar MB. Human alveolar capillaries undergo angiogenesis n pulmonary veno-occlusive disease. Eur Respir J. 1996; 9: 346–350.CrossrefMedlineGoogle Scholar26 Milne EN, Zerhouni EA. Blood supply of pulmonary metastases. J Thorac Imaging. 1987; 2: 15–23.CrossrefMedlineGoogle Scholar27 Pascaud MA, Griscelli F, Raoul W, Marcos E, Opolon P, Raffestin B, Perricaudet M, Adnot S, Eddahibi S. Lung overexpression of angiostatin aggravates pulmonary hypertension in chronically hypoxic mice. Am J Respir Cell Mol Biol. 2003; 29: 449–457.CrossrefMedlineGoogle Scholar28 Beppu H, Ichinose F, Kawai N, Jones RC, Yu PB, Zapol WM, Miyazono K, Li E, Bloch KD. BMPR-II heterozygous mice have mild pulmonary hypertension and an impaired pulmonary vascular remodeling response to prolonged hypoxia. Am J Physiol Lung Cell Mol Physiol. 2004; 287: L1241–L1247.CrossrefMedlineGoogle Scholar29 Mitzner W, Wagner EM. Vascular remodeling in the circulations of the lung. J Appl Physiol. 2004; 97: 1999–2004.CrossrefMedlineGoogle Scholar30 Durmowicz AG, Orton EC, Stenmark KR. Progressive loss of vasodilator responsive component of pulmonary hypertension in neonatal calves exposed to 4,570 m. Am J Physiol. 1993; 265: H2175–H2183.MedlineGoogle Scholar31 Nagaoka T, Fagan KA, Gebb SA, Morris KG, Suzuki T, Shimokawa H, McMurtry IF, Oka M. Inhaled Rho kinase inhibitors are potent and selective vasodilators in rat pulmonary hypertension. Am J Respir Crit Care Med. 2005; 171: 494–499.CrossrefMedlineGoogle Scholar32 Nagaoka T, Morio Y, Casanova N, Bauer N, Gebb S, McMurtry I, Oka M. Rho/Rho kinase signaling mediates increased basal pulmonary vascular tone in chronically hypoxic rats. Am J Physiol Lung Cell Mol Physiol. 2004; 287: L665–L672.CrossrefMedlineGoogle Scholar33 Jernigan NL, Walker BR, Resta TC. Chronic hypoxia augments protein kinase G-mediated Ca2 desensitization in pulmonary vascular smooth muscle through inhibition of RhoA/Rho kinase signaling. Am J Physiol Lung Cell Mol Physiol. 2004; 287: L1220–L1229.CrossrefMedlineGoogle Scholar34 Nagaoka T, Morio Y, Oka M, McMurtry IF. Endothelin-1 and serotonin are involved in Rho-kinase-mediated augmented pressor response to KCl in chronically hypoxic hypertensive rat lungs (abstract). Am J Respir Crit Care Med. 2003; 167: A697.Google Scholar35 Riento K, Ridley AJ. ROCKS: multifunctional kinases in cell behavior. Nat Rev Mol Cell Biol. 2003; 4: 446–456.CrossrefMedlineGoogle Scholar36 Shimokawa H. Rho-kinase as a novel therapeutic target in treatment of cardiovascular diseases. J Cardiovasc Pharmacol. 2002; 39: 319–327.CrossrefMedlineGoogle Scholar37 Somlyo AP, Somlyo AV. Ca2 sensitivity of smooth muscle and nonmuscle myosin II: modulated by G proteins, kinases, and myosin phosphatase. Physiol Rev. 2003; 83: 1325–1358.CrossrefMedlineGoogle Scholar38 Abe K, Shimokawa H, Morikawa K, Uwatoku T, Oi K, Matsumoto Y, Hattori T, Nakashima K, Kaibuchi K Takeshita A. Long-term treatment with a Rho-kinase inhibitor improves monocrotaline-induced fatal pulmonary hypertension in rats. Circ Res. 2004; 94: 358–393.Google Scholar39 Fagan KA, Oka M, Bauer NR, Gebb SA, Ivy DD, Morris KG, McMurtry IF. Attenuation of acute hypoxic pulmonary vasoconstriction and hypoxic pulmonary hypertension in mice by inhibition of Rho-kinase. Am J Physiol Lung Cell Mol Physiol. 2004; 287: L656–L664.CrossrefMedlineGoogle Scholar40 Bund SJ, Lee RMKW. Arterial structural changes in hypertension: a consideration of methodology, terminology and functional consequence. J Vasc Res. 2003; 40: 547–557.CrossrefMedlineGoogle Scholar Previous Back to top Next FiguresReferencesRelatedDetailsCited By Lee M and Tuder R (2022) Pathology of Pulmonary Arterial Hypertension Encyclopedia of Respiratory Medicine, 10.1016/B978-0-08-102723-3.00057-3, (516-529), . Penumatsa K, Singhal A, Warburton R, Bear M, Bhedi C, Nasirova S, Wilson J, Qi G, Preston I, Hill N, Fanburg B, Kim Y and Toksoz D (2022) Vascular smooth muscle ROCK1 contributes to hypoxia-induced pulmonary hypertension development in mice, Biochemical and Biophysical Research Communications, 10.1016/j.bbrc.2022.02.064, 604, (137-143), Online publication date: 1-May-2022. Bagali S and Das K (2021) Hypoxia and its preconditioning on cardiac and vascular remodelling in experimental animals, Respiratory Physiology & Neurobiology, 10.1016/j.resp.2020.103588, 285, (103588), Online publication date: 1-Mar-2021. Liu H, Wang N, Li J, Wang W, Han W and Li Q (2021) AAV1-Mediated shRNA Knockdown of SASH1 in Rat Bronchus Attenuates Hypoxia-Induced Pulmonary Artery Remodeling , Human Gene Therapy, 10.1089/hum.2020.242, 32:15-16, (796-805), Online publication date: 1-Aug-2021. Diaz G, Marquez A, Ruiz-Parra A, Beghetti M and Ivy D (2021) An Acute Hyperoxia Test Predicts Survival in Children with Pulmonary Hypertension Living at High Altitude, High Altitude Medicine & Biology, 10.1089/ham.2021.0026, 22:4, (395-405), Online publication date: 1-Dec-2021. Li J, Jia M, Liu M, Cao Z, Wang X, Feng N, Gu X, Zhang S, Fan R, Guo H, Wang Y, Liu M and Pei J (2020) The effect of activated κ-opioid receptor (κ-OR) on the role of calcium sensing receptor (CaSR) in preventing hypoxic pulmonary hypertension development, Biomedicine & Pharmacotherapy, 10.1016/j.biopha.2020.109931, 125, (109931), Online publication date: 1-May-2020. Garat C, Majka S, Sullivan T, Crossno J, Reusch J and Klemm D (2020) CREB depletion in smooth muscle cells promotes medial thickening, adventitial fibrosis and elicits pulmonary hypertension, Pulmonary Circulation, 10.1177/2045894019898374, 10:2, (1-15), Online publication date: 1-Apr-2020. Tuder R and Stenmark K (2020) Perspective: pathobiological paradigms in pulmonary hypertension, time for reappraisal, American Journal of Physiology-Lung Cellular and Molecular Physiology, 10.1152/ajplung.00067.2020, 318:6, (L1131-L1137), Online publication date: 1-Jun-2020. Shimoda L (2020) Cellular Pathways Promoting Pulmonary Vascular Remodeling by Hypoxia, Physiology, 10.1152/physiol.00039.2019, 35:4, (222-233), Online publication date: 1-Jul-2020. Mu Y, Huang Q, Zhu J, Zheng S, Yan F, Zhuang X, Sham J and Lin M (2018) Magnesium attenuates endothelin-1-induced vasoreactivity and enhances vasodilatation in mouse pulmonary arteries: Modulation by chronic hypoxic pulmonary hypertension, Experimental Physiology, 10.1113/EP086655, 103:4, (604-616), Online publication date: 1-Apr-2018. Maston L, Jones D, Giermakowska W, Resta T, Ramiro‐Diaz J, Howard T, Jernigan N, Herbert L, Maurice A
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