Pulmonary Vascular Biology Research Articles

The Intersection of HIV and Pulmonary Vascular Health: From HIV Evolution to Vascular Cell Types to Disease Mechanisms.

People living with HIV (PLWH) face a growing burden of chronic diseases, owing to the combinations of aging, environmental triggers, lifestyle choices, and virus-induced chronic inflammation. The rising incidence of pulmonary vascular diseases represents a major concern for PLWH. The study of HIV-associated pulmonary vascular complications ideally requires a strong understanding of pulmonary vascular cell biology and HIV pathogenesis at the molecular level for effective applications in infectious diseases and vascular medicine. Active HIV infection and/or HIV proteins disturb the delicate balance between vascular tone and constriction, which is pivotal for maintaining pulmonary vascular health. One of the defining features of HIV is its high genetic diversity owing to several factors including its high mutation rate, recombination between viral strains, immune selective pressures, or even geographical factors. The intrinsic HIV genetic diversity has several important implications for pathogenic outcomes of infection and the overall battle to combat HIV. Challenges in the field present themselves from two sides of the same coin: those imposed by the virus itself and those stemming from the host. The field may be advanced by further developing in vivo and in vitro models that are well described for both pulmonary vascular diseases and HIV for mechanistic studies. In essence, the study of HIV-associated pulmonary vascular complications requires a multidisciplinary approach, drawing upon insights from both infectious diseases and vascular medicine. In this review article, we discuss the fundamentals of HIV virology and their impact on pulmonary disease, aiming to enhance the understanding of either area or both simultaneously. Bridging the gap between preclinical research findings and clinical practice is essential for improving patient care. Addressing these knowledge gaps requires interdisciplinary collaborations, innovative research approaches, and dedicated efforts to prioritize HIV-related pulmonary complications on the global research agenda.

Mitochondrial Dynamics in Pulmonary Hypertension.

Mitochondria are essential organelles for energy production, calcium homeostasis, redox signaling, and other cellular responses involved in pulmonary vascular biology and disease processes. Mitochondrial homeostasis depends on a balance in mitochondrial fusion and fission (dynamics). Mitochondrial dynamics are regulated by a viable circadian clock. Hypoxia and nicotine exposure can cause dysfunctions in mitochondrial dynamics, increases in mitochondrial reactive oxygen species generation and calcium concentration, and decreases in ATP production. These mitochondrial changes contribute significantly to pulmonary vascular oxidative stress, inflammatory responses, contractile dysfunction, pathologic remodeling, and eventually pulmonary hypertension. In this review article, therefore, we primarily summarize recent advances in basic, translational, and clinical studies of circadian roles in mitochondrial metabolism in the pulmonary vasculature. This knowledge may not only be crucial to fully understanding the development of pulmonary hypertension, but also greatly help to create new therapeutic strategies for treating this devastating disease and other related pulmonary disorders.

Therapeutic options for chronic kidney disease-associated pulmonary hypertension.

Pulmonary hypertension is a common and devastating complication of chronic kidney disease (CKD). Traditionally considered a consequence of volume overload, recent findings now expand this paradigm. These novel mechanisms herald new treatment options. This review summarizes the current evidence to provide a theoretical model of the contributing factors for CKD-associated pulmonary hypertension. Along this framework, we highlight current and emerging therapeutic strategies for each putative factor. A series of retrospective studies of right heart catheterization data provide insights into the potential hemodynamic profile of CKD-associated pulmonary hypertension. These studies suggest that elevated pulmonary vascular resistance may commonly contribute to pulmonary hypertension. In addition, preclinical models implicate an increasing array of CKD-associated factors which influence pulmonary vascular biology. Many of these factors also adversely affect kidney function and CKD progression. Clinical trial and other prospective data for treatments of CKD-associated pulmonary hypertension remain limited. Volume overload and left-ventricular dysfunction are the predominant focus of CKD-associated pulmonary hypertension treatment for most patients. However, new findings suggest that treatments targeting pulmonary vascular vasoconstriction and remodeling may be promising treatment options for select patients. Clinical trials are needed for all therapeutic strategies for CKD-associated pulmonary hypertension.

Impacts of high altitude on pulmonary vascular biology and related diseases

Impacts of high altitude on pulmonary vascular biology and related diseases

2018 AHA Late-Breaking Basic Science Abstracts.

2018 AHA Late-Breaking Basic Science Abstracts.

Pulmonary Hypertension Roundtable: Conference Impressions and Applications

Guest Editor and Conference Scientific Sessions Chair Vinicio de Jesus Perez assembled a group of attendees to discuss their experiences at PHA's International Conference and Scientific Sessions in Orlando in June 2018. Participating in the conversation were Zhiyu Dai, PhD, Research Assistant Professor in the Department of Pediatrics at Northwestern University Feinberg School of Medicine, Chicago; Elena Goncharova, PhD, Associate Professor of Medicine and Bioengineering and head of PH Basic Research, Center for Pulmonary Vascular Biology and Medicine, Pulmonary, Allergy & Critical Care Division, University of Pittsburgh Department of Medicine; Kara Goss, MD, Assistant Professor, Division of Allergy, Pulmonary and Critical Care, University of Wisconsin, Madison; and Tim Lahm, MD, Associate Professor, Department of Medicine, Indiana University School of Medicine. Adding to the conversation was Jair Tonorio, PhD, Research Associate, Hospital Universitario La Paz, Madrid, Spain.

Pulmonary vascular disease in bronchopulmonary dysplasia

Pulmonary hypertension contributes significantly to morbidity and mortality of chronic lung disease of infancy, or bronchopulmonary dysplasia (BPD). Advances in pulmonary vascular biology over the past few decades have led to new insights into the pathogenesis of BPD; however, many unique issues persist regarding our understanding of pulmonary vascular development and disease in preterm infants at risk for chronic lung disease. Recent studies have highlighted the important contribution of the developing pulmonary circulation to lung growth in the setting of preterm birth. These studies suggest that there is a spectrum of pulmonary vascular disease (PVD) in BPD rather than a simple question of whether or not pulmonary hypertension is present. Epidemiological studies underscore gaps in our understanding of PVD in the context of BPD, including universally accepted definitions, approaches to diagnosis and treatment, and patient outcomes. Unfortunately, therapeutic strategies for pulmonary hypertension in BPD are based on small observational studies with poorly defined endpoints and rely on results from older children and adult studies. Yet, unique characteristics of this population create other potential risks for the adoption of these strategies. Despite many recent advances, PVD remains an important contributor to poor outcomes in preterm infants with BPD. Substantial challenges persist, especially with regard to understanding mechanisms and the clinical approach to PVD. Future studies are needed to develop evidence-based definitions and clinical endpoints through which the pathophysiology can be investigated and potential therapeutic interventions evaluated.

MicroRNA in the Diseased Pulmonary Vasculature: Implications for the Basic Scientist and Clinician.

Since the first descriptions of their active functions more than ten years ago, small non-coding RNA species termed microRNA (miRNA) have emerged as essential regulators in a broad range of adaptive and maladaptive cellular processes. With an exceptionally rapid pace of discovery in this field, the dysregulation of many individual miRNAs has been implicated in the development and progression of various cardiovascular diseases. MiRNA are also expected to play crucial regulatory roles in the progression of pulmonary vascular diseases such as pulmonary hypertension (PH), yet direct insights in this field are only just emerging. This review will provide an overview of pulmonary hypertension and its molecular mechanisms, tailored for both basic scientists studying pulmonary vascular biology and physicians who manage PH in their clinical practice. We will describe the pathobiology of pulmonary hypertension and mechanisms of action of miRNA relevant to this disease. Moreover, we will summarize the potential roles of miRNA as biomarkers and therapeutic targets as well as future strategies for defining the cooperative actions of these powerful effectors in pulmonary vascular disease.

Whole exome sequencing to identify a novel gene (caveolin-1) associated with human pulmonary arterial hypertension.

Heritable and idiopathic pulmonary arterial hypertension (PAH) are phenotypically identical and associated with mutations in several genes related to transforming growth factor (TGF) beta signaling, including bone morphogenetic protein receptor type 2, activin receptor-like kinase 1, endoglin, and mothers against decapentaplegic 9. Approximately 25% of heritable cases lack identifiable mutations in any of these genes. We used whole exome sequencing to study a 3-generation family with multiple affected family members with PAH, but no identifiable TGF beta mutation. We identified a frameshift mutation in caveolin-1 (CAV1), which encodes a membrane protein of caveolae abundant in the endothelium and other cells of the lung. An independent de novo frameshift mutation was identified in a child with idiopathic PAH. Western blot analysis demonstrated a reduction in caveolin-1 protein, while lung tissue immunostaining studies demonstrated a reduction in normal caveolin-1 density within the endothelial cell layer of small arteries. Our study represents successful elucidation of a dominant Mendelian disorder using whole exome sequencing. Mutations in CAV1 are associated in rare cases with PAH. This may have important implications for pulmonary vascular biology, as well as PAH-directed therapeutic development.

Recent progress in understanding pediatric pulmonary hypertension

Pulmonary artery hypertension (PAH) in children contributes significantly to morbidity and mortality in diverse pediatric cardiac, lung, hematologic and other diseases. Advances in pulmonary vascular biology over the past few decades have significantly expanded therapeutic strategies; however, many unique issues persist regarding our understanding of pediatric PAH. Recent studies of pediatric PAH include those that highlight gaps in our understanding of pediatric diseases associated with PAH from those of adult onset, emphasizing the strong need for specific studies regarding unique aspects of the pathogenesis and treatment of children with PAH. Registries have begun to provide new data showing differences in physiology, course, and genetics between adult and pediatric forms of PAH. Unfortunately, therapeutic strategies in pediatric pulmonary hypertension are often limited to small observational studies in children and are dependent on results from larger adult studies. In addition, clinical endpoints for studies and care remain poorly defined in infants and children. Despite many advances, long-term outcomes for children with PAH remain guarded and substantial challenges persist, especially with regard to understanding mechanisms and approach to severe PAH. Future studies are needed to develop novel biomarkers, clinical endpoints and interventions for young children with diverse causes of PAH.

Vaikų plautinė hipertenzija

Straipsnyje supažindinama su vaikų plautinės hipertenzijos klasifikacija, diagnostika, simptomais, gydymo galimybėmis.

Pulmonary hypertension in children: A historical overview

Pulmonary arterial hypertension in children contributes significantly to morbidity and mortality in diverse pediatric cardiac, lung, hematologic, and other diseases. Pulmonary arterial hypertension is generally a disease of small pulmonary arteries characterized by vascular narrowing due to high-tone and abnormal vasoreactivity, structural remodeling of the vessel wall, intraluminal obstruction, and decreased vascular growth and surface area. Without therapy, high pulmonary vascular resistance contributes to progressive right ventricular failure, low cardiac output, and death. Advances in basic pulmonary vascular biology over the last few decades have led directly to several novel therapies, which have significantly expanded therapeutic choices and have led to improved survival and quality of life of many children with pulmonary arterial hypertension. Despite these improvements, long-term outcomes in many settings remain guarded and substantial challenges persist, especially with regard to understanding mechanisms and approach to structural remodeling of severe pulmonary arterial hypertension.

Conference Faculty

Surgical InfectionsVol. 7, No. s1 Conference FacultyPublished Online:10 Oct 2006https://doi.org/10.1089/sur.2006.7.s1-3AboutSectionsPDF/EPUB Permissions & CitationsPermissionsDownload CitationsTrack CitationsAdd to favorites Back To Publication ShareShare onFacebookTwitterLinked InRedditEmail "Conference Faculty." , 7(S1), p. s3FiguresReferencesRelatedDetailsCited byThe enhanced permeability retention effect: a new paradigm for drug targeting in infection10 October 2012 | Journal of Antimicrobial Chemotherapy, Vol. 68, No. 2Role for Staphylococci in Misguided Thrombus Resolution of Chronic Thromboembolic Pulmonary HypertensionArteriosclerosis, Thrombosis, and Vascular Biology, Vol. 28, No. 4 Volume 7Issue s1Jan 2006 Information© 2006 Mary Ann Liebert, Inc.To cite this article:Conference Faculty.Surgical Infections.Jan 2006.s3-s3.http://doi.org/10.1089/sur.2006.7.s1-3Published in Volume: 7 Issue s1: October 10, 2006PDF download

The endothelin system and its role in pulmonary arterial hypertension (PAH)

Endothelin receptor antagonists represent a major advance in the treatment of PAH but much remains to be learned of their effectiveness in specific forms of pulmonary hypertension The endothelin system is emerging as an important mediator in pulmonary arterial hypertension (PAH) and the endothelin receptor antagonists represent a major advance in the treatment of this condition. PAH results from a massive proliferation of myofibroblast cells in the intima of small pulmonary arteries. Thickening of the media is also observed and abnormal proliferation of endothelial cells may result in plexiform lesions. The endothelin system has been extensively studied over the 15 years since its initial discovery by Yanagisawa and co-workers in 1988. It is clear that endothelin 1 (ET-1) is a key mediator of pulmonary vascular biology and pathophysiology. It is a powerful vasoconstrictor and proliferative cytokine. In the early 1990s ET-1 was identified as an important mediator of PAH. Plasma ET-1 levels were found to be elevated in patients with pulmonary hypertension and correlated with the raised pulmonary vascular resistance.1 Furthermore, expression of ET-1 mRNA and protein was increased in endothelial cells comprising vascular lesions in primary pulmonary hypertension.2 The availability of ET-1 receptor antagonists allowed testing of these compounds in experimental models. In rat models of experimental pulmonary hypertension—including pulmonary hypertension induced by chronic (2–3 weeks) hypoxia3 and by the alkaloid monocrotaline—ET-1 antagonists prevent the development of PAH. More compelling is the finding that ET-1 antagonists can partly reverse established PAH in experimental models.4 These observations suggest that ET-1 antagonists can potentially reverse established pulmonary vascular remodelling rather than simply prevent vasoconstriction.5 In clinical PAH the main component of the increased pulmonary vascular resistance is remodelling rather than vasoconstriction. However, in animal models the predominant lesion is medial hypertrophy rather than intimal thickening, and …

Making Up and Breaking Up

The concept that blood pressure influences vessel wall composition and structure is well established. Any alterations in stretch (caused by changes in blood pressure) solicit counteracting radial and tangential forces, driving transformations in the vessel wall that aim to accommodate the new conditions and to ultimately restore basal levels of tensile stress.1–3 Thus, when tensile stress increases because of a rise in arterial pressure, smooth muscle cell hypertrophy and collagen and elastin contents augment. Inversely, when the circumferential stress falls, the wall undergoes atrophy.4,5 See page 957 Understanding how vessel wall remodeling occurs is valuable because it relies on the delicate balance between restructuralization and overcompensation. For instance, vascular accumulation of type I, III, and IV collagen in hypertensive patients6 and in animal models of hypertension7,8 effectively counteracts the distending force of blood pressure, but at length it also results in increased vascular stiffness. Clinically, vascular stiffness translates to greater pulse wave velocity, which is an independent predictor of mortality in patients with end-stage renal failure, hypertension, and diabetes, as well as in older individuals.9 In this issue of Atherosclerosis, Thrombosis and Vascular Biology , Jackson et al10 show that the opposite holds true for vessels in which axial tension is off-loaded. In rabbit carotid arteries elongated by interposition of the contralateral carotid artery, the authors found that tortuosity caused by loss of axial strain was not rectified in the months that followed the intervention. Smooth muscle cell proliferation was observed, but this was offset by equivalent cell apoptosis. Likewise, elastin and collagen accumulation was countered by matrix metalloproteinase (MMP) upregulation and activation. But on close observation of the extracellular matrix (ECM), it became apparent that the fenestrae of the internal elastic laminae were greatly enlarged, and indeed the authors found that …

A novel mechanism for pulmonary arterial hypertension?

The pathophysiology of primary pulmonary hypertension (PPH) involves alterations in vascular reactivity, vascular structure, and interactions of the vessel wall with circulating blood elements.1 An imbalance of vasodilator and vasoconstrictor influences is likely to be an early derangement. Progressive intimal and medial thickening, due to proliferation and migration of vascular smooth muscle cells and fibroblasts, reduces the cross-sectional area of the pulmonary microvasculature, causing fixed alterations in pulmonary resistance. Contributing to the progressive increase in pulmonary resistance is thrombosis of the small pulmonary vessels, which explains the benefit of anticoagulation in these patients. In advanced disease, “plexiform arteriopathy” of the small pulmonary vessels is observed. These lesions proliferate into the lumen, creating high-resistance, convoluted endoluminal channels. There is some controversy regarding the nature of the cells constituting these lesions, one group suggesting they are of endothelial origin, whereas more recent evidence indicates that they are myofibroblasts.2,3 See p 1493 The normal pulmonary endothelium maintains a low vascular resistance, suppresses vascular smooth muscle growth, inhibits platelet adherence and aggregation, and stems inflammation. In patients with PPH, the endothelium has lost these vasoprotective functions.1 The endothelium of the PPH patient is characterized by the increased elaboration of vasoconstrictors, mitogens, and prothrombotic and proinflammatory mediators (such as thromboxane, endothelin, plasminogen activator inhibitor, and 5-lipooxygenase). These endothelial alterations promote the pathophysiology of PPH. Furthermore, there is less influence of the countervailing factors prostacyclin and NO. Endothelium-derived NO plays a critical role in pulmonary …

Recent insights into the pathogenesis and therapeutics of pulmonary hypertension

The normal adult pulmonary circulation is a low-pressure, high-capacity circuit. Pulmonary vascular resistance is regulated by alveolar oxygen tension, potassium channels and a variety of locally produced and circulating vasoactive factors. Perturbations of these systems may contribute to the pathogenesis of pulmonary hypertension. Recently, mutations in BMPR2 and ALK-1, genes that encode members of the transforming growth factor-beta (TGF-beta) receptor superfamily, have been found in patients with primary pulmonary hypertension. These observations provide a novel insight into the pathogenesis of primary pulmonary hypertension, and emphasize the importance of the integrity of the TGF-beta receptor family in the maintenance of normal pulmonary vascular structure and function. This review discusses the latest developments in the field of pulmonary vascular biology and the prospects for improving the treatment of pulmonary hypertension.

Endothelin Receptor Antagonism: A New Era in the Treatment of Pulmonary Arterial Hypertension

Abstract The endothelin system has been extensively studied over the last several years. It is clear that endothelin-1 (ET-1) is a key mediator in pulmonary vascular biology and physiology. Abnormal increases in ET-1 production and decreased pulmonary clearance appear to play a major pathogenetic and perpetuating role in the pulmonary hypertensive process, through their vasconstrictive, smooth muscle cell proliferative and profibrotic effects. The degree of overexpression of ET-1 may correlate with the severity of pulmonary hypertension (PH). Advances in understanding the role of ET-1 in pulmonary hypertension have driven the development of endothelin receptor antagonists. One such agent, bosentan (Tracleer), is FDA approved for pulmonary arterial hypertension. Bosentan was approved following two randomized, placebo-controlled, double-blind studies that both showed marked improvement in exercise capacity after treatment with bosentan. The beneficial effects of bosentan appear to be sustained in most patients followed for as long as 22 months. Other uses for endothelin receptor antagonists are being examined, such as in combination with epoprostenol (Flolan) or in pediatric PH patients.

Primary pulmonary hypertension: a vascular biology and translational research "Work in progress".

Primary pulmonary hypertension (PPH) is a syndrome of dyspnea, chest pain, and syncope defined by increased pulmonary vascular resistance and the absence of a known cause. It also occurs in a familial form, which is linked to unidentified genes on chromosome 2. This syndrome is characterized by abnormalities of pulmonary vascular biology in each compartment of the blood vessel. The lumen has a prothrombotic diathesis, the endothelium displays an excessive production of vasoconstrictors relative to vasodilators, and the smooth muscle cells are depolarized and calcium-overloaded, which is due in part to reduced expression of voltage-gated potassium channels (Kv). This causes vasoconstriction and may promote cell proliferation. The adventitia displays excessive remodeling, which is associated with exaggerated metalloproteinase and elastase activity. Conceptually, PPH seems to require a permissive genotype, a susceptible phenotype (eg, endothelial dysfunction) and, in many cases, an exogenous trigger (eg, an anorexigen). Although there is not a generally accepted, unifying hypothesis regarding its cause, impaired function and the expression of vascular and platelet Kv channels suggest PPH may be a disease of the ion channels. Abnormal matrix metalloproteinase and elastase activity could also explain the abnormal vascular tone, platelet activation, and remodeling in PPH. Although calcium-channel blockers and prostacyclin, particularly when coadministered with warfarin, improve survival, PPH has a 5-year mortality rate of approximately 50%. Pharmacological and gene therapies aimed at enhancing the activity of prostacyclin, nitric oxide synthases, and Kv channels or at inhibiting endothelin and matrix metalloproteinases are promising areas for future development.

Series introduction: tissue ischemia: pathophysiology and therapeutics

This issue of the JCI contains the first articles in a Perspective series that focuses on ischemia, the major cause of mortality in the developed world. The specific mechanisms and consequences of ischemia differ in each tissue or organ, which reflects differences in anatomy and physiology. For this reason, the series has been organized to include articles on cerebral (Dennis Choi and colleagues), myocardial (Sandy Williams and Ivor Benjamin), and skeletal muscle (Jeff Isner) ischemia, as well as discussions of ischemia in epithelial tissues (Sanjay Nigam and colleagues) and hypoxia-induced pulmonary vascular remodeling (Norbert Voelkel and Rubin Tuder). In each case, the authors present a balanced overview of the field and focus on an area of particular interest, such as the contribution of excitatory neurotransmitter release to the pathogenesis of cerebral infarction, the protective effect of heat shock proteins (HSPs) in myocardial ischemia, the role of VEGF in ischemia-induced angiogenesis, the disruptive effects of ischemia on epithelial barrier function, or the effects of hypoxia on pulmonary vascular biology. Most of the research discussed employs tissue culture or small animal model systems and reflects the expectation that insights into basic pathophysiology will offer a foundation for designing therapeutics. Despite the variability of responses to ischemia in various tissues, several general therapeutic strategies can be considered regardless of the anatomical site of ischemia. Ischemia arises when tissue demand for energy substrates (primarily O2 and glucose) is not matched by supply, usually due to impaired perfusion. Thus, ischemia can be prevented or eliminated, in principle, by decreasing demand or increasing supply. As discussed by Williams and Benjamin, decreased demand occurs in the case of hibernating myocardium, in which the ATP-consuming process of contractility is inhibited to minimize O2 and glucose consumption. Global inhibition of myocardial or cerebral function is unlikely to represent a viable therapeutic strategy, but the alternative of increasing supply to these tissues seems feasible, for example, by therapeutic angiogenesis (see Perspective by Isner). DNA- or protein-based clinical trials involving VEGF, other angiogenic factors, or mediators of their production are currently underway. Another approach is to prevent the death of ischemic tissue, i.e., infarction. A major focus of investigation has been the preconditioning phenomena that have been demonstrated in virtually every organ, including the heart and brain. Thus, exposure of an organ or tissue to one or more brief episodes of ischemia will provide protection against subsequent prolonged ischemia that would otherwise result in infarction. The preconditioning stimulus provides an immediate but short-lived “first window” of protection, which occurs over a period of minutes to hours and requires the altered activity of pre-existing proteins, as well as a delayed but sustained “second window” of protection, which persists over a period of hours to days and depends on new protein synthesis. Considerable progress has been made in elucidating the signal transduction pathways that mediate these adaptive responses, as described in the Perspectives by Choi’s group and by Williams and Benjamin. A pharmacologic agent capable of activating a preconditioning pathway would, of course, have tremendous therapeutic potential. A third approach is to target for inhibition or induction a specific gene or protein product that is known to promote ischemia or to protect against infarction. The analysis of knockout and transgenic mice has provided a wealth of data regarding genes that, when inactivated or activated, either promote or protect against cerebral or myocardial infarction. The interpretation of these data, however, is not always entirely straightforward. For example, the Nos2 gene encoding inducible nitric oxide synthase is required for late-phase cardiac preconditioning, but NOS2-deficient mice develop smaller cerebral infarctions than their wild-type littermates in response to cerebral arterial occlusion. Thus, NOS2 may help to protect preconditioned animals and also, paradoxically, promote infarction in non-preconditioned animals. Transgenic models have demonstrated that overexpression of HSPs, such as HSP70, provides protection against ischemia in the myocardium (as described by Williams and Benjamin) and in epithelial tissues (as discussed by Nigam and colleagues). Examples of potentially useful pharmacologic inhibitors have come from animal models of hypoxia-induced pulmonary hypertension, in which treatment with angiotensin-converting enzyme inhibitors or endothelin receptor ETA antagonists can prevent or reverse vascular remodeling. However, as Voelkel and Tuder explain, it is not entirely clear to which clinical conditions the rodent model is relevant. The present Perspective series on ischemia has notable parallels to the excellent JCI Perspective series on cancer therapy that was recently edited by Bill Kaelin (December 1999–January 2000). For both ischemic and neoplastic disorders, we are accumulating an impressive fund of knowledge regarding pathophysiology. Although the articles in the present series on ischemia demonstrate the enormous complexity of the disease processes under investigation, the challenge to each investigator and reader of the JCI remains to build this growing investment into clinical dividends, in the form of novel and effective therapeutics.