Marjan Boerma

Radiation-Related Heart Disease: Current Knowledge and Future Prospects

INTRODUCTIONIt has been recognized since the 1960s that the heart may bedamaged by substantial doses of radiation [>30 Gray (Gy)],such as used to occur during mantle radiotherapy for Hodg-kin lymphoma. During the last few years, however, evidencethat radiation-related heart disease (RRHD) can occur fol-lowing doses below 20 Gy has emerged from several inde-pendent sources. Those sources include studies of breastcancer patients who received mean cardiac doses of 3 to 17Gy when given radiotherapy following surgery and studiesof survivors of the atomic bombings of Japan who receiveddoses of up to 4 Gy.At doses above 30 Gy, an increased risk of RRHD can be-comes apparent within a year or two of exposure, and the riskincreases with higher radiotherapy dose, younger age at irra-diation, and the presence of conventional risk factors. Atlower doses, the typical latency period is much longer andis often more than a decade. The nature and magnitude ofthe risk following lower doses is not well characterized,and it is not yet clear whether there is a threshold dose belowwhich there is no risk.The evidence regarding RRHD comes from several differ-ent disciplines. The present review brings together informa-tion from pathology, radiobiology, cardiology, radiationoncology, and epidemiology; it summarizes current knowl-edge, identifies gaps in that knowledge, and outlines somepotential strategies for filling them.CURRENT KNOWLEDGEPathologyThe pathological expressions of RRHD documented fol-lowing therapeutic irradiation can be broadly reduced tofour conditions: pericarditis, pericardial fibrosis, diffusemyocardial fibrosis, and coronary artery disease (CAD)(1, 2). Radiation may also cause valvular disease, althoughtheevidence for this isnotasstrong.None of these conditionsis specific to radiation.Radiation-related pericarditis is characterized by an exu-date of a variable amount of protein-rich fluid within thepericardial sac (pericardial effusion). Rapid accumulationof this fluid can, in rare cases, cause potentially fatal cardiactamponade. Almost invariably, fibrin accumulates on the

γ-Tocotrienol Ameliorates Intestinal Radiation Injury and Reduces Vascular Oxidative Stress after Total-Body Irradiation by an HMG-CoA Reductase-Dependent Mechanism

Abstract Berbée, M., Fu, Q., Boerma, M., Wang, J., Kumar, K. S. and Hauer-Jensen, M. γ-Tocotrienol Ameliorates Intestinal Radiation Injury and Reduces Vascular Oxidative Stress after Total-Body Irradiation by an HMG-CoA Reductase-Dependent Mechanism. Radiat. Res. 171, 596–605 (2009). Analogs of vitamin E (tocols) are under development as radioprophylactic agents because of their high efficacy and lack of toxicity. Gamma-tocotrienol (GT3) is of particular interest because, in addition to being an antioxidant, it also inhibits 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase and accumulates to greater extent in endothelial cells than other tocols. We addressed in vivo whether HMG-CoA reductase inhibition contributes to the radioprotection conferred by GT3. Groups of mice were treated with vehicle, mevalonate (the product of the reaction catalyzed by HMG-CoA reductase), GT3 alone or GT3 in combination with mevalonate. Lethality and standard parameters of injury to the hematopoietic, intestinal and vascular/endothelial systems were assessed after exposure to total-body irradiation. GT3 improved postirradiation survival and decreased radiation-induced vascular oxidative stress, an effect that was reversible by mevalonate. GT3 also enhanced hematopoietic recovery, reduced intestinal radiation injury, and accelerated the recovery of soluble markers of endothelial function. These parameters were not reversed by mevalonate co-administration. Our data confirm GT3s radioprophylactic properties against hematopoietic injury and, for the first time, demonstrate benefits in terms of protection against gastrointestinal and vascular injury. The radioprotective efficacy of GT3 against vascular injury is related to its properties as an HMG-CoA reductase inhibitor.

Prevention and Treatment of Functional and Structural Radiation Injury in the Rat Heart by Pentoxifylline and Alpha-Tocopherol

PURPOSE Radiation-induced heart disease (RIHD) is a severe side effect of thoracic radiotherapy. This study examined the effects of pentoxifylline (PTX) and alpha-tocopherol on cardiac injury in a rat model of RIHD. METHODS AND MATERIALS Male Sprague-Dawley rats received fractionated local heart irradiation with a daily dose of 9 Gy for 5 days and were observed for 6 months after irradiation. Rats were treated with a combination of PTX, 100 mg/kg/day, and alpha-tocopherol (20 IU/kg/day) and received these compounds either from 1 week before until 6 months after irradiation or starting 3 months after irradiation, a time point at which histopathologic changes become apparent in our model of RIHD. RESULTS Radiation-induced increases in left ventricular diastolic pressure (in mm Hg: 35 +/- 6 after sham-irradiation, 82 +/- 11 after irradiation) were significantly reduced by PTX and alpha-tocopherol (early treatment: 48 +/- 7; late treatment: 53 +/- 6). PTX and alpha-tocopherol significantly reduced deposition of collagen types I (radiation only: 3.5 +/- 0.2 mum(2) per 100 mum(2); early treatment: 2.7 +/- 0.8; late treatment: 2.2 +/- 0.2) and III (radiation only: 13.9 +/- 0.8; early treatment: 11.0 +/- 1.2; late treatment: 10.6 +/- 0.8). On the other hand, radiation-induced alterations in heart/body weight ratios, myocardial degeneration, left ventricular mast cell densities, and most echocardiographic parameters were not significantly altered by PTX and alpha-tocopherol. CONCLUSIONS Treatment with PTX and alpha-tocopherol may have beneficial effects on radiation-induced myocardial fibrosis and left ventricular function, both when started before irradiation and when started later during the process of RIHD.

Comparative gene expression profiling in three primary human cell lines after treatment with a novel inhibitor of Rho kinase or atorvastatin.

Inhibitors of Rho kinase (ROCK) are a relatively new class of drugs with potential benefits in oncology, neurology, and fibrotic and cardiovascular diseases. ROCK inhibitors modulate many cellular functions, some of which are similar to the pleiotropic effects of statins, suggesting additive or synergistic properties. Studies to date have used compounds that inhibit both isoforms of ROCK, ROCK1 and ROCK2. This study was designed to compare gene expression profiles of atorvastatin with the newly developed ROCK2 inhibitor SLx-2119 in primary cultures of normal human endothelial cells, smooth muscle cells, and fibroblasts. Cells were treated with each compound for 24 h, after which total RNA was isolated and genome-wide gene-expression profiles were obtained with Illumina arrays. Because of the known effect of statins on the actin cytoskeleton and on connective tissue growth factor, a prominent growth factor involved in tissue fibrosis, the effects of SLx-2119 and atorvastatin on the actin cytoskeleton and connective tissue growth factor mRNA were also examined in cultures of smooth muscle cells with a fibrotic phenotype, isolated from biopsies of human intestine with radiation-induced fibrosis. Although SLx-2119 and atorvastatin affected expression of genes belonging to the same biological processes, individual genes were mostly different, consistent with synergistic or additive properties. Both SLx-2119 and atorvastatin reduced connective tissue growth factor mRNA and remodeled the actin cytoskeleton in fibrosis-derived smooth muscle cells, suggesting that both compounds have antifibrotic properties. These results form the basis for further studies to assess the possible therapeutic benefit of combined treatments.

Radiation damage to the gastrointestinal tract: mechanisms, diagnosis, and management.

Purpose of reviewTo summarize current knowledge about gastrointestinal radiation toxicity, with emphasis on mechanisms and clinical diagnosis and management. Recent findingsWhile there has been only modest change in cancer incidence and cancer mortality rates during the past 30 years, the number of cancer survivors has more than doubled. Moreover, the recognition of uncomplicated cancer cure as the ultimate goal in oncology has intensified efforts to prevent, diagnose, and manage side effects of radiation therapy. These efforts have been facilitated by recent insight into the underlying pathophysiology. SummaryThe risk of injury to the intestine is dose limiting during abdominal and pelvic radiation therapy. Delayed bowel toxicity is difficult to manage and adversely impacts the quality of life of cancer survivors. More than 200 000 patients per year receive abdominal or pelvic radiation therapy, and the estimated number of cancer survivors with postradiation intestinal dysfunction is 1.5–2 million. Worthwhile progress towards reducing toxicity of radiation therapy has been made by dose-sculpting treatment techniques. Approaches derived from an improved understanding of the pathophysiology of bowel injury, however, will result in further advances. This article discusses the mechanisms of radiation-induced bowel toxicity and reviews current principles in diagnosis and management.

Microarray analysis of gene expression profiles of cardiac myocytes and fibroblasts after mechanical stress, ionising or ultraviolet radiation

BackgroundDuring excessive pressure or volume overload, cardiac cells are subjected to increased mechanical stress (MS). We set out to investigate how the stress response of cardiac cells to MS can be compared to genotoxic stresses induced by DNA damaging agents. We chose for this purpose to use ionising radiation (IR), which during mediastinal radiotherapy can result in cardiac tissue remodelling and diminished heart function, and ultraviolet radiation (UV) that in contrast to IR induces high concentrations of DNA replication- and transcription-blocking lesions.ResultsCultures enriched for neonatal rat cardiac myocytes (CM) or fibroblasts were subjected to any one of the three stressors. Affymetrix microarrays, analysed with Linear Modelling on Probe Level, were used to determine gene expression patterns at 24 hours after (the start of) treatment. The numbers of differentially expressed genes after UV were considerably higher than after IR or MS. Remarkably, after all three stressors the predominant gene expression response in CM-enriched fractions was up-regulation, while in fibroblasts genes were more frequently down-regulated. To investigate the activation or repression of specific cellular pathways, genes present on the array were assigned to 25 groups, based on their biological function. As an example, in the group of cholesterol biosynthesis a significant proportion of genes was up-regulated in CM-enriched fractions after MS, but down-regulated after IR or UV.ConclusionGene expression responses after the types of cellular stress investigated (MS, IR or UV) have a high stressor and cell type specificity.

Increased deposition of von Willebrand factor in the rat heart after local ionizing irradiation

Background and Purpose:Von Willebrand factor (vWf), a glycoprotein involved in blood coagulation, is synthesized by endothelial cells. Increased amounts of vWf in blood plasma or tissue samples are indicative of damaged endothelium. In the present study, mRNA expression and localization of vWf were determined in irradiated rat heart tissue.Material and Methods:Sprague-Dawley rats received local heart irradiation with a single dose of 0, 15, or 20 Gy. Hearts were dissected at different time points (up to 16 months) after irradiation. In a second experiment, rats were injected with the radioprotector amifostine (160 mg/kg, i. p.) 15–20 min before irradiation and sacrificed after 6 months. Immunohistochemistry was performed using a polyclonal anti-vWf antibody. Serial sections were subjected to a general rat endothelial cell immunostaining (RECA-1) or a collagen staining (picrosirius red). mRNA expression was determined by using PCR.Results:In control tissue, all endothelial cells lining the lumen of the endocardium and coronary arteries, but not capillary endothelial cells, were stained for vWf. 1 month after irradiation with both 15 and 20 Gy, myocardial capillaries became immunoreactive. From 3 months onward, staining was observed also within the extracellular matrix (ECM) of fibrotic areas. At mRNA level, no changes in vWf could be observed at all time points after irradiation, suggesting that vWf deposition was not due to increased biosynthesis of the protein. In sections of amifostine-treated rat hearts, vWf staining was increased to a lesser extent.Conclusion:These dose- and time-dependent increases in deposition of vWf indicate the presence of damaged endothelium in the irradiated rat heart. These increases in vWf accumulation precede development of fibrosis in the subendocardial layer and myocardium of the left ventricles, right ventricles, and atria.Hintergrund und Ziel:Das Glykoprotein Von-Willebrand-Faktor (VWF) spielt eine wichtige Rolle bei der Blutgerinnung und wird durch Endothelzellen synthetisiert. Erhöhte VWF-Konzentrationen im Blutplasma oder in Gewebeproben weisen auf geschädigtes Endothel hin. In der hier vorgestellten Studie werden die mRNA-Expression und VWF-Lokalisation im Gewebe bestrahlter Rattenherzen bestimmt.Material und Methodik:Sprague-Dawley-Ratten erhielten eine lokale Bestrahlung des Herzens mit einer Dosis von 0, 15 oder 20 Gy. Die Herzen wurden zu definierten Zeitpunkten von bis zu 16 Monaten nach der Bestrahlung seziert. In einem zweiten Experiment wurden Ratten seziert, denen 15–20 min vor der Bestrahlung der Radioprotektor Amifostin (160 mg/kg, i. p.) injiziert worden war. Immunhistochemische Tests wurden unter Verwendung des polyklonalen Anti-VWF-Antikörpers durchgeführt. Serielle Schnitte wurden einer allgemeinen Ratten-Endothelzellen-Immunfärbung (RECA-1) oder Kollagenfärbung (Picrosirius-Rot) unterzogen. Die mRNA-Expression wurde mittels PCR bestimmt.Ergebnisse:Im Kontrollgewebe wurden alle Endothelzellen des Endokards und der Kranzarterien, nicht jedoch die Endothelzellen der Kapillargefäße auf VWF gefärbt. 1 Monat nach Bestrahlung mit 15 und 20 Gy wurden die Kapillaren des Myokards immunreaktiv. Nach Zeiträumen von ≥ 3 Monaten ließ sich auch eine Färbung der extrazellulären Matrix (ECM) innerhalb fibrotischer Bereiche beobachten. Bezüglich des mRNA-Levels konnten unabhängig vom Zeitpunkt der Untersuchung nach der Bestrahlung keine Veränderungen für den VWF festgestellt werden. Dies lässt vermuten, dass die VWF-Deposition nicht auf eine erhöhte Biosynthese des Proteins zurückzuführen ist. In den Schnitten der mit Amifostin behandelten Rattenherzen war die Zunahme der VWF-Färbung weniger ausgeprägt.Schlussfolgerung:Die von der Strahlendosis und Zeit abhängige Zunahme der VWF-Einlagerung deutet auf das Vorliegen von geschädigtem Endothel in den bestrahlten Rattenherzen hin. Die Zunahme der VWF-Akkumulation geht der Fibrosierung in der Subendokardschicht und im Myokard der linken und rechten Ventrikel sowie im Atrium voraus.

Radiation responses in skin and connective tissues: effect on wound healing and surgical outcome

Radiation therapy, either alone or in combination with other types of treatment, is responsible for 40% of cancer cures and 70% of all cancer patients receive radiation therapy at some point during the course of their disease. Radiation therapy has profound effects, both acute and long-term, on skin and connective tissues. Radiation therapy also affects the time course and end result of wound healing, and the risk of postoperative complications. For example, radiation therapy of tumors in the abdomen or in the abdominal wall inevitably affects the integrity of abdominal wall structures and may adversely affect the outcome of operations on the abdominal wall, for example hernia surgery. All surgeons will encounter patients who have undergone or will receive radiation therapy. In these situations, it is important to carefully consider the optimum timing of surgery relative to radiation therapy, to decide which perioperative precautions are needed to minimize the risk of complications, to estimate and inform the patient about the increased risk of complications, and, if surgery is done before a planned course of radiation therapy, to consider how soon after surgery it is safe to commence the radiation treatment. This review will (1) describe features of acute and long term radiation-induced changes in skin and connective tissues; (2) provide a brief overview of the biological mechanisms underlying these changes; and (3) discuss practical considerations that have direct relevance to surgical decision making and postoperative outcome.

Comparative expression profiling in primary and immortalized endothelial cells: changes in gene expression in response to hydroxy methylglutaryl-coenzyme A reductase inhibition.

Immortalized cell lines offer significant logistical advantages over primary cells when used for in-vitro studies. Immortalized cells may, however, exhibit important differences relative to their primary cell counterparts. In this study, microarrays were used to make a genome-wide comparison between primary human umbilical vein endothelial cells (HUVECs) and EA.hy926, an immortalized HUVEC cell line, in their baseline properties and in their response to inhibition of the mevalonate pathway with an inhibitor of hydroxy methylglutaryl-coenzyme A reductase (statin). HUVECs and EA.hy926 were incubated with control medium, atorvastatin, mevalonate, or a combination of atorvastatin and mevalonate for 24 h. Gene expression profiles were obtained in duplicates using Affymetrix Human Genome U133A 2.0 arrays (Santa Clara, California, USA). Probe-sets were selected according to the following criteria: a twofold or greater increase/decrease in atorvastatin-treated cells compared with untreated cells; a twofold or greater reversal of the effect of atorvastatin by combined treatment with atorvastatin and mevalonate; no significant change in gene expression in cells treated with mevalonate alone compared with untreated cells. Most genes that were expressed by untreated HUVECs, were also expressed by untreated EA.hy926 cells. EA.hy926 cells, however, constitutively expressed a large number of additional genes, many of which were related to cell cycle control and apoptosis. Atorvastatin induced differential expression (≥ twofold) of 103 genes in HUVECs (10 up, 93 down) and 466 genes in EA.hy926 cells (198 up, 268 down). Applying the above selection criteria, thrombomodulin and tissue plasminogen activator were up-regulated in both cell types, whereas, connective tissue growth factor, thrombospondin-1, and cysteine-rich angiogenic inducer 61 were down-regulated. In conclusion, EA.hy926 cells retain most of the characteristics of endothelial cells under baseline conditions as well as after treatment with atorvastatin. It is necessary, however, to carefully select and validate changes in genes that are the focus of studies when using EA.hy926 cells. While this cell line is highly useful in studies on some genes, including genes encoding molecules involved in regulating thrombohemorrhagic homeostasis, they appear to be less suited for studies focused on other genes, particularly those involved in the regulation of cell proliferation and apoptosis.

Influence of Mast Cells on Structural and Functional Manifestations of Radiation-Induced Heart Disease

Radiation-induced heart disease (RIHD), characterized by accelerated atherosclerosis and adverse tissue remodeling, is a serious sequelae after radiotherapy of thoracic and chest wall tumors. Adverse cardiac remodeling in RIHD and other cardiac disorders is frequently accompanied by mast cell hyperplasia, suggesting that mast cells may affect the development of cardiac fibrosis. This study used a mast cell-deficient rat model to define the role of mast cells in RIHD. Mast cell-deficient rats (Ws/Ws) and mast cell-competent littermate controls (+/+) were exposed to 18 Gy localized single-dose irradiation of the heart. Six months after irradiation, cardiac function was examined by echocardiography and Langendorff-perfused isolated heart preparation, whereas structural changes were assessed using quantitative histology and immunohistochemical analysis. Mast cell-deficient rats exhibited more severe postradiation changes than mast cell-competent littermates. Hence, mast cell-deficient rats exhibited a greater upward/leftward shift in the left ventricular (LV) diastolic pressure-volume relationship (P = 0.001), a greater reduction in in vivo LV diastolic area (from 0.50 +/- 0.024 cm in age-matched controls to 0.24 +/- 0.032 cm after irradiation; P = 0.006), and a greater increase in LV posterior wall thickness (from 0.13 +/- 0.003 cm in age-matched controls to 0.15 +/- 0.003 cm after irradiation; P = 0.04). Structural analysis revealed more pronounced postradiation accumulation of interstitial collagen III but less myocardial degeneration in hearts from mast cell-deficient rats. These data show that the absence of mast cells accelerates the development of functional changes in the irradiated heart, particularly diastolic dysfunction, and suggest that, in contrast to what has been the prevailing assumption, the role of mast cells in RIHD is predominantly protective.