Femoral or Axillary Cannulation for Extracorporeal Circulation during Minimally Invasive Heart Valve Surgery (FAMI): Protocol for a Multi-Center Prospective Randomized Trial.

BACKGROUND: Minimally invasive heart valve surgery via anterolateral mini-thoracotomy with full endoscopic 3D visualization (MIS) has become the standard treatment of patients with valvular heart disease and low operative risk over the past two decades. It requires extracorporeal circulation and cardioplegic arrest. The most established form of arterial cannulation for MIS is through the femoral artery and is used by most surgeons, but it is suspected to increase the risk of stroke through retrograde blood flow. An alternative route of cannulation is the axillary artery, producing antegrade blood flow during extracorporeal circulation. METHODS: Femoral or axillary cannulation for extracorporeal circulation during minimally invasive heart valve surgery (FAMI) is a multicenter randomized controlled trial designed to determine whether axillary cannulation is superior to femoral cannulation for the outcome of a manifest stroke within 7 days postoperatively. The target sample size was 848 participants. Patients ≥ 18 years of age, with valvular regurgitation or stenosis scheduled for minimally invasive surgery via anterolateral mini-thoracotomy, were randomized to axillary cannulation (treatment group) or to femoral cannulation (standard care). Patients were followed up for seven days postoperatively. A CT scan was performed pre-operatively to screen patients for vascular calcifications and to assess the safety of femoral cannulation. The standard of care is femoral artery cannulation, but is performed only in patients without significant vascular calcifications or severe kinking of the iliac arteries and in patients with sufficient vessel diameter. The cannulation is performed via Seldinger's technique, and the vessel closed percutaneously using a plug-based vascular closure device. Only patients without significant vascular calcifications are considered for femoral cannulation, as an increased risk of stroke is assumed. In patients with vascular calcifications, axillary cannulation is the standard of care to avoid these risks. Retrospective studies have hinted that, even in patients without vascular calcifications, there may be a lower stroke risk with axillary cannulation compared to femoral cannulation. We present a protocol for a multi-center randomized trial to investigate this hypothesis. DISCUSSION: To date, evidence on the best access for peripheral artery cannulation during minimally invasive heart valve surgery has been scarce. Patients may benefit from axillary cannulation for extracorporeal circulation in terms of stroke risk and other neurological and vascular complications, though femoral cannulation is the gold standard. The aim of this study is to determine the risks of peri-operative stroke in a prospective randomized comparison of femoral vs. axillary cannulation.

Radiation-induced activation of TGF-beta signaling pathways in relation to vascular damage in mouse kidneys.

The purpose of this study was to investigate the long-term effects of radiation-induced alterations in TGF-beta signaling pathways with respect to the development of vascular damage in the irradiated kidney. Total RNA was isolated from mouse kidneys at 1-30 weeks after irradiation, and quantitative real-time PCR analyses were performed for TGF-beta receptors (ALK1, ALK5, endoglin), downstream mediators (Smad7, CTGF), and downstream targets (PAI-1 and Id-1). Expression of endoglin and Smad7 protein as well as nucleo-cytoplasmic distribution of phospho Smad 2/3 and phospho Smad 1/5 was analyzed by immunohistochemistry. Radiation caused a rapid and persistent increase in expression of TGF-beta receptors and mediators from 1-30 weeks after treatment. Expression of Id-1, a downstream target of endothelial cell specific receptor ALK1, was transiently increased (1-10 weeks after irradiation) but returned to control levels at later times. Expression of PAI-1, a downstream target of ALK5, increased progressively from 10-30 weeks after irradiation. These results show that radiation activated TGF-beta signaling pathways in the kidney and shifted the balance in favor of ALK5 signaling, which generally inhibits endothelial cell proliferation and migration. We hypothesize that prolonged activation of ALK5 signaling and relative suppression of ALK1 signaling may provide an explanation for the telangiectatic phenotype observed in irradiated kidneys.

Ionizing radiation shifts the PAI-1/ID-1 balance and activates notch signaling in endothelial cells.

PURPOSE: Transforming growth factor-beta (TGF-beta) and Notch signaling pathways are important regulators of vascular homeostasis and vessel remodeling; mutations in these pathways can lead to vascular disorders. Similar vascular phenotypes develop in the normal tissues of cancer patients as a long-term effect of radiotherapy. Irradiation most severely affects the capillaries, which become leaky and dilated and might eventually rupture. To investigate the mechanism of such capillary damage, we studied the effect of TGF-beta and Notch signaling in microvascular endothelial cells. METHODS AND MATERIALS: Human microvascular endothelial cells were irradiated with 5 or 10 Gy and activation of TGF-beta and Notch signaling pathways was assessed by biochemical methods and a cell migration assay. RESULTS: Ionizing radiation induced Smad2 phosphorylation and nuclear translocation and increased mRNA and protein expression of the activin-like kinase 5 (ALK5) target gene plasminogen activator inhibitor-1 (PAI-1). At the same time, we observed diminished Smad1/5/8 activation and downregulation of the ALK1 downstream target, inhibitor of DNA binding-1 (ID-1). We also measured an upregulation of the Notch ligand Jagged-1 and the target gene Hey1. Decreased inhibitor of DNA binding-1 levels coincided with a reduced ability of the cells to migrate. CONCLUSION: Ionizing radiation shifts the balance from ALK1 to ALK5 signaling and activates the Notch pathway in endothelial cells. This combination of anti-angiogenic signals contributes to reduced cell migration after irradiation.

Fractalkine: an important candidate for directing periglomerular leukocyte accumulation in irradiated mouse kidneys.

Radiation-induced impairment of renal function is preceded by capillary endothelial cell damage, which initiates a cascade of inflammatory and thrombotic events. Accumulation of leukocytes in the irradiated kidney, especially in areas surrounding the glomeruli, has been clearly demonstrated. The chemokine fractalkine has recently been identified as a key mediator of leukocyte adhesion that functions without the requirement of integrins or selectin-mediated rolling. In this study we investigate the possible involvement of fractalkine in the inflammatory response of the irradiated kidney. Mouse kidneys were irradiated with single doses of 16 or 0 Gy, and protein and mRNA levels of fractalkine and PECAM-1 were examined after 10 to 40 weeks. These changes were correlated with the progressive increase and distribution of leukocytes in the irradiated kidneys. Increased fractalkine immunoreactivity was seen at glomerular sites 30 to 40 weeks after irradiation. This fractalkine expression was strongly associated with the presence of leukocytes surrounding the Bowman's capsule of the same glomeruli. No significant changes in mRNA levels of fractalkine were seen in whole kidney extracts after irradiation, but expression levels were not determined for isolated glomeruli. PECAM-1 protein levels did not change with time after irradiation, although a significant decrease in mRNA expression was seen at 10 weeks. This study is the first demonstration of increased fractalkine after irradiation and the results suggest that fractalkine may be an important mechanism of leukocyte trafficking in the development of a radiation induced inflammatory response.

Gene expression arrays as a tool to unravel mechanisms of normal tissue radiation injury and prediction of response.

Over the past 5 years there has been a rapid increase in the use of microarray technology in the field of cancer research. The majority of studies use microarray analysis of tumor biopsies for profiling of molecular characteristics in an attempt to produce robust classifiers for prognosis. There are now several published gene sets that have been shown to predict for aggressive forms of breast cancer, where patients are most likely to benefit from adjuvant chemotherapy and tumors most likely to develop distant metastases, or be resistant to treatment. The number of publications relating to the use of microarrays for analysis of normal tissue damage, after cancer treatment or genotoxic exposure, is much more limited. A PubMed literature search was conducted using the following keywords and combination of terms: radiation, normal tissue, microarray, gene expression profiling, prediction. With respect to normal tissue radiation injury, microarrays have been used in three ways: (1) to generate gene signatures to identify sensitive and resistant populations (prognosis); (2) to identify sets of biomarker genes for estimating radiation exposure, either accidental or as a result of terrorist attack (diagnosis); (3) to identify genes and pathways involved in tissue response to injury (mechanistic). In this article we will review all (relevant) papers that covered our literature search criteria on microarray technology as it has been applied to normal tissue radiation biology and discuss how successful this has been in defining predisposition markers for radiation sensitivity or how it has helped us to unravel molecular mechanisms leading to acute and late tissue toxicity. We also discuss some of the problems and limitations in application and interpretation of such data.

A portrait of cisplatin-induced transcriptional changes in mouse embryonic stem cells reveals a dominant p53-like response.

Accumulation of damage in undifferentiated cells may threaten homeostasis and regenerative capacity. Remarkably, p53 has been suggested to be transcriptionally inactive in these cells. To gain insight in the kinetics and interplay of the predominant transcriptional responses of DNA damage signalling pathways in undifferentiated cells, mouse embryonic stem cells were exposed to cisplatin at four different time points (2, 4, 8 and 24h) and concentrations (1, 2, 5 and 10 microM). RNA was isolated and subjected to genome-wide expression profiling. Up to one fourth of the tested genes could be identified as being differentially expressed (false discovery rate=10%) after the cisplatin treatment. Clustering of the expression changes showed a strong time dependency. To investigate the relationship between affected genes, a gene set analysis method was used. Functionally related gene sets were defined using gene ontologies or transcription factor binding sites and were tested for overrepresentation within the differentially expressed genes. A variety of gene sets were clearly enriched among which 'apoptosis' and 'cell cycle' were the most pronounced. Furthermore, there was a strong enrichment of genes with a p53-binding motif. The involvement of the 'cell cycle' and 'apoptosis' gene sets in the cisplatin response was detected at concentrations and time points where the respective biological assays were still negative. The results reveal novel insights into the mechanisms which maintain the genomic integrity in undifferentiated cells. Additionally the results illustrate that gene set analysis of genome-wide expression changes provides a sensitive instrument to detect cellular stress responses to DNA damage.

Ionizing radiation accelerates the development of atherosclerotic lesions in ApoE-/- mice and predisposes to an inflammatory plaque phenotype prone to hemorrhage.

After radiotherapy treatment, there is an increased incidence of localized atherosclerosis in patients with Hodgkin's disease, breast cancer, and head and neck cancer. Here, we established a mouse model to study the development and progression of radiation-induced atherosclerosis and to compare the phenotype of these lesions with age-related atherosclerosis. Atherosclerosis-prone ApoE-/- mice fed a regular chow diet received single radiation doses of 14 Gy or sham treatments (0 Gy) to the neck, including both carotid arteries. At 22, 28, and 34 weeks after irradiation, blood samples were taken, and the arterial tree was removed for histological examination. Cholesterol levels in irradiated mice were not significantly different from age-matched controls, and markers of systemic inflammation (soluble intercellular adhesion molecule-1, soluble vascular cell adhesion molecule-1, and C-reactive protein) were not elevated. The lesions in irradiated arteries were macrophage rich, with a remarkable influx of inflammatory cells, predominantly granulocytes. Intraplaque hemorrhage and erythrocyte-containing macrophages were seen only in lesions of irradiated arteries. Based on these data, we propose that irradiation accelerates the development of macrophage-rich, inflammatory atherosclerotic lesions prone to intraplaque hemorrhage.

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.

Microarray analysis to identify molecular mechanisms of radiation-induced microvascular damage in normal tissues.

PURPOSE: Radiation-induced vascular injury can be a serious problem for cancer survivors. In capillary vessels, this manifests as telangiectasia, causing cosmetic problems when occurring in the skin and more serious problems, e.g. excessive bleeding requiring surgery, when occurring in rectal or bladder mucosa. In addition, thrombotic, inflammatory, and fibrogenic events play an important role in the development of late radiation injury in many tissues. However, the sequence of these events and the relationship between various mechanistic pathways is unclear. The purpose of this project is to identify genes that are differentially expressed in tissues with manifest vascular damage, with the ultimate goal of intervening in this process to block the progressive development of tissue injury. METHODS AND MATERIALS: Microarray experiments were performed using amplified RNA isolated from irradiated mouse kidney and rectum, and from sham-irradiated controls, at 10 and 20 weeks after treatment. Tissue samples were also taken for histologic evaluation of vascular damage at 10, 20, and 30 weeks after irradiation. Expression profiles for irradiated and sham-irradiated samples were compared, and differentially expressed genes were identified after normalization procedures, using information from straight color, color reverse, and self-self experiments. The extent of overlap in expression profiles for kidney and rectum during the phase of vascular damage was also examined. RESULTS: The mouse kidney experiments showed upregulation of 31 genes at 10 weeks and 42 upregulated genes at 20 weeks. Only 20 genes showed significantly increased expression at both time points. Some of these genes were of particular interest in terms of their known involvement in vascular injury and signal transduction pathways. Irradiated mouse rectum had 278 upregulated genes at 10 weeks and 86 upregulated genes at 20 weeks. Only 19 of the genes upregulated during the period of identified telangiectasia (10-20 weeks) were common to both tissues. These included jagged 1 and Kruppel-like factor 5 (KLF5), which are reported to play a role in vascular development and remodeling. CONCLUSIONS: Microarray analysis of RNA from irradiated normal tissues is an effective tool for identifying new genes of potential interest in the development of late tissue injury. Such experiments should be regarded as generating testable hypotheses for mechanisms of radiation-induced injury.

Identification of differentially expressed genes in mouse kidney after irradiation using microarray analysis.

Irradiation of the kidney induces dose-dependent, progressive renal functional impairment, which is partly mediated by vascular damage. The molecular mechanisms underlying the development of radiation-induced nephropathy are unclear. Given the complexity of radiation-induced responses, microarrays may offer new opportunities to identify a wider range of genes involved in the development of radiation injury. The aim of the present study was to determine whether microarrays are a useful tool for identifying time-related changes in gene expression and potential mechanisms of radiation-induced nephropathy. Microarray experiments were performed using amplified RNA from irradiated mouse kidneys (1 x 16 Gy) and from sham-irradiated control tissue at different intervals (1-30 weeks) after irradiation. After normalization procedures (using information from straight-color, color-reverse and self-self experiments), the differentially expressed genes were identified. Control and repeat experiments were done to confirm that the observations were not artifacts of the array procedure (RNA amplification, probe synthesis, hybridizations and data analysis). To provide independent confirmation of microarray data, semi-quantitative PCR was performed on a selection of genes. At 1 week after irradiation (before the onset of vascular and functional damage), 16 genes were significantly up-regulated and 9 genes were down-regulated. During the period of developing nephropathy (10 to 20 weeks), 31 and 42 genes were up-regulated and 9 and 4 genes were down-regulated. At the later time of 30 weeks, the vast majority of differentially expressed genes (191 out of 203) were down-regulated. Potential genes of interest included TSA-1 (also known as Ly6e) and Jagged 1 (Jag1). Increased expression of TSA-1, a member of the Ly-6 family, has previously been reported in response to proteinuria. Jagged 1, a ligand for the Notch receptor, is known to play a role in angiogenesis, and is particularly interesting in the context of radiation-induced vascular injury. The present study demonstrates the potential of microarrays to identify changing patterns of gene expression in irradiated kidney. Further studies will be required to evaluate functional involvement of these genes in vascular-mediated normal tissue injury.

Effects of amifostine on radiation-induced cardiac damage.

The purpose of this study was to investigate whether administration of amifostine prior to irradiation could reduce radiation damage of the rat heart. Female Spraque-Dawley rats were randomized to receive single-dose irradiation (0-22.5 Gy) locally to the heart. Fifteen to twenty minutes before radiation exposure, the animals received either intraperitoneally administered amifostine (160 mg/kg) or buffered saline solution. At 6 months post-irradiation, cardiac function was assessed by the in vitro working rat heart preparation. The severity of interstitial and/or perivascular fibrosis in different anatomical regions of the rat heart was assessed using a semi-quantitative scoring system. Radiation exposure to doses > or = 20 Gy markedly reduced coronary flow, aortic flow and cardiac output. Administration of amifostine prior to radiotherapy afforded protection against these effects and normal cardiac output was maintained, even after 22.5 Gy. A small, non-significant, reduction in histological damage (i.e. perivascular fibrosis and interstitial fibrosis) was also apparent in animals treated with amifostine. There was a clear protective effect of amifostine on the severity and extent of macroscopic damage in lung tissue included in the cardiac irradiation field. The findings of this study suggest that a single dose of amifostine administered prior to irradiation is effective in reducing cardiac damage.

Proteinuria and vascular changes after renal irradiation: the role of reactive oxygen species (ROS) and vascular endothelial growth factor (Vegf).

Proteinuria occurs in all degrees of radiation nephropathy and can be present without other symptoms. In this study, radiation-induced proteinuria in C3H mice demonstrated a clear dose-response relationship and was apparent before the onset of significant structural vascular changes and decreases in renal function. This suggests that proteinuria is not a secondary event due to loss of the vascular structure. In an attempt to ameliorate radiation-induced proteinuria and progressive renal failure, two factors were studied. The influence of reactive oxygen species (ROS), which are generated by infiltrating neutrophils and mediate proteinuria in models of acute glomerular injury, was the first to be investigated. Short-term administration of the reactive oxygen scavengers superoxide dismutase (SOD) and catalase did not reverse an established radiation-induced proteinuria. Continuous administration of the antioxidant N-acetylcysteine (NAC) also failed to inhibit this proteinuria. However, since no direct assessment of the impact of these interventions on renal redox status was made, the putative role of ROS in radiation-induced proteinuria and nephropathy remains undefined. The second factor studied was vascular endothelial growth factor (Vegf), which is suggested to be involved in glomerular vessel permeability and the development of proteinuria in some models of renal disease. Northern blot analysis of mRNA from whole kidneys did not demonstrate any increased expression of Vegf after irradiation. There was also no change in the ratio of the different Vegf isoforms (PCR analysis), either in the whole kidney or in isolated glomeruli. No significant role for Vegf was identified for radiation-induced vascular changes or proteinuria, although post-transcriptional changes cannot be excluded.