View clinical trials related to Cytomegalovirus Infections.
Filter by:Human cytomegalovirus (CMV) is the leading cause of neonatal viral infection and can have a significant impact on the neurosensory development of newborns and especially premature infants. CMV infection can result from materno-fetal transmission during pregnancy (congenital infection) or postnatal transmission. The prevalence of congenital CMV infection in the newborn is estimated to be between 0.1 and 0.5%. Among the newborns in utero infected by CMV, it is estimated that 10-15% will present symptoms at birth (hypoacousia / unilateral or bilateral deafness, microcephaly, chorioretinitis, psychomotor retardation, etc.) and 0.5% of them will die. 20% of infected infants, mainly symptomatic newborns, suffer permanent sequelae, mainly loss of hearing. Many asymptomatic children at birth will present hearing loss and other delayed neurological complications. A progressive neurosensory hearing loss may develop for 13-15% of asymptomatic newborns at birth. Deafness is bilateral in 50% of cases, severe in more than 50% of cases, and its occurrence is often delayed. The hearing loss has a significant impact on the future life of the child, mainly on language acquisition and school performance. A systematic CMV screening is not currently recommended at birth due to the frequency of asymptomatic forms, difficulty in fetal diagnosis and prognosis, lack of consensus for preventive and curative treatment of the infection. New treatments are being evaluated and encouraging results could revive the debate. PCR from urine is the gold standard for the diagnosis of CMV infection. Urine collection is not systematic in newborns and its realization can sometimes be difficult. On the other hand, in children at risk (hypotrophy, prematurity, infectious risks, fetal distress or respiratory distress at birth), gastric aspiration is systematically performed at birth to overcome obstruction of the upper aero-digestive tract, to prevent oesophageal atresia, to avoid inhalation by reflux and sometimes to make a bacteriological diagnosis. Our hypothesis is that this liquid could be used for the detection of CMV infection without adding any invasive action in newborns. Ultimately, gastric aspirate could allow for routine CMV screening in children at risk and thus allow for appropriate care by nursing staff.The occurrence of immediate or delayed sensory sequelae in these children would be then limited.
Donor and recipient CMV-serostatus is one of the risk factor for CMV infection in solid organ transplantation. Recipients with IgG positive anti-CMV are classified as low-risk patients since it is considered that patients also have specific cellular immunity against CMV. However, investigators group has published that around 25% of solid organ transplant candidates lack CMV-specific CD8+ T-cell response ("humoral/cellular mismatch") and they are at a higher risk of CMV replication after transplantation. The main goal of this study is to analyze the impact of the humoral/cellular mismatch in hematopoietic stem cell transplantation (HSCT) CMV-seropositive donors on the CMV reactivation after HSCT in CMVseropositive recipients. Investigators will study not only the incidence of CMV reactivation but also the severity (duration and peak viral load), CMV disease and survival. CMV-seropositive patients who receive a HSCT (bone marrow or peripheral blood) from related donors will be consecutively recruited from Reina Sofía Hospital (Córdoba) and Marqués de Valdecilla Hospital (Santander). Patients will be monitored during 12 months after HSCT. CMV-specific CD8+ T-cell response will be determined in their donors, using QuantiFERON-CMV assay, to know the frequency of humoral/cellular mismatch. Innate and adaptive immune reconstitution will be assessed by flow cytometry and experimental QuantiFERON Monitor assay. CMV-specific CD8+ T-cell reconstitution will be determined using QuantiFERON-CMV assay.
Cytomegalovirus (CMV) is the most common cause of congenital infection, with approximately 0.5% of pregnant women being infected during pregnancy. CMV transmission to the fetus occurs in about one third of women who are infected in first trimester. Babies infected before birth are at risk for serious neurological complications such as intellectual disability, seizures, deafness, and even death. Most couples facing a diagnosis of congenital cytomegalovirus infection in their unborn baby focus heavily on the predicted neurological outcome for their child. To date, methods to assess brain development in fetuses have been mainly limited to detecting structural brain abnormalities by ultrasound. However, these ultrasound signs may not become apparent until very late in pregnancy, and some neurological disability is not accompanied by any structural brain changes. More research on methods of predicting neurodevelopmental outcome independent of structural brain malformations before third trimester is urgently needed. The purpose of this study is to investigate a new method of studying the health of unborn babies using amniotic fluid. Amniocentesis is often performed after maternal CMV infection to diagnose fetal infection. Prior research by Dr Hui has demonstrated that cell free RNA in amniotic fluid can provide meaningful information from multiple organs including the fetal brain. The investigators propose to collect and analyse a small sample of amniotic fluid to detect which genes are turned "on" or "off" (gene expression) in a fetus that has a congenital CMV infection, compared to those without any infection. The genes that are differentially expressed in CMV infected fetuses will then be analysed to provide information on the broad physiological processes that are altered due to the infection ("functional analysis") and identify neurodevelopmental gene transcripts of interest for future studies ("biomarker discovery").
Coronary artery disease is a contraction of the coronary arteries that prevent adequate blood supply to the heart muscle is called CAD. Usually caused by atherosclerosis, it may be advanced to the point where the heart muscle is injured due to lack of blood supply. Such damage may result in infarction, arrhythmias, and heart failure(1,2). Telomeres are short in circulating leucocytes in patients with coronary artery disease but the precise mechanism is not well-known (3). Telomere and telomerase are affected by cytomegalovirus (CMV) infection due to its effect on increasing the number of highly differentiated T cells that are characterized by shorter telomere length (TL) and lowered telomerase activity (TA). Both genetic and environmental factors have been connected with individual distinction in TL.Cardiovascular risk factors such as smoking, diabetes mellitus, hypertension, obesity, and stress have been considered to upsurge inflammation, oxidative stress, therefore accelerating TL shortening (1,2) It has also been observed that telomere loss in type 2 diabetic patients contributes to oxidative stress and endoplasmic reticulum stress while telomere shortening has also been proposed that it can serve as an independent risk factor of T2DM and it can measure disease progression(4). Moreover, telomeric length in peripheral blood mononuclear cells (PBMCs) is associated with the duration of disease and good glycemic control seems to be protective for telomeric loss (5). Growth differentiation factor-15 (GDF-15) is a member of the transforming growth factor (TGF)-β superfamily. GDF-15, recently identified as one of the new cardioprotective cytokines. It is highly expressed in cardiomyocytes, adipocytes, macrophages, endothelial cells, and vascular smooth muscle cells in normal and pathological condition. GDF-15 increases during tissue injury and inflammatory states and is associated with cardiometabolic risk(6). Dipeptidyl peptidase inhibitors (DPP4 -I) are called gliptins which increase the incretin levels and therefore prolong the post-prandial insulin action(7). Diana et al reported that In type 2 diabetic patients, leukocyte telomere was significantly shorter than control groups and was significantly elongated after intervention by sitagliptin(8). The common feature of all risk factors of CAD and T2DM imbalance between pro- and anti-oxidative factors in the organism with an increased production of reactive oxygen species (ROS).Nuclear factor erythroid-derived factor 2-related factor 2(Nrf2) is a family of transcription factors which plays an important role in protection against CVD and DM by regulating antioxidant enzymes in cells after ROS exposure (9). In our study, we will propose a model, which would provide the basis to establish a marker for chronic reactivation of CMV and shed more light into the pathophysiology of CMV infection in patients with CAD in relation to GDF-15 and NrF2 and their implications on disease progression. Ultimately, this would then enable us to identify patients at risk and develop novel strategies for future treatment and prevention of heart diseases in our country. In light of our project research, the question arises whether telomere length could represent a marker of chronic CMV reactivation and uncertainty their length will be modified by the effect of DPP-4 or not?
Viral infections remain an important cause of morbidity and mortality after allogeneic stem cell transplantation (SCT), especially after myelo-ablative conditioning and if the donor is antigen-mismatched or haplo-identical.. In the described setting the patient's own immune system has been destroyed by the necessary highly immuno- and myelo-ablative conditioning and all memory against infections has been deleted. Therefore, there is a high risk for several viral infections and other infectious organisms.Both primary viral infections and reactivations can occur, and patients can become refractory to antiviral treatments, or in some cases an adequate antiviral treatment is unavailable or too toxic. In this study, the investigators will target CMV, as refractory CMV infection and disease is accompanied by an extremely high mortality rate and therefore the development of new treatment approaches is required. Despite the available antiviral drugs, a considerable number of patients are facing an insufficient control of CMV reactivation after SCT. Because reconstitution of CMV-specific T cells confer protection against the development of CMV disease after SCT, attempts have been made to restore antiviral immunity by direct infusion of CMV-specific T cells. Most clinical cellular immunotherapy protocols for CMV treatment have used CMV-specific cytotoxic CD8+ T-cell lines generated by repetitive in vitro stimulation with CMV antigens with success. Despite the proven efficacy, use of cellular therapy in the clinic has been limited, because the approach is time and labor consuming and requires specialized facility allowing handling of the therapeutic cells according to good manufacturing practice. In addition, no sustained response was seen after adoptive transfer that involved only cytotoxic CD8+ T cells. This phenomenon is supported by the fact that recall responses to latent infections depend on the presence of CD4+ T cells to help cytotoxic CD8+ T cells. An alternative approach for the transfer of T-cell immunity is the isolation of Ag-specific T cells ex vivo from the blood of CMV seropositive donors, based on interferon γ (IFN-γ) secretion of T cells after in vitro stimulation with viral Ag, resulting in a combination of CD4+ T helper and cytotoxic CD8+ CMV specific T cells. Using this strategy, a short-term ex vivo protocol was developed for the isolation of pp65 (CMV immunodominant protein)-specific T cells. Since then, several centers have used this protocol in the clinic, infusing low numbers of pp65-specific T cells, that were able to restore protective T-cell immunity against CMV in a post SCT setting in patients with refractory CMV disease or viremia. For this protocol the investigators have set up and validated this method of CMV-specific T-cell generation in the Ghent University Hospital and the investigators will make it available for other Belgian transplant centers.
Human cytomegalovirus (CMV) infection is a major cause of morbidity and mortality for recipients of allogeneic hematopoietic stem cell transplantation(HSCT). we propose to study the immunologic and virologic effects of donor derived CMV specific cytotoxic T lymphocyte (CMV-CTL) given to transplant recipients CMV antigen peptides will be used to induce the CMV antigen specific T lymphocytes derived from donor peripheral blood mononuclear cells for a period of 18~21 days.The patients will receive CMV-CTL cells when they are sero-positive for CMV-DNA 30 days after transplant. The CMV-DNA level will be monitored weekly after transfusion.
The study will test the hypothesis that CMV TCR-transduced T cells, at a specific T-cell dose/kg, can generate a functional CMV immune response post-transplant, where CMV-specific donor T cells cannot be isolated by conventional means. This will be tested in the context of adult HLA-matched sibling allogeneic HSCT. In the proposed trial, an HLA-A*0201-restricted CMV pp65-specific T cell receptor (TCR) will be introduced into donor T cells via ex vivo GMP retroviral transduction. Donor T cells will be isolated from peripheral blood following a simple venesection procedure. The CMV TCR-transduced T cells will be tested for TCR expression, CMV-specific cytokine secretion and microbiological contamination before being frozen and stored at -80C. CMV seropositive transplant recipients will be tested weekly for CMV reactivation by quantitative PCR on peripheral blood. On first detection of CMV DNA > 200 copies/ml, 104 (cohort 1) or 105 (cohort 2) bulk CMV TCR-transduced T cells/kg recipient weight will be infused into the patient. Blood will be taken regularly to determine persistence and expansion of the CMV TCR-transduced T cells. Weekly CMV PCR will be continued. Patients will be examined at appropriate intervals (daily if inpatients, twice weekly in BMT clinic if outpatients) for the development of graft versus host disease (GVHD) or other potential side effects.
Cytomegalovirus (CMV) infections remain an important cause of morbidity and mortality in allogeneic hematopoietic cell transplant (HSCT) recipients, especially in patients received haploidentical transplantation. During the past decades, prophylactic or preemptive treatment with antiviral drugs has significantly reduce the incidence of early-onset CMV infection. Unfortunately, prolonged antiviral treatment is associated with substantial toxicity and may delay recovery of virus specific immune responses, resulting in an increasing of late-onset CMV disease. To date, adoptive immunotherapies have been developed as treatment alternatives to antiviral agents for CMV infection after HSCT. Studies have demonstrated that prophylactic or preemptive therapy with donor CMV-specific T cells can restore antiviral immunity and clear CMV viremia after transplantation. In this prospective clinical phase I/II trial, we propose to reconstitute antiviral immunity against CMV by preemptive transfer of CMV-specific T cells at an early time point after allogeneic stem cell transplantation. We also propose to demonstrate whether protect against CMV is associated with recovery of CMV-specific T cells.
The purpose of this study is to determine if a specific type of cell-based immunotherapy, using T-cells from a donor that are specific against cytomegalovirus (CMV) is feasible to treat infections by CMV. Adoptive T-cell therapy is an investigational (experimental) therapy that works by using the blood of a donor and selecting the T-cells that can respond against a specific infectious entity. These selected T-cells are then infused to the patient, to try to give the immune system the ability to fight the infection. Adoptive T-cell therapy is experimental because it is not approved by the Food and Drug Administration (FDA).
This study evaluates the safety and availability of oral valganciclovir(VGC) at the does of 450mg daily begin within 10 days after renal transplantation, and till to Day 100 posttransplant. Compare to the guidelines for effective antiviral prophylaxis, the investigators divide these patients into three groups in random. One third will oral VGC 450mg daily as mentioned above; one third will oral VGC 900mg daily; and the other one third will intravenous GCV 5mg/kg daily within the first 14 days posttransplant, and continue to oral GCV 1g 3 times daily till to Day 100 posttransplant; with does adjusted per renal function for all agents.