View clinical trials related to Lymphopenia.
Filter by:Participants were classified as normal or malnourished according to anthropometric measures. Serum albumin and zinc were recovered on the 1st and 7th days of hospitalization. Lymphocyte count was also recorded on the 1st and 7th days.
Definition: Idiopathic CD4+ T lymphocytopenia (ICL) is an immune deficiency first described in 1992 and characterized by the US Centers for Disease Control (CDC) as absolute CD4+ T-lymphocyte count < 300/mm3 or < 20% of total T cells on more than one cell count; no evidence of infection with HIV-1/2 or human T-cell lymphotropic 1/2 (HTLV-1/2); and lack of a defined immune-deficiency disease or therapy for lymphocytopenia. Epidemiologic, clinical and immunological characteristics of the syndrome were described in 1993 and ICL is now considered a heterogeneous syndrome not caused by an infectious agent. Patients with ICL may show opportunistic infections such as disseminated Cryptococcus neoformans infection, Pneumocystis jiroveci pneumonia and John Cunningham (JC) virus infection as a result of profound cell-mediated immune-response deficiency. Few studies have focused on the pathophysiology of ICL. CD4+ T-lymphocyte phenotyping revealed increased CD95 expression that could be responsible for excess apoptosis leading to lymphocytopenia. Moreover, the membrane expression of C-X-C chemokine receptor type 4 (CXCR4) was found impaired in T lymphocytes with ICL, and CXCR4 trafficking was improved with interleukin 2 (IL-2) treatment in some patients. Recently, mutations in nunc119, MAGT1 and Rag were found associated with CD4+ T lymphocytopenia. In a prospective study of 39 patients, CD8+ T lymphocytopenia (<180/mm3) and degree of CD4+ T-cell activation measured by human leukocyte antigen DR (HLA-DR) expression was found associated with poor prognosis. ICL is a heterogeneous disorder often associated with deficiencies in CD8+, CD19+, and/or NK cells. Long-term prognosis may be related to initial CD4+ and NK cell deficiency. Larger studies are needed to better identify the patients who might benefit from IL-2 therapy. This is why the investigators conduct the Lympho-4 study, in which the investigators plan to include 200 patients with a suspected/proven diagnosis of ICL.
The purpose of the study is to evaluate the impact of an immunotherapy by IL-7 on CD4 lymphopenia, risks of severe haematological toxicity and tumor progression in metastatic breast cancer patients. The primary objective is to determine the optimal schedule to deliver CYT107 during chemotherapy based on restoration of CD4 count. This study is a phase II, randomised, double-blind, placebo-controlled, single-centre. 24 patients will be included in the study.
The purpose of this study is to identify risk factors for low lymphocyte count among patients with type 2 diabetes who are treated with oral antidiabetic drugs.
The goal of the proposed research is to establish the validity of a newborn screening method for severe combined immunodeficiency (SCID). The assay to be used is developed on the basis of PCR quantification of T-cell receptor excision circles (TRECs) that is absent in SCID patients, thus correlating with the disease
This research study will investigate the safety and effectiveness of two different dose levels of a new, unapproved drug to be given along with the chemotherapy regimens gemcitabine and carboplatin or gemcitabine and cisplatin prescribed to women for the treatment of ovarian cancer. This experimental drug is called TXA127 and is being tested for effectiveness to see if it will help reduce some of the side effects of the chemotherapy, primarily low blood platelet levels that lead to excess bleeding. This study also intends to test the safety of TXA127 when given as an injection under the skin on a daily basis concurrently with up to 6 cycles of the prescribed chemotherapy.
The purpose of this research study is to learn if your own immune cells can be activated and multiplied in order to help your body fight off the tumor cells in your brain. The safety of this procedure will also be studied. This procedure, called CMV-autologous lymphocyte transfer or CMV-ALT is investigational which means that it is not approved by the US Food and Drug Administration (FDA) and is still being tested in research studies. Autologous lymphocyte transfer or ALT means that you will receive your own immune cells back (and not from another donor) as a treatment after they have been activated and grown to large numbers in a clinical lab. It is believed that the body's immune (protection) system can attack tumor cells and kill them. Immune cells called T-lymphocytes (T-cells) can recognize special proteins on the surface of tumors as a signal to attack and fight the cancer. In most patients with advanced cancer, the immune system does not adequately destroy the tumor because the white blood cells or T-cells are not stimulated enough. Before your T-cells can become active against tumor cells, they require strong stimulation. There are special "stimulator" cells in the body called Dendritic Cells (DCs) that can take up proteins released from cancer cells and present pieces of these proteins to T lymphocytes to create this strong stimulation. Dendritic cells taken from your blood will be "pulsed" or loaded with genetic material called RNA (ribonucleic acid), which stimulates the DC to change the RNA into a protein called pp65. This protein is produced by a common virus called Cytomegalovirus (CMV) that 70-80% of us have been exposed to in our lifetime. Recently, we have found that this virus is present in many malignant brain tumors. Brain tumors are very aggressive and, for reasons we do not yet understand, are difficult for the body to attack. The CMV virus is a target in the tumor that, if attacked by your immune systems cells, may prevent your tumor from growing. We have found that we can grow immune cells to very large numbers from the blood of people who have evidence of prior exposure to this virus. You will therefore be tested to determine if you have pre-existing antibodies to this virus in order to participate in this study. We will use your DCs to activate and grow immune cells from your blood to large numbers in a clinical laboratory. These CMV-specific immune cells, called CMV-ALT, will be returned to your body when they have become activated. It is hoped that these cells will seek out and kill tumor cells that express the CMV viral protein and not attack normal cells. The transfer of immune cells that stimulates your immune system is called adoptive immunotherapy. We will evaluate two doses of immune cells in this study (Dose 1 and Dose 2). Depending on when you are enrolled in this study you will receive either Dose 1 or 2. The first six patients enrolled on this study will receive Dose 1 (the lower dose) and the next six patients will receive Dose 2 (the higher dose). We do not know at this time if either dose is more effective or safer to administer which is why we are testing both doses. Dose 2 will be a larger number of immune cells if the treatment is found to be safe in the first six patients treated during this study. In this study we will also see, in some randomly selected patients, if giving an injection of the DC pulsed with pp65 RNA into the skin improves the function of the CMV-ALT treatment or not. You will receive three injections under the skin of either some of the same DC that were used to stimulate your immune cells in the clinical laboratory or three injections of saline (salt solution) under the skin starting with the infusion of the CMV-ALT. It is unknown if a DC injection will be beneficial to the immune cells or not so the responses will be compared in patients who receive DC versus saline injection with their CMV-ALT. After these three injections, blood will be collected to compare the responses between patients that received saline to those that received DC injections.
RATIONALE: Monoclonal antibodies, such as basiliximab, can block tumor growth in different ways. Some block the ability of tumor cells to grow and spread. Others find tumor cells and help kill them or carry tumor-killing substances to them. Drugs used in chemotherapy, such as temozolomide, work in different ways to stop the growth of tumor cells, either by killing the cells or by stopping them from dividing. Radiation therapy uses high-energy x-rays to kill tumor cells. Vaccines may help the body build an effective immune response to kill tumor cells. Giving these treatments together may kill more tumor cells. Granulocyte Macrophage-Colony Stimulating Factor (GM-CSF) is a powerful adjuvant capable of stimulating macrophage function, inducing proliferation and maturation of DCs, and is able to enhance T-lymphocyte stimulatory function. Intradermal administration of GM-CSF enhances the immunization efficacy at the site of administration PURPOSE: This clinical trial is studying how well basiliximab works in treating patients with newly diagnosed glioblastoma multiforme and temozolomide-caused lymphopenia who are undergoing targeted immunotherapy.
This study will evaluate the safety of a new experimental drug, IL-7, in people with HIV infection. Animal studies have shown that IL-7 can improve the function and number of infection-fighting cells called T lymphocytes, or T cells. If this study shows that IL-7 is safe, additional studies will be done to see if it can improve the function or numbers of T-cells in HIV-infected persons. HIV-infected persons who have been receiving HAART therapy for at least 12 months before enrolling in the study and have been stable on this treatment for at least 3 months before enrollment may be eligible for this study. Participants have about 10 clinic visits over 3 months. They receive three injections of IL-7, one injection a week for 3 consecutive weeks. The injections are given as a shot under the skin in the arm or leg. On the day of each injection, the participant stays in the clinic for up to 8 hours or longer for observation and collection of blood samples. Three additional visits (one every 3 months) may be scheduled. During the study visits the following may be done: - Medical history, physical examination, blood tests every visit. - Electrocardiogram (EKG) at study days 0 (day of first dose), 1, 7 (day of second dose), 14 (day of third dose) and 21. - Chest x-ray study on day 21. - Blood sample collections at frequent intervals during the first 96 hours after the first dose administration. A catheter (thin plastic tube) may be put into a vein in the arm and left in place to allow several blood samples to be drawn without repeated needle sticks. - Urine tests several times during the study.
This study will evaluate HIV-negative patients with unusually low levels of CD4+ T lymphocytes (a type of white blood cell) to learn more about the clinical symptoms, cause, immunology, and biology of this problem. CD4+ T lymphocytes play an important role in immune function, and low counts may leave people susceptible to unusual infections. CD4+ T cell deficiencies are most often associated with HIV infection. Patients 8 years of age and older with CD4+ T cell counts below 300 cells/mm3 who test negative for HIV infection by standard blood tests may be eligible for this study. Patients' family members and partners may also be enrolled to investigate the possible role of a genetic factor or exposure to some agent in this problem. Patients will be evaluated at the NIH Clinical Center at least once, and generally two or more times. The evaluations, which may be done on an inpatient or outpatient basis, will include some or all of the following tests and procedures: - Complete physical examination. - Medical history, including questions about sexual contacts, intravenous drug use, travel, blood transfusions, previous illnesses, including sexually transmitted diseases, and health of family members. - Urine test. - Blood tests for routine and research purposes, including tests for HIV, hepatitis, syphilis and other infections, evaluation of immune function, and culture for viruses in the HIV family. No more than 1 pint of blood will be drawn every 6 weeks. - Pregnancy test for women of childbearing potential. - Skin tests for tuberculosis and immune function. These tests involve injecting a small amount of the substance to be tested just under the skin and looking for a raised area 1 to 2 days later. - Apheresis. Whole blood is collected through an arm vein (similar to donating blood), and circulated through a cell separator machine, where it is spun to separate the components. The red cells are then returned to the patient either through the same needle or through a needle in the other arm, and the plasma and white cells are extracted for study. The procedure, which takes 1 to 2 hours, may be repeated up to 3 times. Family members will have 60 cc (4 tablespoons) of blood drawn to determine CD4+ T cell counts.