View clinical trials related to Mitochondrial DNA.
Filter by:This study is to characterize mitochondrial DNA (mtDNA) populations in adults with eye injuries and eye diseases. The eye exam is often hindered by the clouding of tissues involved in injury or disease. This protocol examines the use of mtDNA populations as indicators of developing inflammation and resolution of injury. This may be used to provide proactive treatment or define appropriate treatment needs beyond the indications of an ophthalmological exam.
Background: Giving birth is a critical moment for the mother and the fetus, potentially accompanied by stress, tissue damage, cell injury, placental hypoxia and sometimes multisystem vascular syndrome known as preeclampsia. Epidural analgesia with a local anesthetic is a common anesthetic approach during labor. Local anesthetics inhibit the oxidative phosphorylation and impair the synthesis of ATP, resulting in mitochondrial dysfunction and increased reactive oxygen species. Especially when the high demand of ATP during pregnancy cannot be reached, apoptosis will occur in an anaerobic environment. During apoptosis the cell membrane integrity is disturbed, releasing the cytoplasm into the blood circulation. Circulating cell-free mitochondrial DNA acts as a damage associated molecular pattern (DAMP) by activating the innate immune system leading to inflammation. These DAMPs are evolutionary conserved and have structural similarity to their bacterial ancestor. Therefore, cell-free mitochondria can act as a potent agent triggering the immune system in an autoimmune manner as well as a biomarker for cell damage and hypoxia. Objective: The aim of this study is to investigate to role of epidural analgesia during birth, quantifying the copy number of circulating cell-free mitochondrial DNA in maternal serum and the placenta compared to controls. The investigators hypothesize that epidural analgesia with a local anesthetic has an effect on cell-free mitochondrial DNA levels, promoting the pathogenesis of ERMF and early inflammation. In addition, circulating mitochondrial DNA could be a potent biomarker for cell damage, early placenta hypoxia/insufficiency or preeclampsia. Methods: For this study the investigators planned 3 groups each consisting of 15 patients. The intervention group (group 1) will be women with vaginal delivery having epidural analgesia and developing fever before delivery. The control group (group 2) will be women with vaginal delivery having an epidural analgesia without developing fever before delivery. Women with vaginal delivery without an epidural analgesia will serve as additional control (group 3). Blood will be taken at arrival at the delivery ward and immediately after delivery from a peripheral venous line. In addition, venous blood from the umbilical vein will be drawn postpartum. Axillary temperature will be measured routinely using a thermometer in a routine clinical fashion. Circulating cell-free mitochondrial DNA and other immunological markers will be quantified in maternal and umbilical cord (fetal) serum by real time quantitative PCR and statistical analysis will be performed by non-parametric tests.
Sarcopenia is the decline of muscle mass and strength with age. Evidence suggests that oxidative stress and molecular inflammation play important roles in age-related muscle atrophy. The two factors may interfere with the balance between protein synthesis and breakdown, cause mitochondrial dysfunction, and induce apoptosis. Sarcopenia, inflammation and oxidative stress is highly prevalent in hemodialysis patients and may contribute to mortality. The copy number of mitochondrial DNA (mtDNA) is affected by oxidative stress in blood circulation. This study aimed to test whether mtDNA copy number correlates with oxidative stress and some uremic toxins in nondiabetic hemodialysis(HD) patients. 200 nondiabetic hemodialysis patients and 50 healthy subjects will be enrolled. This study will be performed to investigate quantitative changes in mtDNA occur in HD patients with and without sarcopenia. Copy number of mtDNA in leukocyte DNA is determined by real-time polymerase chain reaction in HD patients and 50 age- and sex-matched control subjects. In addition, correlation of the alterations of albumin redox status, 8-isoprostane, plasma IL-6 ,LBP and TNF-a and as well as various uremic toxins will be performed.
Pregnancy rates for women over 35 years old are significantly lower when compared to younger women. One of the causes for this decrease is believed to be chromosomal aneuploidy. Chromosomal aneuploidy is a natural phenomena and occurs in women of every age and has been implicated in spontaneous miscarriages, and preimplantation embryo wastage (Hassold and Hunt, 2001). As maternal age increases, so too does the incidence of chromosomal aneuploidy. Embryo quality from older patients undergoing IVF tends to be reduced and associated with higher rates of chromosomal abnormalities when compared to good quality embryos (Munne et al., 1995). Chromosomal aneuploidy derives from the improper segregation of chromosomes during preimplantation development. The process of segregation, or mitosis, includes synthesis of the complete genome, equal division of chromosomes to opposite poles by the spindle apparatus, and separation of the two cells by cytokinesis, yielding two chromosomally identical cells. The entire process of cellular and genetic replication requires energy in the form of adenosine tri phosphate (ATP). ATP is mainly produced in mitochondria in the process known as the electron transport chain (ETC). There are many important molecules required for ATP production, CoQ10 can act as the appropriate carrier of electrons through the ETC. When a deficiency in CoQ10 is present, ATP production is decreased resulting in aneuploidy (Bentov et al., 2013). Similarly, research has shown that chromosome alignment and spindle formation are affected by mtDNA copy number (Ge et al., 2012). It has also been shown that the transfer of ooplasm from young, healthy oocyte donors into oocytes of women with repeated embryonic failure has result in children with subsequent mitochondrial heteroplasmy (Cohen et al., 1998). CoQ10 concentrations have been shown to decrease as age increases (Bentov et al., 2011). Consequently, the decrease in CoQ10 concentrations seen in older women may cause an increase in chromosomal aneuploidy in subsequent embryos (Bentov et al., 2013). In this pilot study, we test the hypothesis that the supplementation of CoQ10 prior to an IVF cycle can increase mitochondrial DNA activity and possibly decrease chromosomal aneuploidy in AMA patients.