Active clinical trials for "Neurodegenerative Diseases"

This Phase 1 study looks at how a new videogame-based program can help residents and care partners prepare for ADLs in a fun way with minimal risk, potentially reducing escalating problems associated with ADL completions.

Alzheimer's disease is a severe neurodegenerative disorder of the brain that is characterized by progressive loss of memory and cognitive decline. With the ageing population, AD is a major public health problem affecting nearly 35 million people worldwide with numbers projected to rise to 115.4 million by 2050. AD is the only cause of death among the top ten causes that has no prevention or cure . It is believed that novel treatment of AD needs to start early or even at the prodromal stage in order to be effective. Therefore, there is an urgent need to find accurate methods of early detection before patients with AD develop clinical dementia. This study aims to identify biomarkers for AD in local Chinese population. this study hypothesizes blood-based proteomics, retinal imaging, ASL-MRP and tau PET can improve the accuracy and staging of AD.

The STAREE-Mind imaging sub-study will examine the effect of statin treatment over a 4-year period, compared with placebo, on markers of brain health.

The underlying pathophysiology following traumatic brain injury (TBI) in how different neurodegenerative conditions are developed are still unknown. Different neuroinflammatory and neurodegenerative pathways have been suggested. The goal of this study is to follow-up patients that have been treated for TBI at the neurosurgical department about 10-15 years after their initial injury, in order to analyze fluid biomarkers of inflammation, injury and degeneration and associate these with structural imaging and long-term functional outcome. The investigators aim to invite about 100 patients back and perform advanced magnetic resonance imaging protocols, sample cerebrospinal fluid and blood for different bio- and inflammatory markers, study genetic modifications and associate it with outcomes being assessed through questionnaires. The investigators' hypothesis is that patients with ongoing inflammatory processes will present with more fluid biomarkers of neurodegeneration, worse clinical presentation and also more structural/atrophic signs on imaging. This will result in an increased understanding of the interplay between neuroinflammation and neurodegeneration in chronic TBI, as well as a panel of tentative biomarkers that could be used to assess level of disability following TBI and chronic traumatic encephalopathy (CTE).

Amyotrophic Lateral Sclerosis (ALS) is an aggressive, deadly disease. ALS leads to destruction of the neural pathways which control the conscious movements of the muscles. This destruction leads to muscular dystrophy with increasing difficulties in moving, breathing, swallowing, and speaking. In the last phase of an ALS patient's life it is necessary with respiratory therapy in order to breathe. In average an ALS patient lives 3 years from the time he or she gets the diagnose. The cause of the disease is still unknown and there is currently no treatment which can stop the progression of the disease. Former clinical studies have indicated that the innate immune system and in particular the complement system plays a significant role in the progression of ALS. The complement system, which is activated in cascades, is part of the innate system but participates in the innate as well as the acquired immune system. Former clinical trials have been characterized by limited knowledge about both the complement system as well as to how it is measured. Today it is possible to measure directly on the different components of the complement system and to understand its contribution to the overall immune response. It is also possible today to detect defects of the complement system. All these progressions are the foundation for this project which is carried out in close cooperation with one of the world's leading researchers in the complement system, professor Peter Garred from Rigshospitalet. The aim is to make a national research project about ALS in order to investigate the role of the innate immune system, and especially the complement system, in patients with ALS. In the long term the hope is, that this will lead the way to a targeted and effective medical treatment to the people affected by this grave disease.

There is a long history of research into body fluid biomarkers in neurodegenerative and neuroinflammatory diseases. However, only a few biomarkers in cerebrospinal fluid (CSF) are being used in clinical practice. One of the most critical factors in biomarker research is the inadequate linkage of biological samples with data from medical records, environmental exposure, lifestyle information and other medically relevant information. In this context the biobanks are an invaluable resource for medical research and, in particular, for the identification of biomarkers. This project aims to enstablish a biobank for Multiple Sclerosis that allow to collect periodically, at each follow up, clinical data, tissues such as blood and cerebrospinal fluid and DNA, RNA, proteins, from patients afferent at the Centre for the Study and Cure of Multiple Sclerosis in Neurological Institute "Neuromed", Pozzilli, Isernia. The samples stored in this biobank are examined by quantization of a potential innovative biomarker focused on the formation of circulating mitochondrial DNA. Fragments of mitochondrial DNA (mtDNA) are released outside the cell and they appear to persist in extracellular fluids as circulating, cell-free, mtDNA (ccf-mtDNA). This occurs during acute inflammation, which anticipates the neurodegenerative process. Thus, an increase in inflammatory cells in the affected regions is expected to add on mtDNA release into the CSF. Thus, ccf-mtDNA may represent a powerful biomarker for disease screening and prognosis at early stage, although its biological role may extend to generating the neurobiology of disease. Aims: Identify a technique that allows to isolate, the mitochondrial DNA circulating from different biological tissues (Droplet Digital PCR, Real Time PCR). Use different technologies to quantify the presence of circulating mitochondrial DNA Use circulating mitochondrial DNA as a biomarker of neurodegenerative and / or neuroinflammatory pathologies. It is essential to understand the tissue specific origin of circulating mtDNA for both diagnostic and therapeutic considerations. . We believe that our current knowledge on cell free circulating mtDNA is in a rather exploratory phase with a potential for the future to rewrite the pathology of the leading causes of morbidity and mortality such as inflammatory conditions, autoimmune disorders, cancer, heart disease, stroke and injury.

This study aims to develop and evaluate biomarkers using non-invasive optical coherence tomography (OCT) and OCT angiography (OCTA) as well as ultra-widefield (UWF) fundus photography to assess the structure and function of the retinal and choroidal microvasculature and structure in persons with mild cognitive impairment (MCI) and Alzheimer's Disease (AD), Parkinson's Disease (PD), or other neurodegenerative disease, diseases as outlined.

Human fibroblasts and possibly other human somatic cells may be reprogrammed into induced pluripotent stem (iPS) cells by the forced expression of transcription factors (1-5). The iPS cells seem to share many properties with human embryonic stem cells. Induced pluripotent stem cells potentially may be useful in the future as an unlimited source of cells for transplantation. The major goal of the project is to develop human iPS cells from cell cultures from skin biopsies or the patient's hair. The iPS cells will be developed primarily for modeling diseases and drug discovery as well as basic research, and for developing the technology that may eventually allow the use of iPS cells for future transplantation therapy. The iPS cells developed in the course of this application are not intended for use in transplantation therapy. Future development of iPS cells for clinical transplantation therapies will be subjected to the appropriate authorization by ethical and regulatory committees.

The purpose of the study is to systematically characterize the clinical course of the progressive neuropathy and optic atrophy observe in pediatric and adult patients with biallelic mutations in the ferredoxin reductase gene.

There is an urgent need for the development of digital progression biomakers, which are sensitive to detect small, but potentially clinically relevant changes in the disease course. Digital biomarkers are based on (i) continuously collected real-time data, during the patient's day to day activities; and (ii) task-based assessment. In this study the investigators are interested in developing algorithms for the detection of disease progression in PSP patients in key clinical parameters: bradykinesia, gait, rising from a chair and falls, based on (i) sensor data obtained by means of passive monitoring during daily living; and (ii) sensor data collected during the Virtual Motor Exam.