View clinical trials related to Neurotoxicity Syndromes.
Filter by:The aim of the proposed project is to study the long-term impact of adjuvant systemic multi- agent chemotherapy (cisplatin, anthracyclines, vincristine, methotrexate, alkylating agents) in survivors (treated between 1992 and 2014 in UZ Leuven) of paediatric bone or soft tissue sarcomas on neurocognitive functioning.
The primary objective of this study is to assess the efficacy of monosialotetrahexosylganglioside (GM1) for preventing oxaliplatin induced neurotoxicity in colorectal cancer patients who received oxaliplatin-based adjuvant chemotherapy.
For gastric patients of Karnofsky scores between 60-80 scores, mFolfox6 is an option for chemotherapy. Neutropenia and oxaliplatin-induced neurotoxicity are the most common adverse effects which even result in discontinue of chemotherapy, especially for patients suffered from heavily acute neurotoxicity. Monosialotetrahexosylganglioside is a component of membrane of nerve cells. Previous phase II clinical trial showed, it can reduce oxaliplatin-induced neurotoxicity(OIN). But it did not certificated by phase III trial. A phase III trial is needed to investigate the effect and safety of monosialotetrahexosylganglioside Sodium Injection for prevention OIN at gastric cancer.
The morbidity of colorectal cancer(CRC) is 10%~15% in China.mFolfox6 has become one of the standard regimes for metastatic colorectal cancer (mCRC). Neutropenia and oxaliplatin-induced neurotoxicity are the most common adverse effects which even result in discontinue of chemotherapy, especially for patients suffered from heavily acute neurotoxicity. Monosialotetrahexosylganglioside is a component of membrane of nerve cells. Previous phase II clinical trial showed, it can reduce oxaliplatin-induced neurotoxicity(OIN). But it did not certificated by phase III trial. Investigators designed the phase III trial to investigate the effect and safety of monosialotetrahexosylganglioside Sodium Injection for prevention OIN at colorectal cancer.
This research trial studies heavy metal exposure in predicting peripheral neuropathy in patients with stage I-III breast cancer undergoing chemotherapy. Studying samples of blood and urine in the laboratory for heavy metal exposure from patients receiving chemotherapy may help doctors find out whether side effects from chemotherapy are related to heavy metal exposure.
In this study investigators will use a multi-modal imaging approach of MRS and fMRI to comprehensively assess the biological changes in the brain associated with EFV-based regimen (EFV/FTC/TDF), specifically alterations in the brain circuitry, function and local neurochemistry, and their correlation with neuropsychological function. In a cohort of HIV-infected patients who are clinically stable on the commonly use regimen of EFV/emtricitabine (FTC)/truvada (TDF) or Atripla, investigators propose to replace the EFV component with an integrase inhibitor, Raltegravir (RAL), given as the RAL and FTC/TDF to evaluate the EFV-related neural alterations. This is a multidisciplinary study which will be lead by Dr. Nina Lin, in collaboration with the research teams of Dr. Alexander Lin, Director of the Center for Clinical Spectroscopy, and Dr. Emily Stern, Director of the Functional Neuroimaging Laboratory, both members of the Brigham and Women's Department of Radiology at Harvard Medical School, as well as Dr. Jane Epstein, a researcher in Dr. Stern's research group. Dr. Epstein is a staff psychiatrist at Brigham and Women's hospital with extensive experience and expertise in research on abnormalities of affective and motivational processing in the context of neuropsychiatric disorders. Investigators will utilize the established clinical research platform in the Infectious Disease outpatient clinical practice at the Brigham and Women's Hospital, where there is currently have many ongoing HIV-related studies and a large panel of HIV-infected patients motivated to be involved in clinically relevant research. Investigators propose to use advanced neuroimaging to measure biologically changes in the brain associated with long-term EFV use with the following specific aims: 1. Determine changes in neurometabolites measured by MRS in the brain associated with long-term EFV use 2. Assess for alterations in neural activity correlated with affective symptoms associated with EFV vs RAL use using fMRI, and their associations with changes in neurometabolites assessed by MRS, and with changes in cognition assessed by Trail Making and Digit Substitution Tests. 3. Determine changes in emotion, cognition and sleep quality after switching from EFV to RAL, and how they correlate with subject treatment preference. This clinical study will extend our current understanding of EFV neurotoxicity by further defining the nature of these biological changes. Further elucidation of the neurobiological underpinnings of EFV-induced CNS toxicity will have clinical relevance in improving the quality of life and drug adherence of HIV-infected patients on ART, especially among older patients or those with baseline neuropsychiatric disorders, whom at baseline are more vulnerable to neurocognitive decline from long-term HIV infection.
Multi-Drug resistant pathogens (MDR) are reported worldwide with increasing incidence, especially in intensive care settings. One of the drugs which are effective against MDRs, is colistin (polymyxin E). This agent has been reintroduced in response to the increase of MDR pathogens and might be used more often in the future. Data on safety regarding the most important side effects are not sufficiently available. l This study evaluates the toxicity in patients who receive aerosolized colistin.
Evaluate the efficacy and safety of Monosialoganglioside(GM1) to prevent the neurotoxicity induced by cisplatin
Nanomedicines are currently being developed in the treatment of cancer due to their pharmacological advantages over traditional formulations; they provide a shorter infusion time and lower risks of hypersensitivity reactions associated with commonly used solvents. Nab-paclitaxel is a nanoparticle albumin-bound particle form of paclitaxel that is thought to exploit natural albumin pathways to enhance the selective uptake and accumulation of paclitaxel at the site of the tumour, thus reducing its diffusion to normal tissues. Nab-paclitaxel has been approved for the treatment of metastatic breast cancer patients who have failed first-line treatment for metastatic disease and for whom standard, anthracycline-containing therapy is not indicated. SPARC is a cysteine rich acid protein that is overexpressed in a broad proportion of solid tumours. Expression of this protein could sensitize tumour cells to antitumor activity of Nab-paclitaxel, due to its union through albumin-binding to this protein. First-line clinical trials have been developed with different Nab-paclitaxel regimens and also in combination with different chemotherapies and trastuzumab, showing a high level of efficacy. Toxicity profile of Nab-paclitaxel is well characterized with significantly less haematological toxicities compared with conventional paclitaxel. Nab-paclitaxel derived grade III neuropathy is short-lasting and more reversible than conventional paclitaxel-derived neuropathy, probably due to absence of Cremophor solvent, or due to paclitaxel itself. However there is still a lack of clinical and physiological characterisation of Nab-paclitaxel induced neuropathy. The current used tools for early detection and continuous evaluation of neurotoxicity are not optimal. Most used toxicity scales are limited, as they do not provide a detailed information of the severity of the neuropathy, its impact on quality of life, or physiopathology mechanisms. In addition, an inter-individual variability exists in terms of neurotoxicity predisposition when taxanes are used; it could be related to polymorphic differences in genes implicated in transport and metabolism of these drugs.
Many patients with cancer that are treated with a drug called oxaliplatin. This drug is used with other drugs to treat cancer. The drug can cause problems with the nerves in the hands and feet called peripheral neuropathy (a side effect of the drug). Peripheral neuropathy may make the hands and feet feel like they are tingling, have a burning feeling, and can cause pain. Almost all patients who receive oxaliplatin as part of their cancer treatment have peripheral neuropathy. Patients who do have this side effect usually have to take a lower dose of or stop taking the oxaliplatin even if the drug is helping their cancer. So far there is not a lot of information about how to make this side effect better or help it go away completely. There is some information that low levels of Vitamin D in the blood might be linked to problems or diseases of the nervous system like multiple sclerosis or Parkinson's Disease. It is even thought that Vitamin D may help protect the cells in the nervous system. Because of this information, researchers want to see if giving patients Vitamin D while they are receiving the drug oxaliplatin to see if it helps prevent the side effect peripheral neuropathy. Patients taking oxaliplatin who want to be in this study will take one Vitamin D capsule each day while they take oxaliplatin. Being in this study will not affect how the patient's cancer is treated. There are blood tests in the study to check Vitamin D levels and for a protein called nerve growth factor (NGF). The study team will carefully monitor the patients for any signs of oxaliplatin-related neurologic toxicity during the study.