Active clinical trials for "Radiation Injuries"

The "Hyperbaric OxygeN therapy on brEast cancer patients with late radiation toxicity" (HONEY) trial aims to evaluate the effectiveness of HBOT on late radiation toxicity in breast cancer patients using the trial within cohorts (TwiCs) design.

The objective of the study is to evaluate the safety of intramuscular (IM) administration of PLX-R18 in subjects exposed to ionizing radiation and who are at risk of developing HS-ARS. Indication:Post-Exposure Prevention (PEP) or treatment of Hematopoietic Syndrome of Acute Radiation Syndrome (HS-ARS) in subjects suspected to have been exposed to ionizing radiation.

Background: Radiotherapy is a common treatment for many malignancies. Radiation-related complications developing months or years after radiation treatment are known as late radiation tissue injury (LRTI) and are estimated to effect 5%-15% of all long-term survivors who have received radiation. Hyperbaric oxygen therapy (HBOT) is a well established treatment of LRTI. Most of the studies evaluating effect of HBOT on LRTI are focused on survival, resolution of tissue damage and improvement in LENT-SOMA scale. Very few studies have addressed effect of HBOT on pain in LTRI. Krahn and colleagues were the first to report the analgesic effect of HBOT in 3 cases of refractory pain in oncological patients with radiation soft tissue injury. Other studies showed significant improvement in pain intensity in patients with breast cancer and pelvic malignancies treated with HBOT for LTRI. In patients that had developed radiation- induced brachial plexopathy, HBOT elicited an increase in warm pain thresholds and a reduction in lymphoedema. A prospective case study of 16 patients with gynecological cancer found no changes with respect to pain and depression outcomes. A trial in patients with radiation induced proctopathy showed that 75% of patients with rectal pain had some improvement, although none experienced a complete resolution of pain symptoms. There are several mechanisms by which HBOT may elicit analgesic effects. There is a growing body of evidence that HBOT's analgesic effect related to nitric oxide metabolism and endogenous opioid secretion. Furthermore, the inhibition of tumor necrosis factor alph (TNF-α), the production of substance P, and the modulation of serotonergic pathways have all demonstrated a modification in the pain response following HBOT. In animal studies HBOT decreased allodynia and hyperalgesia in different models of neuropathic and inflammatory pain. The long lasting antinociceptive effect of HBOT was found to be dose-dependent in non-injured tissues. In human studies, HBOT decreased pain and edema and improved function in patients suffering from the complex regional pain syndrome, and improved pain scores and range of motion in patients with idiopathic femoral head necrosis. Women suffering from interstitial cystitis demonstrated a reduction in pelvic pain following weeks and months of HBOT treatment. In patients suffering from idiopathic trigeminal neuralgia HBOT produced a rapid reduction in symptoms and these effects were lasting for 6 months following treatment. HBOT was also found to be an effective treatment for cluster headaches and migraines and alleviated muscle and bone pains in patients with myofascial syndrome, fibromyalgia, and biphosphonate-related osteonecrosis of the jaw. Based on the evidence presented above and HBOT's known analgesic effect in many conditions, the investigators designed this study with the objective to evaluate if HBOT reduces pain, improves depression and impacts on patients quality of life in patients suffering from late radiation tissue injury. Study Design: Prospective observational study (n=300). Patients that have had radiation therapy for malignancy, developed late radiation injury and suffer from chronic pain.

The purpose of this study is to determine whether magnetic resonance imaging (MRI) using inhaled hyper polarized xenon-129 (129Xe) gas, and conventional contrast can help visualize impaired lung function and detect changes over time in patients receiving treatment as well as those who don't. 129Xe is a special type of xenon gas and when inhaled during MRI may be able to show areas of abnormal thickening of parts of the lungs. These images combined with images taken with injected contrast agents or other special types of MRI such as conventional proton (1H) MRI may provide a better way to look at lung structure and function. The ultimate goal is to predict the degree of radiation-induced lung injury that will develop in a given patient for a given treatment plan. The investigators anticipate that these images will provide more specific information about lung disease than standard lung function tests. The use of 129Xe MRI is investigational. Investigational means that these tests have not yet been approved by the US Food and Drug Administration and are only available in research studies like this one. In addition, standard MRI with contrast is not typically done as standard of care for monitoring changes due to thoracic radiation therapy, therefore, its use in this study is also considered investigational. Healthy volunteers are being asked to participate in this study because to develop a database of functional images that are representative of healthy lungs.

Retrospective multicenter study aimed to evaluate radiation exposure associated with different interventional procedures involving interventional cardiologists, interventional radiologists and electrophysiologists.

Using a multi-echo gradient echo sequence to calculate R2* and quantitative susceptibility maps and well as susceptibility-weighted imaging post processing the investigators hypothesize that the investigators would be able to distinguish between pseudoprogression and true progression with the use of an easily implementable sequence on clinical MRI scanners.

The investigators plan to investigate the consequences of late effects (radiation-induced survivorship syndromes) after radiotherapy in Gynecological and Prostate cancer survivors on return to work (Yes/No) and if RTW happened then time to RTW. In addition, whether general health, type of work (occupation), work environment factors, individual factors (lifestyle, socioeconomic status etc.), contribute to the adverse late effects of radiotherapy and these Gynecological cancer survivors have a higher risk for disability pension/long term sickness absence (NOT Return to work).

This is a Phase 1, non-randomized, sequential-cohort, dose escalation, open-label study designed to evaluate the safety and tolerability of RadProtect® in healthy volunteers. This study is to be conducted at two clinical centers and in conformity with Good Clinical Practice (GCP).

The clinically widely used X-ray computed tomography examination has a low-grade radiation effect and recently has attracted much attention concerning the possible adverse effects of radiation on human body [ref. 1-5]. The radiation is harmful to human tissues and cells mainly because it can interact with water (which makes up to 80% of cells) to generate reactive oxygen species (ROS), especially the formation of hydroxyl radicals. So far as we can reach, there is no report concerning the relation between X-ray computed tomography examination and the blood ROS level. Therefore, we wish to conduct this study to clarify if the cardiac computed tomography angiography (cardiac CTA) may induce a higher level of ROS in the peripheral blood. Study subjects will be OPD patients who are arranged for cardiac CTA examination because of suspect coronary artery disease (CAD). In total, twenty cases will be enrolled for the study. The formal consent will be delivered and explained to the patients and families after the arrangement of cardiac CTA. It then will be retrieved just before the performance of cardiac CTA. For each enrolled case, peripheral blood will be sampled three times (once before and twice after the performance of cardiac CTA). Totally 60 blood samples will be collected from 20 study subjects within 3 months (January 1 ~ March 31, 2009). ROS level in the collected blood samples will be then measured, compared, and analyzed.

The clinically widely used X-ray computed tomography examination has a low-grade radiation effect and recently has attracted much attention concerning the possible adverse effects of radiation on human body [ref. 1-5]. The radiation is harmful to human tissues and cells mainly because it can interact with water (which makes up to 80% of cells) to generate reactive oxygen species (ROS), especially the formation of hydroxyl radicals. So far as we can reach, there is no report concerning the relation between X-ray computed tomography examination and the blood ROS level. Therefore, we wish to conduct this study to clarify if the routinely applied abdominal X-ray computed tomography examination may induce a higher level of ROS in the peripheral blood. Study subjects will be patients who are admitted to our hospital because of abdominal diseases that need to receive abdominal X-ray computed tomography examination for diagnosis. In total, sixty cases will be enrolled for the study. The formal consent will be delivered and explained to the patients and families several hours before the performance of abdominal X-ray computed tomography. The formal consent will be retrieved and then the peripheral blood will be sampled just before the performance of computed tomography.ROS level in the sampled peripheral blood, before and after the performance of abdominal X-ray computed tomography, will be measured, compared, and analyzed. Totally 120 blood samples, including 60 samples just before and 60 samples 2 hours after the performance of computed tomography, will be collected from 60 study subjects within 5 months (August 10 ~ December 30, 2008). Reactive oxygen species（ROS）levels will be measured by a chemiluminescence (CL) analysing system (CLD-110, Tohoku Electronic Industrial, Sendai, Japan).