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Clinical Trial Summary

Primary and secondary brain tumors are a constant challenge for the medicine. Tissue sensitivity to ionizing radiation differs and depends on numerous factors and the same dose of radiation may produce different effects in particular structures of the CNS. It can also affect the surrounding healthy tissues and lead to adverse effects like the cognitive or physical function impairment. One of brain structures most sensitive to ionizing radiation is the limbic system, especially the hippocampus, because it is here that the postnatal neurogenesis takes place via neural stem cells, which are a self-renewing population of precursor cells. There have been no studies that would thoroughly examine the impact of different CNS radiation therapy techniques on the cognitive function, potential neuroplasticity markers or blood-brain barrier damage in brain tumor patients with a concomitant use of neurocognitive combination therapies or physical exercise, and their impact on the CNS function. The aim of the study is to assess the impact of selected RT techniques: IMRT, WBRT, and CyberKnife (SRS) on the processes regulating cognitive and physical function in patients with primary (Group III and IV, WHO, 2016) and metastatic CNS tumors. The secondary objective is the analysis of the effect of selected forms of neurorehabilitation on the parameters studied. The study will be a prospective clinical trial conducted in 150 patients. Patient evaluation will be carried out before RT, after RT, during a follow-up visit-3 months after RT, and finally after 6 months. The methods will be used: analysis of the blood-brain barrier permeability markers including exact connection proteins, markers confirming neuroplasticity of the brain, cerebral secretory activity, and onco- and anti-neuronal antibody activity, brain structure analysis (MRI) and volume testing of selected brain structures, and assessment of cognitive and physical function of the patients. The study will be a part of the search trend aiming to explain the mechanism of the formation of cognitive-behavioral disorders in humans based on the most fundamental principles governing information processing in CNS, and the impact of neoplasia and ionizing radiation on selected brain structures and functions. The results of the study might become a starting point for the formulation of new guidelines on the level of physical activity or cognitive exercise in patients treated with CNS radiation therapy.

Clinical Trial Description

Every year, thousands of patients worldwide undergo radiotherapy (RT) for primary brain tumors (BT) and brain metastases originating from extracranial tumors. Radiation injury is multifactorial and is characterized by e.g. vascular abnormalities, inflammation, gliosis, demyelination, and often at high doses, white matter necrosis. Standard treatment of BT includes high dose megavoltage radiation to the cranial vault, but 50-90% of overall survivors exhibit impaired cognition and functional dysfunction. The radiation cognitive syndrome is still poorly understood, and there is no effective prevention or long-term treatment. Therefore, the investigators will analyze specific molecular markers which may have a relationship with morfological changes in the brain, its secretive and imunological role as well as cognitive function and postulate that previously undetected and comparatively subtle early manifestations of irradiation damage to CNS may synergize over time to form macro- and microstructural abnormalities. The investigators plan to corroborate a hypothesis that impairment of cognitive and motor functions in patients undergoing RT can be limited. In study, the investigators will quantitatively and objectively evaluate the effects of exercise on brain activity during cognitive and physical training in BT patients treated with RT. Therefore, specific objectives include: 1. Analysis of the molecular mechanism in BBB disruption. 2. Multidimensional analysis of specific neuroplasticity markers, onconeural-antibodies etc. 3. Assessment of the volume of the brain structures and their morphology. 4. Analysis of the results of neurocognitive and functional tests. Significance of the project The Response Assessment in Neuro-Oncology working group recommended that neurocognitive outcome should be considered one of the primary endpoints in BT clinical trials. Despite the importance and clear concern about radiation-induced cognitive decline, the pathophysiology driving the progression of this syndrome remains poorly understood, and there are no effective preventative measures or long-term treatments. To date, there has been no study comparing different techniques of irradiation, namely intensity-modulated photon RT (IMRT), whole brain RT (WBRT), and stereotactic radiosurgery (CyberKnife), in BT patients in the aspect of pathophysiology of BBB or immunological aspects, as well as neurogenesis, neuroplasticity. These methods will be rely on a detailed understanding of radiation dose-volume effects, which link the incidence and severity of neurocognitive and functional impairment to specific volumes and morphology of normal brain. Possible explanations for the preservation of cognition and behavior include the resiliency of the cerebellum, frontal and tempo-parietal lobes, the hippocampus-mammillary complex and other supratentorial regions. Radiation is now known to suppress the proliferation of progenitor cells and their differentiation into neurons. The relatively recent discovery of neural stem cells in discrete areas of the brain is the impetus behind the most recent potential target for radiation. Early changes below the gross anatomical level, including a decline in neurogenesis, microvascular damage, subtle loss of white matter integrity, and disturbances of neuronal morphophysiology, may interact and progressively alter neuronal stem cell niches to impede neuronal function, viability, and progenitor cell differentiation. Therefore, the investigators will thoroughly observe the mechanism of neurogenesis and the possible improvement of neuroprotection and neuroregeneration in BT patients undergoing various forms of RT. Previous research has shown that physical exercise in healthy people is associated with increased structural and functional integrity in regions that overlap with brain functions, including the frontal, motor cortex, and the cerebellum. The precise neurobiological mechanism for cognitive effects of rehabilitation remains unknown, however a vast rodent literature supports a central role of protective neurotrophins, which have been shown to facilitate production of new neurons in the hippocampus, promote synaptic plasticity in cerebral cortex, and enhance growth and protection of neurovasculature and suggests exercise may promote formation and strengthening of connections between the hippocampus and its widespread cortical connections, which improve cognitive and behaviour functioning. However, the specific brain structure and function regions activated during rehabilitation exercise in patients with BT during oncological treatment still remain largely undefined. The study results obtained in this project will provide new knowledge about metabolic and structural pathways of the CNS in the context of RT and will also provide the basis for the development of regenerative medicine in oncology. Work plan The investigators will conduct study in the Greater Poland Cancer Centre. The participants will be enrolled in this study according study criteria from the Department of Radiotherapy after medical assessment by an oncologist (physician). Evaluation of the all subjects will be carried out: at baseline (T0), one month after RT (T1), and control (T2) - 3 months after RT and final (T3) - 6 months after RT (unless there is a deterioration of health making the assessment impossible, or death). The investigators will monitor the patients by: A. Analysis of the patient's blood serum: 1/ markers of BBB disruption: S-100β and circulating tight junction-related proteins (occludin, claudin-5, zonula occludens-1); 2/ factors with potential effect on neuroplasticity - immune-cell production of neurotrophins e.g. brain-derived neurotrophic factor, beta-nerve growth factor, neurotrophin-3, neurotrophin-4/5; 3/ activity of carnosinase and its isoenzymes; 4/ onconeural antibodies (anti-Hu, anti-Ri, anti-Yo, anti-Ma/Ta, anti-Cv2, and anti-amphiphysin as well as anti-myelin, anti-MAG, anti-GAD) and anti-surface neuronal antigens (anti-NMDA, anti-AMPA, anti-GABA, anti-DPPX, anti-LGI1, anti-CASPR) to investigate correlations with types of BT, RT, and possible paraneoplastic syndromes or cognitive impairment. B. Assessment of brain structures and volume testing of selected brain structures. C. Cognitive and functional assessment using clinical tests. All participants groups treated with different RT techniques (three groups) will by randomly divided to two subgroups: exercise subgroup - EG (these are the patients who will have regular cognitive and physical training) and second subgroup (control group - CG). Analysis of risk in planned study will be connected with failure to reach targeted number of patients (the investigators will enlarge the recruitment pool across additionally cancer hospitals) or increase dropout rate (motivational information will be provided to participants and clinicians). The Greater Poland Cancer Centre has very modern research infrastructure allowing for execution of the proposed project. Methods of research The study protocol was accepted by the Ethics Committee of Poznan University of Medical Sciences (No. 703/18), and each recruited participant will be given a written informed consent. The investigators will enroll patients with BT using the updated 2016 edition of the World Health Organization Classification of Tumors of CNS which uses molecular parameters and the histology to define the main tumor categories for the first time. The investigators will analyze 150 patients together with three different CNS groups of tumors: from III and IV brain tumor groups, and metastatic tumors. The study will include patients with BT enrolled to RT, between 18-70 y o , in good general health conditions (according to Eastern Cooperative Oncology Group 0-2), after obtaining informed consent for participation in the study. The investigators are planning to exclude patients with numerous tumors (> 2), with psychological or psychiatric illnesses treated pharmacologically, or with other neurological disorders (e.g. sclerosis multiplex, Parkinson's disease, meningitis, etc.), or significant clinical circulatory failure (> III NYHA). Enrolled patients will be treated with the one of three RT techniques in the Department of Radiotherapy: 1) CyberKnife, which relies on precise 3D imaging and localization to deliver ablative doses of radiation to the tumor, and can significantly reduce exposure of healthy brain tissue (18 Gy per dose to total 66 Gy) or 2) IMRT using conventional fractionation of 1.8 Gy per day to total dose 54 Gy or 2 Gy per dose to the total dose 60 Gy) or 3) WBRT as the treatment choice for metastatic tumors - the fractionation schedule used is 30 Gy delivered in 10 fractions or 20 Gy in 5 days. Participants randomly selected to EG will perform cognitive and physical training (120 min./5 times per week during study observation) conducted by rehabilitation staff who will be employed for this project: physiotherapist and neuropsychologist. For neuropsychological rehabilitation, the investigators will use the RehaCom system - a special neurocognitive programs and software. During RT, EG will do physical training (such as cycling, running on properly calibrated equipment as well as neuromuscular reeducation exercises using advanced technical tool - Neuroforma computer software) with maximum heart rate to 70%HRmax. After RT, participants in EG will do special exercise training at home under supervision of the hospital staff. Participants from CG will be provided with normal hospital care during RT and next will conduct a normal daily activity at home. According to the study evaluation plan, all participants will be observed before and after end of RT, and during control visits (T2, T3) at cancer center. Patients' blood samples will be collected in the Laboratory Ward in the morning, before breakfast according to the study plan. The investigators will evaluate individual markers in the Department of Radiobiology in collaboration from the Department of Neurochemistry and Neuropathology at Poznan University of Medical Sciences, because the Radiobiology Laboratory is fully equipped with all specialized, high-tech instruments required for the execution of this project.. In the Department of Rehabilitation in cancer center, all study participants will be evaluated in terms of cognitive and physical functioning. Raw cognitive test scores will be compared with published normative values according to age and to education. The investigators will include in the study evaluation with the use of Mini-Mental State Examination (MMSE), Benton Visual Retention Test (BVRT), California Verbal Learning Test (CVLT), Color trials test (CTT), Wisconsin Card Sorting Test (WCST), Trail Making Test A and B (TMT A & B), Montreal Cognitive Assessment (MoCA) 7.2 scale, and Addenbrooke's Cognitive Examination III (ACE III) test as well as the Psychology Experiment Building Language (PEBL) software for objective evaluation of selected cognitive and behavior functions. For general assessment of physical, psychological and social function the investigators will use the Functional Independence Measures (FIM) scale. This will be an unprecedented study yielding unique results on neuroscience in the process of cancer treatment with modern techniques. ;

Study Design

Related Conditions & MeSH terms

NCT number NCT05192447
Study type Interventional
Source The Greater Poland Cancer Centre
Contact Katarzyna Hojan, MD, PhD
Phone +48601509967
Email [email protected]
Status Recruiting
Phase N/A
Start date April 1, 2021
Completion date March 31, 2025

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