There are about 21062 clinical studies being (or have been) conducted in Italy. The country of the clinical trial is determined by the location of where the clinical research is being studied. Most studies are often held in multiple locations & countries.
The main idea behind MICRO-LEARNER is to provide new insights about the response of healthy tissues to radiation by using information from the micro-environment obtained by biological measurements and imaging. This new knowledge will be included in current available predictive models of radio-induced toxicity, thus allowing to add unique biological characteristics of patients to dosimetry and treatment/clinical related variables. MICRO-LEARNER focuses on prostate cancer (PCa) and head-and-neck cancer (HNCa). For both cancers, radiotherapy is effectively used as curative treatment, in single modality or within a multidisciplinary approach including surgery (PCa) and/or chemotherapy (HNCa). Prediction and reduction of radio-induced side effects are becoming a priority: for PCa, high survival rates should be accompanied by a very low rate of moderate/severe toxicities; for HNCa, there is the need to tailor radiation dose according to disease recurrence risk profile. The shared aim of both cancers is to balance the improvement in outcome with a well-tolerated toxicity profile. Recent research indicates that the intestinal/salivary bacteria are strongly suspected of being very important in mediating the response to inflammation and lesions. Although their balance deeply changes during radiotherapy, studies done so far in the field of the microbiota-host relationship in radiotherapy have not addressed their role in insurgence of radiation toxicity. In this study, the investigators will assess how microbial populations evolve and how this influences the host and radiation induced toxicity in a significant number of patients. Moreover, the individual response at the tissue microstructure level, through analysis of images with advanced bioengineering techniques, will be determined. Results from this research, besides suggesting new ways to predict patients at risk of relevant side-effects, may also suggest possible treatments to change the baseline microbiota of patients at high risk or to modify it during therapy, in order to mitigate toxicity. Understanding the microbiota-radiotherapy interaction may thus lead to novel, effective and inexpensive ways of assessing and managing complications of cancer treatment.
The main purpose of the present study is to compare the diagnostic performance of three non-invasive stiffness imaging methods (TE, SWE and MRE) in a consecutive cohort of patients with chronic viral C hepatitis or co-infected by HCV+ Human Human Immunodeficiency Virus (HIV).
Comparing the cardio-respiratory adaptation and differences to non invasive ventilation techniques, nasal intermittent positive pressure ventilation (NIPPV) non synchronized vs synchronized (SNIPPV) in preterm newborns (gestational age at birth < 32 weeks) at their first approach to non invasive ventilation as first intention (soon after birth) or after extubation.
Background: Antithrombotic therapy in the context of treatment related thrombocytopenia (i.e. low levels of platelets) is not uncommon. Guidelines are based upon a paucity of retrospective data and focus on the scenario of cancer associated venous thrombosis and low molecular weight heparin treatment. Even less is known regarding direct oral anticoagulants, antiplatelet therapy, or anticoagulation prescribed for other indications. Aims: The study aims are to evaluate how physicians manage anticoagulant and antiplatelet medication in patients with hematological malignancy and thrombocytopenia, and to assess the frequency of bleeding and thrombosis. Additional aims are to assess how management changes affect drug activity and blood clotting (coagulation), and to evaluate the use of platelet transfusions. Design: The investigators plan a multinational prospective registry of patients admitted to the inpatient hematology department or outpatient clinic at one of the study centers. Patients with hematological malignancies, platelets below 50 X 109/L, and anticoagulant and/or antiplatelet medication will be studied. Patients will be enrolled when the combination of antiplatelet/anticoagulant medication and thrombocytopenia is first detected. Patients will be followed until 30 days after the baseline study visit (which occurs 30 days after enrollment or when platelets < 50*109/L, whichever come first) or death. Patients will be indexed at the time of baseline visit. Patients will be excluded from study analysis if one of the following events occurs before study index: Withdrawal of consent, death, clinically-relevant non-major bleeding or the composite primary outcome. Risk factors for bleeding and thrombosis will be recorded at baseline. Parameters from routine blood tests will be recorded throughout the study. During the study major bleeding events and thrombosis will be recorded. Investigational blood tests assessing coagulation and drug activity will be drawn at baseline (=study index). Throughout the study all management decisions regarding antithrombotic therapy, including platelet and red blood cell transfusion, will be recorded. This is an observational study and management will be solely at the discretion of the physician. Analysis: The investigators will first look at the frequency of either bleeding or thrombosis according to the type of management strategy and evaluate the platelet threshold at which a given management strategy is employed. At the next stage, in selected subgroups, the optimal management strategy with respect to bleeding/thrombotic risk, will be determined.
Some alterations of the foveal contour do not meet the criteria established for the definition of lamellar macular hole on the basis of optical coherence tomography (OCT). However, these alterations may show an appearance, on blue fundus autofluorescence (B-FAF) imaging, reminiscent of lamellar macular hole. The aim of the study is to evaluate in detail these alterations recording simultaneously OCT and B-FAF.
Myoinositol (MI) and D-chiro inositol (DCI) are isomeric forms of inositol that were found to have insulin-like properties, acting as second messengers in the insulin intracellular pathway; both of these molecules are involved in the increasing insulin sensitivity of different tissues to improve metabolic and ovulatory functions. Myoinositol is the predominant form that can be found in nature and food. Inositol has been mainly used as a supplement in treating several pathologies such as polycystic ovary syndrome (PCOS), metabolic syndrome, type 2 diabetes mellitus (T2DM) and gestational diabetes (GDM). In the case of GDM, a condition defined as a glucose impairment first detected in pregnancy, a preventive role of inositol for GDM onset was recognized. In addition, inositol has been studied as a therapeutic option for the treatment of GDM and T2DM. The main effect of inositol is decreasing the level of insulin resistance. Consequently, a potential role of inositol as a treatment option could be hypothesized for other conditions typically characterized by insulin resistance like metabolic syndrome and obesity. Zinc also plays an important role in insulin action and carbohydrate metabolism. It may also have a protective role in the prevention of atherogenesis. Several human studies have demonstrated that Zinc supplementation reduces total cholesterol, LDL cholesterol and triglycerides, in addition to increasing the HDL cholesterol levels. Studies have shown that diabetes is accompanied by hypozincemia and high levels of Zinc in urine. In addition Zinc is also an integral part of key anti-oxidant enzymes and Zinc deficiency impairs their synthesis, resulting in increased oxidative stress. A supplementation with Myo-Inositol and Zinc could represent a valid strategy in paediatric obesity in addiction to a standard approach. The purpose of our study is to evaluate the supplementation of Myo-inositol and Zinc in the treatment of paediatric obesity.
Evaluate incidence, clinical indications, and feasibility of PCI performed after TAVI.
Admission to an Intensive Care Unit (ICU) is one of the major causes of stress and both physical and emotional difficulties for critically ill patients, both because of the illness that caused the admission and of the ICU nevironment itself. Despite the use of protocols and tools to evaluate sedation, many patients continue to have high levels of anxiety. An inadequate treatment of this condition is associated with increased sympathetic activity which causes dyspnea and an increase in myocardial oxygen consumption. Sedative drugs, on the other side, may have significant side effects. In view of this, there is clear need to find new strategies and instruments allowing for the maximization of critical patients' comfort, by promoting pain, anxiety, stress and agitation relief and minimising the need of sedative therapy. The main hypothesis of this study is that the use of music therapy for critically ill patients can lead to a significant increase of the days free from neuroactive therapy (analgesics, sedatives, antianxiety meds, antipsychotics) in the first 28 days following Intensive Care Unit admission. To this purpose, data obtained from 3 groups of patients will be compared - a group with individual treatment administered by a music therapist and delivered by headphones, a group with a generalised treatment, through the creation of a weekly musical program continuously broadcasted in the hospital room, and a control group.
Although colonoscopy with polypectomy can prevent up to 80% of colorectal cancers, a significant adenoma miss rate still exists, particularly in the right colon. Optimizing the detection of adenomas and sessile serrated lesions in the right colon is crucial to increase the effectiveness of colonoscopy in colorectal cancer prevention. Last generation Fuji videocolonscopes incorporates the Linked Color Imaging (LCI), a recently developed technology that differentiates the red colour spectrum more effectively than White Light imaging thanks to its optimal pre-process composition of light spectrum and advanced signal processing. The increased colour contrast results in more accurate delineation of abnormal inflammatory or neoplastic findings of colonic mucosa. Preliminary data suggest that LCI may be improve the detection of neoplastic lesion of colon. The investigators performe a tandem prospective study to compare the right colon adenoma miss rates of LCI colonoscopy with those of conventional white light colonoscopy. Therefore participants scheduled for colonoscopy for the assessment of symptoms or for colorectal cancer screening/surveillance receive the examination of the right colon twice, in a back to back fashion, with standard white light (WL) and with LCI. Patients are randomly assigned (1:1), via computer-generated randomisation with block size of 20, to which procedure is done first. The endoscopist are masked to group allocation until immediately before the cecum is reached. Examinations are performed with Fuji videocolonscopes series 700 (EC-760R, EC-760ZP).
Phase I-II, single-arm, non-randomized, open-label, multicenter, international clinical trial, with two stages. Stage one has two cohorts (soft tissue sarcoma and bone sarcoma) and stage two has eight cohorts (DDCS, EMC, VS, SFT, CCS, ASPS, UPS, LMS and OS). Nine sites in Spain, 3 sites in Italy and 1 site in the United Kingdom. Stage 1 (PHASE 1 and PHASE 2) Objective: To determine the recommended dose of the sunitinib plus nivolumab combination for phase II part. To evaluate the efficacy of the sunitinib plus nivolumab combination as measured by the progression-free survival rate (PFSR) at 6 months in patients with advanced soft tissue and bone sarcomas. Treatment: Adult patients will receive an initial induction phase (IP) from day 1 to day 14 of sunitinib 37.5 mg/day followed by a maintenance phase (MP) of sunitinib 37.5 mg/day continuously + nivolumab 3 mg/kg intravenous every 2 weeks infused over 1 hour. If three or more DLTs occur from day 15 to 42, for an initial set of 10 patients, sunitinib dose will be lowered to 25 mg/day or treatment schedule will be changed to 2 weeks on and one week off until recovery from toxicities. Stage 2 C1 to 6 Objective: To evaluate the efficacy of the sunitinib plus nivolumab combination as measured by PFSR at 6 months (CS/DDCS, EMC, VS, SFT, CCS cohorts) and at 12 months (ASPS cohort). Treatment: Adult patients will receive an initial induction phase (IP) from day 1 to day 14 of sunitinib 37.5 mg/day followed by a maintenance phase (MP) of sunitinib 25mg/day continuously + nivolumab 240mg every 2 weeks. Pediatric patients will receive an initial IP from day 1 to day 14 of (<18 years) sunitinib at 25 mg/day unless the body surface area (BSA) of the patient is >1.7. If BSA is >1.7, then sunitinib 37.5 mg/day will be given followed by a MP of sunitinib 25 mg/day continuously + nivolumab 240 mg every 2 weeks regimen (if weight ≥40 kg) or sunitinib 25 mg/day continuously + nivolumab 3 mg/kg every 2 weeks regimen (if weight <40kg). C 7 Objective: To determine the MTD of the epirubicin + ifosfamide + nivolumab combination in undifferentiated pleomorphic sarcoma and of the doxorubicin + dacarbazine + nivolumab combination in leiomyosarcoma. Treatment:Cohort 7a dose level 0: Patients will receive epirubicin dose of 60 mg/m2/d, d1 and d2 IV 20 minutes; followed by ifosfamide 3 g/m2/d d1-3, IV 3h with MESNA protection (40% of total dose of ifosfamide in each administration at 0, 3 and 6 h from ifosfamide initiation). Once finished Ifosfamide infusion of day 3, nivolumab is administered during 30 minutes, at dose of 360 mg IV, Q3W. GCSF support is mandatory. If three or more DLTs occur nivolumab dose will be lowered to dose level -1. Cohort 7b dose level 0: Patients will receive doxorubicin at dose of 75 mg/m2/d, d1 IV 20 minutes; followed by dacarbazine 400 mg//m2/d IV 60 minutes. Dacarbazine is administered also on day 2 of cycle. Once finished Dacarbazine infusion of day 2, nivolumab is administered for 30 minutes, at dose of 360 mg IV, Q3W. GCSF support is mandatory. If three or more DLTs occur nivolumab dose will be lowered to dose level -1 where patients will receive doxorubicin at dose of 75 mg/m2/d, d1 IV 20 minutes; followed by dacarbazine 400 mg//m2/d IV 60 minutes. Dacarbazine is administered also on day 2 of cycle. Once finished dacarbazine infusion of day 2, nivolumab is administered for 30 minutes, at dose of 240 mg IV, Q3W. GCSF support is mandatory. One-year maintenance of nivolumab is foreseen in the absence of progressive disease. C 8 Objectives:To determine the MTD of the MAP + nivolumab combination (phase I). Proportion of patients achieving good pathological response (phase II) Treatment dose level 0: In the IP, patients will receive CDDP 120 mg/m2 in 48h IV infusion (days 1-2) followed by doxorubicin 75 mg/m2 in 48h IV infusion (days 3-4). CDDP and doxorubicin will be given on days 1-4 and 36-39. Nivolumab administration will start on day 4 at flat dose 240 mg (after the end of doxorubicin), being the following doses administered on days 18, 39, and 53 (240 mg). HD methotrexate at 12 g/m2 in 2-h infusion will be administered on days 22, 29, 57, and 64. Surgery will be performed after finishing IP. Adjuvant chemotherapy will be administered after surgery. During the MP patients will receive nivolumab on day 210, every two weeks up to day 364. If three or more DLTs occur, then nivolumab dose level -1 will be activated.