View clinical trials related to Cancer.
Filter by:The objective of this protocol is to develop an institution-wide liquid biopsy protocol that will establish a common process for collecting blood and corresponding archived tumor specimens for future research studies at the University Health Network's Princess Margaret Cancer Centre. Circulating cell-free nucleic acids (cfNA), including cell-free DNA (cfDNA) and cell-free RNA (cfRNA), are non-invasive, real-time biomarkers that can provide diagnostic and prognostic information before cancer diagnosis, during cancer treatment, and at disease progression. Cancer research scientists and clinicians at the Princess Margaret are interested in incorporating the collection of peripheral blood samples ("liquid biopsies") into research protocols as a means of non-invasively assessing tumor progression and response to treatment at multiple time points during a patient's course of disease.
The purpose of the LEAPS program is to understand how a trained lay health worker who engages with newly diagnosed patients after a diagnosis of an advanced stage of cancer can help to engage patients in advance care planning, improve patient satisfaction with their decision-making, activation, quality of life, and healthcare resource utilization.
Background: To effectively alleviate suffering and improve quality of life for patients with serious illness and their caregivers, palliative care (PC) services must be offered across multiple settings. Research is needed to determine how best to optimize home-based palliative care (HBPC) services to meet the needs of individuals with high symptom burden and functional limitations. Aim: The investigators will compare a standard HBPC model that includes routine home visits by a nurse and provider with a more efficient tech-supported HBPC model that promotes timely inter-professional team coordination via synchronous video consultation with the provider while the nurse is in the patient's home. The investigators hypothesize that tech-supported HBPC will be as effective as standard HBPC. Design: Cluster randomized trial. Registered nurses (n~130) will be randomly assigned to the tech-supported or standard HBPC model so that half of the patient-caregiver dyads will receive one of the two models. Setting/Participants: Kaiser Permanente (15 Southern California and Oregon sites). Patients (n=10,000) with any serious illness and a prognosis of 1-2 years and their caregivers (n=4,800) Methods: Patients and caregivers will receive standard PC services: comprehensive needs assessment and care planning, pain and symptom management, education/skills training, medication management, emotional/spiritual support; care coordination, referral to other services, and 24/7 phone assistance. Results: Primary patient outcomes: symptom improvement at 1 month and days spent at home in the last six months of life; caregiver outcome: perception of preparedness for caregiving. Conclusion: Should the more efficient tech-supported HBPC model achieves comparable improvements in outcomes that matter most to patients and caregivers, this would have a lasting impact on PC practice and policy.
The growing incidence of cancer associated to an aging population represents an epidemiologic reality that requires questioning access to care and prognosis in elderly with cancer, for which disparities have been highlighted. However, generally speaking, studies are limited in that they overlook geriatric-specific factors. The aim of this work was to study sociodemographic, socioeconomic and clinical determinants of access to care (cancer stage, cancer treatment) and prognosis (functional decline, survival) in elderly cancer patients.
This study is a phase II, single-arm, open label study under an umbrella trial for NSCLC. This clinical study is targeted for the patients who harbor exon 14 skipping mutation of MET and all patients will be treated with Capmatinib. The treatment period begins on Day 1 of Cycle 1 and 1 cycle consists of 28 days.
This study is a phase II, single-arm, open label study. All participating patients must sign on the written informed consent form, and a separate form of consent will be used for the use of tissue for the biomarker research.
Heart rate variability biofeedback (HRV-B) is a complementary, non-pharmacologic therapy that is being tested to see if it can help cancer survivors reduce their symptoms of pain, stress, insomnia, fatigue, or depression. HRV-B is an interactive procedure in which participants relax and breathe regularly while watching the a computer screen. The computer screen provides feedback that helps people increase their heart rate variability.
The purpose of this study is to assess how bone density and body composition changes after a cancer patient completes treatment and through 12-weeks post-treatment. Patients who enroll in the 12-week exercise program, Moving On, and those that do not elect to participate in the Moving On program will both be tracked, with assessments including SOZO measurements, DEXA scan (bone density and whole body composition), performance status tests, food log, urine color test, and other study assessments.
To characterize the fecal, skin, nasal and oral microbiome and metabolome in patients with lung cancer and other malignancies, and correlate to treatment response and toxicities of various therapies including immunotherapy, chemotherapy and targeted therapy, etc.
Metabolic changes related to disease are the precursor to anatomical changes in tissues. Currently the imaging methods routinely used in clinical practice look at the anatomical changes. Whilst these methods are very helpful in making clinical decisions, they are far from being perfect. Early disease can be missed because these methods are not sensitive enough and it is not clear whether disease is present or not. Additionally, it is also difficult to know whether disease it aggressive or non-aggressive. Hyperpolarised MRI is a new imaging tool that may allow addressing these deficiencies in current imaging technology. The process of hyperpolarisation allows the production of an injectable solution that can produce signal on a standard MRI scanner inferring information about the metabolism occurring at a particular location. This technology has only just become available for clinical use. The initial stages of evaluation require the investigators to refine and develop the new imaging protocols so that assessment can be made as to whether consistent results can be achieved. Additionally, refining the imaging protocol could also aid in identifying where the best potential future clinical use of this technology should be targeted. Within this application the investigators aim to try out hyperpolarised MRI in a number of different cancers and also see whether it is useful to assess cardiac metabolism. The investigators will be using 13C-labelled metabolites (for this study 13C- pyruvate) which will allow interrogation of glucose metabolism. The derangement of glucose metabolism is common to a number of disease processes.