Search clinical trials by condition, location and status
This is Phase 1/2, multicenter, clinical study to evaluate the safety, efficacy, PK, and immunogenicity of IDE849 in subjects with DLL3-expressing tumors including SCLC.
Genes give your body instructions on how to make proteins. Proteins are needed to keep the body working properly. Many types of cancer are caused by changes in certain genes, making them faulty. Some people with non small cell lung cancer (NSCLC) have a faulty ALK gene. ALK stands for anaplastic lymphoma kinase. People with NSCLC who have the faulty ALK gene are called ALK-positive. ALK inhibitors are an approved treatment for people with ALK positive NSCLC. Some people stop responding to treatment with ALK inhibitors over time due to more changes happening in their faulty ALK gene, so there is an unmet medical need. Gilteritinib is an approved treatment for people with acute myeloid leukemia (AML) with the faulty FLT3 gene who haven't responded to previous treatment, or their cancer came back after previous treatment. Gilteritinib also blocks changes in the ALK gene which could help people with ALK-positive NSCLC. A study needs to be done with gilteritinib in people with ALK-positive NSCLC. The main aim of the study is to check the safety of gilteritinib in people with ALK-positive NSCLC and if they tolerate gilteritinib. People in this study will be adults with locally advanced or metastatic ALK-positive non-small cell lung cancer (NSCLC). Locally advanced means the cancer has spread to nearby tissue. Metastatic means the cancer has spread to other parts of the body. They have stopped responding to treatment with ALK inhibitors, including alectinib or lorlatinib, over time. The key reasons people cannot take part are if they have symptomatic cancers in the brain or nervous system, their cancer has spread to the thin tissue that covers the brain and spinal cord (leptomengingeal metastasis), have recently had or planning to have major surgery, have certain heart conditions, or have recently had an infection, a stroke or mini-stroke. People in the study will take tablets of gilteritinib once a day in a 28-day cycle. They may be given up to 2 different doses of gilteritinib. People in the study will start on the lower dose but can eventually switch to the higher dose if they tolerate the lower dose and meet the safety checks. Whilst taking gilteritinib, people will have regular scans of their tumors. People will continue taking gilteritinib until their cancer gets worse, they have medical problems from gilteritinib that they can't tolerate, they ask to stop taking gilteritinib, they start other cancer treatment or, sadly pass away. People will visit the clinic about 7 days and then 30 days after they stop taking gilteritinib. They will be asked about any medical problems and will have a safety check. After this, people who stopped taking gilteritinib, but their cancer hadn't become worse, will continue to have regular scans of their tumors. If their cancer does get worse, they will no longer have scans of their tumors. After finishing gilteritinib, people will be phoned every 12 weeks to check on their health. People will be in the study for up to 4 years, depending on how they respond to gilteritinib.
The goal of this trial is to compare the impact of two outreach strategies (high touch vs. standard outreach) on a collaborative care program delivered via telehealth to patients with lung cancer.
The goal of this randomized intervention trial is to determine the effect of bright light therapy on sleep disturbance, as well as to investigate the impacts of bright light therapy on biological age measured by clinical biomarkers. The main questions it aims to answer are: * Does bright light therapy improve sleep patterns (i.e., sleep onset latency, sleep disturbance, and sleep efficiency) in lung cancer patients? * Can bright light therapy slow the rate of aging measured by biological age in lung cancer patients? Researchers will compare bright light therapy group to control group to see if bright light works to reduce sleep disturbance and decelerate biological aging. Participants will: * Receive bright light exposure or usual light exposure every day for 4 weeks * Get blood draw at the baseline and at 4 weeks for clinical biomarkers tests * Complete self-reported sleep, fatigue and stress surveys at the baseline and at 4 weeks * Keep a daily sleep log
The purpose of this study is to compare the clinical benefit of the combination of BMS-986504 (a selective MTA-cooperative inhibitor of PRMT5) plus pembrolizumab and chemotherapy versus placebo plus pembrolizumab and chemotherapy in first-line metastatic non-small cell lung cancer participants with homozygous MTAP deletion
This is a single-armed screening research study which screens immediate family member of lung cancer patients with a driver mutation to see if lung cancer can be inherited and whether researchers can find lung cancer early. Immediate family members of lung cancer patients will be 40-80 years old and screened using a low dose CT scan.
The ON-SITE study represents a prospective, observational study focused on the training/tuning and pivotal validation of deep learning algorithms that detect cell/tissue morphology suspicious for cancer in biopsies of peripheral lung nodules/masses and mediastinal/hilar lymph nodes imaged with the NIO Laser Imaging System in the procedure room without requiring traditional sample processing. The study includes four arms based on biopsy location and biopsy modality/tool: 1. Transbronchial forceps biopsy of peripheral lung nodules/masses (peripheral-TBBx) 2. Transbronchial needle aspiration biopsy of peripheral lung nodules/masses (peripheral TBNA) 3. Transbronchial needle aspiration biopsy of mediastinal/hilar lymph nodes (EBUS-TBNA) 4. Transbronchial cryo biopsy of peripheral lung nodules/masses (peripheral-CBx)
The objective of this study is to build a prospective cohort in patients with locally advanced or metastatic NSCLC with common EGFR mutations. In NPM-002, there will be standardized data collection at baseline, on-treatment and at discontinuation of therapy. Patients who enroll prior to initiation of osimertinib treatment (\~30%) will undergo imaging with standardized intervals.
This phase II trial tests how well GT103 in combination with pembrolizumab works in treating patients with STK11 mutant non-small cell lung cancer that may have spread from where it first started to nearby tissue, lymph nodes, or distant parts of the body (advanced) or that has spread from where it first started (primary site) to other places in the body (metastatic). GT103 is a monoclonal antibody that may interfere with the ability of cancer cells to grow and spread. GT103 targets the tumor cell-protein complement factor H found on some cancer cells and may provide specific anti-tumor activity that may help block the formation of growths that may become cancer. Immunotherapy with monoclonal antibodies, such as pembrolizumab, may help the body's immune system attack the cancer, and may interfere with the ability of tumor cells to grow and spread. Giving GT103 in combination with pembrolizumab may kill more cancer cells and improve outcomes in patients with advanced or metastatic STK11 mutant non-small cell lung cancer.
The purpose of this research study is to test a new process for diagnosing lung cancer by examining changes to your DNA that can be detected from a blood test. The information we learn by doing this study could potentially help people in the future. Participants in this study will have blood samples collected, have their medical records reviewed by study personnel and fill out questionnaires at different time points during the study. Blood sample collection will occur during normal routine clinic visits. Participation in this study will last approximately 5 years.