View clinical trials related to Lung Cancer.
Filter by:The hypotheses of the study are as follows: - Mass-based inverse optimization in radiotherapy treatment planning will result in a reduction of normal tissue and organs at risk (OAR) doses for desired prescription therapeutic doses to the targets. - Dose-mass histograms (DMHs) may be more relevant to radiotherapy treatment planning and treatment plan assessment than the standard of care, realized through dose-volume histograms (DVHs)
Video-assisted thoracic surgery (VATS) anatomical lung resection provides an effective minimally invasive treatment strategy for stage I and II lung cancer. VATS lobectomy is associated with significantly less postoperative atrial fibrillation, blood transfusion, renal failure, and other complications when compared with lobectomy via thoracotomy. Although VATS lobectomy has been proven to be effective and safe in experienced hands, it is not devoid of risk. Intra-operative surgical complications can be at times catastrophic. Complications include: pulmonary vascular injuries (Pulmonary artery (PA), pulmonary vein) necessitating urgent conversion to open thoracotomy and even death. Causes of conversion included PA injury, difficult anatomy, bulky/calcified lymph nodes, and technical problems including stapler misfire. PA injury alone constituted 37.5% of all conversions. Proper dissection of all tissue around PA branches is sometime difficult especially in the presence of adhesions or large, calcified lymph nodes and may increase the risk of vascular injury. Currently, in spite of being a safe and effective technique in experienced hands, a minority of anatomical pulmonary resections are being performed by VATS. In an analysis utilizing the Nationwide Inpatient Sample (NIS) database in the United States, only 15% of anatomical lung resections were performed by VATS. The technical difficulty and danger of VATS lobectomy is directly related to PA branch manipulation, stapling and division. PA manipulation is the main hesitation of many thoracic surgeons regarding the adoption of VATS lobectomy. We believe that if we can decrease the manipulation and dissection required by the surgeon on the PA branches, we can make these procedures safe and therefore more prevalent for anatomical pulmonary resections.
This study will test feasibility, in smokers with lung, head & neck, and bladder cancers, that examines the effect of e-cigarette substitution, on measures of smoking-related toxicity and medical outcomes. The aim of the study is to determine the appeal of e-cigarettes compared to regular combustible cigarettes.
This is an open-label, multicenter, Phase 1b platform study in subjects with advanced or metastatic solid tumors (Part 1a) and subjects with selected solid tumors (Part 1b and Part 2). Two treatment groups (Group A and Group B) will be evaluated Part 1a utilizes a 3+3 design to evaluate pembrolizumab and INCB combinations in advanced solid tumors. Group A will evaluate a JAK inhibitor with JAK1 selectivity itacitinib (INCB039110) in combination with pembrolizumab (MK-3475) and Group B will evaluate a PI3K-delta inhibitor (INCB050465) in combination with pembrolizumab to determine the maximum tolerated dose (MTD) or PAD and recommend a dose for the Part 1b safety expansion with each combination. Once the recommended dose has been identified in Part 1a, subjects with select solid tumor types will be enrolled into safety expansion cohorts based upon prior treatment history with a PD-1 pathway-targeted agent (Part 1b) for each combination. Part 2 utilizes a Simon 2-Stage design to evaluate INCB050465 in combination with pembrolizumab in patients with small cell lung cancer (SCLC) and a 1 stage design to evaluate the combination in patients with non-small cell lung cancer (NSCLC) and urothelial cancer (UC).
The investigators prospectively evaluated in this study the efficacy and safety profiles of afatinib as 3rd or 4th line treatment after prior failure to systemic chemotherapy and first-generation EGFR-TKI under a Boehringer Ingelheim sponsored Compassionate Use Program (CUP), with comparison of our historical cohort who received erlotinib after previous failure to systemic chemotherapy and first-generation EGFR-TKI.
Patients are asked to participate in this study if they have been diagnosed with a thoracic carcinoma which includes lung cancer and have a gene mutation (alteration in the body's genetic instructions) and after undergoing treatment the cancer has come back, progressed, or shown a partial response on standard treatment.
The Lung Cancer Indicator Detection (LuCID) study investigates the the diagnostic accuracy of FAIMS for diagnosis of lung cancer by analysis of exhaled Volatile Organic Compounds.
This study aims to first apply near-infrared fluorescence imaging technology in thoracic surgery with indocyanine green in China. To evaluate the feasibility usage of the investigators' fluorescence imaging systems and the safety applications in intraoperative sentinel lymph node mapping of lung and esophageal cancer, lung nodule imaging, lung segment resection boundary determination, esophagus - tubular anastomosis, thoracic duct imaging and chylothorax repairing thoracic surgery. Aim to achieve precise boundaries definition during thoracic surgery and realize accurate, minimally invasive thoracic surgery with fluorescence imaging technology.
While the process of fibrosis is essential for normal wound healing, an excessive and uncontrolled 'fibrotic' response can result in impaired tissue structure and function. In other words, affected 'fibrotic' tissues are unable to heal back to normal and therefore don't work as effectively as they normally would. In the case of the lung, fibrosis can occur across large parts of the lung such as in conditions like Idiopathic Pulmonary Fibrosis (IPF) and sarcoidosis or it can occur in much smaller patches such as around the borders of some lung tumours. At the moment the investigators don't fully understand the mechanisms of fibrosis and so therefore cannot monitor or treat these conditions as effectively as the investigators could. Despite the significant global financial burden of these diseases, treatment options are very limited and monitoring of disease progression remains a real challenge. In an effort to address this problem, the research group are currently developing a library of novel optical molecular imaging SmartProbes that are targeted against key pathological processes in the human lung. The functional profile for this portfolio of probes is that they exhibit high stability and specificity in vivo and have a short activation time permitting rapid point-of-care in situ molecular profiling enabling in the future, improved diagnostic certainty and stratification for targeted pharmacological intervention. This clinical microdosing study protocol focuses around the intrapulmonary delivery of microdoses (<100µg) of the Smartprobe Fibroproliferation (FIB ONE) to disparate regions of the human lung to highlight MMP activity combined with an active MMP inhibitor (AZD1236) to the distal lung. This approach will enable the research team to directly demonstrate the utility of this SmartProbe-based platform in the validation of drug target engagement in areas of suspected fibroproliferation (characterised by increased MMP activity).
Individuals with severe mental illness (SMI) including schizophrenia and bipolar disorder are dying younger than the general population; cancer is a leading cause of death in this population. People with SMI have higher rates of dying from breast, lung, and colon cancer, and disparities in treatment appear to be one contributing factor. Individuals with SMI may be diagnosed with more advanced stage cancer and less likely to receive stage-appropriate cancer treatment. Although collaborative care models integrating medical and psychiatric care have shown promise in other populations, the challenge of treating SMI and cancer is distinct and relatively understudied. Patients may have uncontrolled psychiatric symptoms that can impact their understanding of their diagnosis and treatment decisions. Oncologists have less training and inadequate time to address multiple unmet needs. Mental health care is frequently fragmented from cancer care. The investigators want to understand if it is helpful for patients with SMI to be connected to a psychiatrist and case manager when cancer is diagnosed. Optimizing psychiatric symptoms and facilitating communication between the patient, the oncology team, and mental health providers may improve care. The goal is to pilot a pragmatic intervention for patients with cancer and SMI that can be integrated into cancer care, is acceptable to patients and oncology clinicians, and may promote the delivery of stage-appropriate cancer treatment to an underserved population. Patients will be connected to a psychiatrist and case manager at cancer diagnosis who will follow the patient and communicate with the oncology team during the 12 week intervention. All participants will complete brief surveys at baseline, 4 weeks, and 12 weeks. Oncology clinicians will provide feedback about the intervention at 12 weeks. Cancer treatment received and healthcare utilization will be assessed at 6 months post-intervention.