Active clinical trials for "Lung Neoplasms"

In non-small celled lung cancer (NSCLC) 10-15% of the patients harbor a mutation in the tumor's epidermal growth factor receptor (EGFR M+). This receptor is the target for treatment with erlotinib. Identification of EGFR M+ is done on a biopsy, which can be difficult to retrieve. A new blood based test identifies EGFR M+ in plasma, which makes it possible to monitor the level of EGFR M+ in the patient's blood during treatment. This enables both a closer monitoring of the treatment with erlotinib and a closer study of the resistance mechanisms that almost inevitably develop during treatment. A pilot study demonstrated that the quantity of EGFR M+ in plasma correlates to the response to treatment and might be used to predict disease progression. Patients with EGFR M+ NSCLC referred to a participating oncology department may be enrolled in the project. The investigators expect to include 250 patients over a four-year period. Patients will receive standard treatment and follow up. Standard 1st line treatment for patients with metastatic disease is tyrosine kinase inhibitors (TKI) eg. erlotinib. A biopsy and blood sample will be retrieved before treatment with is initiated. The patient will be monitored prospectively with blood samples every 3rd-6th week both during erlotinib treatment, subsequent lines of treatment and treatment intermissions. The blood samples are analyzed for subtypes of EGFR M+ both sensitizing mutations and mutations known to drive resistance to erlotinib treatment. In the event of occurring resistance mutations or unexpected increase in quantity of sensitizing mutations clinical action will be taken; initially in the form of additional scans searching for signs of disease progression. Clinical data will be retrieved from the patient's medical journal. Patients are followed until death or at least 24 months after inclusion. Any excess biological material will be stored for up to 15 years in a bio bank for future research purposes. We expect our results to validate the use of EGFR M+ detection and quantification via blood samples in a clinically relevant setting. The investigators expect earlier identification of disease progression to allow more cases of local treatment thus - hopefully - increasing the progression free survival. Continued blood monitoring in subsequent lines of treatment and treatment intermissions will add to our knowledge of the nature of EGFR M+ NSCLC. The sampling of biological material allows us to further investigate the biology of resistance.

Lung cancer is the leading cause of cancer-related death worldwide and is well known to remain a major health problem. Non-small-cell lung cancer (NSCLC) constitutes more than 80% of all the cases of lung cancer. Today, NSCLC can be defined by various molecular criteria. Especially, somatic mutations within the epidermal growth factor receptor (EGFR) gene itself were discovered in a subset of NSCLC patients. Two activating EGFR mutations are in-frame deletion in exon 19 and the substitutions for L858R in exon 21, which account for 85% of all clinically important mutations related to EGFR TKI sensitivity. Besides two activating EGFR mutations, other EGFR mutations in NSCLC have been discovered. G719 and L861 are reported to have intermediate sensitivity to EGFR TKI. And in-frame insertions within exon 20 and T790, which are known to be resistant to EGFR TKIs. However, there are still other EGFR mutations such as E709 and S768 as well as doublet EGFR mutations are also observed. These rare mutations have not been fully described and data on their correlation with response to EGFR-TKIs are still unclear. Research hypothesis Rare EGFR mutations of unknown clinical significance in NSCLC patients, which are distinguish from mutations such as deletion in exon 19, L858 and insertion in exon 20, have some possibility of EGFR TKI sensitivity. Rationale for conducting this study It has an opportunity to be shown the efficacy of EGFR TKIs in patients with rare EGFR mutation in large number of patients in Korea (Asia) during the short period.

A small proportion of patients with lung cancer present with a solitary pulmonary nodule (SPN). This is an important group of patients because if it is lung cancer, presentation as a SPN represents early disease, which following surgery has a high 5 year survival rate. However as not all SPNs are lung cancer it would be unethical to biopsy every case. Clinical guidelines recommend that SPNs should undergo an initial (FDG)-PET/CT scan, which may give more information about the SPN and may indicate if it is likely to be lung cancer. However in many cases it does not and current practice is to monitor the SPN with a series of CT scans over 2 years to look for changes or growth which may/ but not always indicate lung cancer. If no changes are observed over 2 years the SPN is considered not lung cancer. This is both expensive for the National Health Service (NHS) and worrying for the patient in terms of monitoring CT costs and delayed treatment due to length of time to diagnosis. This study examines the diagnostic capacity of using a different CT scan. Dynamic Contrast Enhanced -CT(DCE-CT). DCE-CT and FDG-PET/CT scans give different information about the SPN and the investigators will look to see if information from either scan or combined information from both scans may be better in the diagnosis of early stage lung cancer. The investigators will also undertake a review of previous studies that have used these scans and use data from both the review and the trial to look at the cost effectiveness of using DCE-CT in the diagnosis of SPN. The trial will recruit 375 people who have a SPN detected by a normal CT scan which requires a FDG-PET/CT scan. In addition they will receive a DCE-CT scan either on the same day or within three weeks of the FDG-PET/CT scan. This is the only extra procedure that will take place to normal NHS care, however we will collect clinical and outcome data over the next two years. The study is coordinated by Southampton University clinical trials unit. Recruitment between January 2013 - April 2016, from up to 14 UK sites. Data analysis and conclusions are expected by the end of 2018. The study is funded by the NIHR-HTA

This is a phase IV multicenter trial to evaluate the mechanisms of resistance and pharmacoeconomic (PE) impact of crizotinib and its companion diagnostic test used in a real-life setting in advanced ALK-positive non-small cell lung cancer (NSCLC) patients. The study will address two anticipated issues surrounding personalized medicine and treatment with crizotinib: it will enable real-life Heath Economics and Outcome Research (HEOR) it will validate and/or identify new blood-based or tissue-based biomarkers of resistance to crizotinib. At least 30 patients will be recruited in Quebec and Ontario for the PE study. Patients will be asked to complete quality-of-life questionnaires at regular intervals in a real-life setting of treatment with crizotinib. Approximately 25 patients will be recruited to the biomarker sub-study in Quebec to understand resistance mechanisms of crizotinib. In these patients, a biopsy from any accessible metastatic lesion will be obtained when the patient is no longer responding to treatment, as well as blood sampling during regular treatment visits.

The purpose of this study is to compare early-stage peripheral non-small cell lung cancer lobectomy and sub-lobectomy surgery to evaluate if sub-lobectomy is as feasible and effective for the treatment of early-stage (diameter ≤2cm) peripheral non-small cell lung cancer as lobectomy.

Primary lung cancer is one of the most common malignancies in China, with 57 percent of patients being diagnosed at advanced stage. At present, advanced lung cancer has entered the era of precise treatment. So it is very important to determine the gene mutation status of the tumor and prescribe drugs at the targets. Liquid biopsy is a suitable alternative when tumor tissues are difficult to obtain. Liquid biopsy technique refers to the use of human body fluid as a sample source to detect the information of related diseases, including blood, urine, saliva and cerebrospinal fluid. It is non-invasive, fast and simple, and can avoid the problem of insufficient sample size and support for repeated sampling to continuously monitor disease. With the increasing incidence of lung cancer and the development of diagnosis and treatment technology, the survival period of patients has been extended, and the incidence and diagnosis rate of the brain metastasis of lung cancer have increased year by year. The brain metastasis of lung cancer is the most common type of brain metastatic tumor. The incidence rate is about 40-50%, and the prognosis is poor--the natural median survival period is about 1-2 months. Because of the impractical intracranial tumor biopsy and very low level of DNA in peripheral blood, cerebrospinal fluid, which makes close contact with brain tumors, becomes potential available samples. Several studies have shown that genetic testing of cerebrospinal fluid is feasible. Therefore, this study aims to test the cerebrospinal fluid, blood and tissue by the latest second-generation sequencing technology at different time points, to dynamically monitor the gene mutation status of cerebrospinal fluid, blood and tissue, to explore the role of cerebrospinal fluid biopsy in the diagnosis and treatment of non-small cell lung cancer with brain metastases.

Non-small cell lung cancer (NSCLC) accounts for more than two-thirds of lung cancer, which is the leading cause of cancer deaths in Taiwan. The overall prognosis of NSCLC is poor with low 5-year survival rates. Recent advances suggest that malignancy NSCLC cancers are the cancer stem cell (CSC) diseases. The stemness potentials of CSC with epithelial-mesenchymal transdifferentiation ensure their invasion and disseminate to metastsis organs. The self-renewal property of CSC mediates intrinsic drug resistance to cytotoxicity therapy and promoted aggressive relapse tumour. Metabolic reprogramming on bioenergetics of malignant cancer cells has been proposed as the key mediator in the stemness CSC development. Malignancy cells uptake glucose for fermented glycolysis to produce lactate which release resulted in acidified microenvironment to trigger the mTOR and sonic hedgehog metabolic stress signaling in supporting CSC stemness potentials. The metabostemness of cancer cells is the new-dimensional hallmark of malignancy tumour, which may serve as the diagnostic markers for the early detection of malignancy cancers. Folate-mediated one carbon metabolism coordinates glucose into amino acid metabolism to tailor the fuel metabolites in supporting macromolecule synthesis and to sustain the bioenergetics requirement. Acting as the metabolic stressor, low folate intake is associated with increased risks of lung cancers. Folate and one-carbon nutrient status of NSCLC patients in Taiwan, however, has not been assessed. The role of low folate metabolic stress (LFMS) in metabostemness marker and metastasis potentials of malignancy NSCLC is unexplored. The causal effect and the working mechanisms by which LFMS promoted NSCLC malignancy remain elusive.

This is a real-world non-interventional observational study. The study was designed to evaluate the effectiveness and safety of clinical treatments in the patients with advanced non-small cell lung cancer (NSCLC) complicated with brain metastases in clinical practice.

The investigators propose a non-invasive prognostic tool for TKIs resistance in patients with stage IV EGFR-mutant non-small cell lung cancer (NSCLC) by computed tomography phenotypic features, which can be conveniently translated to facilitate the pre-therapy individualized management of EGFR TKIs in this disease.

CtDNA detection is a noninvasive detection method, and the second generation of high-throughput gene sequencing (NGS) is an important means of detecting ctDNA, which can detect trace ctDNA from smaller plasma samples. This project is to study the role of ctDNA dynamic monitoring of stage I NSCLC by NGS technique to verify the prognostic predictive effect of ctDNA .