View clinical trials related to Lung Neoplasms.
Filter by:This study is being done to compare a special type of Positron Emission Tomography (PET) scan with CT scan in patients with surgically removable lung cancer to see which method is more useful in measuring a response to treatment. A PET scan uses small amounts of radioactive material injected into the blood to show the internal workings of the body. In this study, we will use two radioactive materials: 18F-FLT (referred to as FLT) and 18F-FDG (referred to as FDG). FDG is used routinely in the staging of lung cancer and is approved by the FDA for that purpose. FLT is used in the special type of PET scan being assessed by this study. In addition the study will assess the effects of the combination of docetaxel and cisplatin (chemotherapeutic drugs) on certain pathological characteristics of the tumor. The combination of docetaxel and cisplatin is approved by the Food and Drug Administration (FDA) for the treatment of advanced/metastatic NSCLC (non-small cell lung cancer). It is not approved for use in patients who have surgically removable NSCLC. In such cases cisplatin is used as a single drug therapy before surgery. The FDA is allowing the use of docetaxel along with cisplatin in this research study.
The causes of failing nutrition status in advanced cancer are not well known. The way fat is moved, stored, burned or changed into other compounds may be affected and will be followed in patients using a tracer and other blood tests. The investigators hypothesize that fat loss and wasting results from low essential fatty acid availability in the body. Changes may occur in the liver that limits distribution and availability of fat to the body as an energy source or for other essential functions.
This open-label study will assess the efficacy and safety of Avastin with or without pemetrexed as maintenance therapy in patients with advanced, metastatic or recurrent non-small cell lung cancer. In Part 1, patients will receive 4 cycles of treatment with Avastin (7.5mg/kg iv) plus cisplatin (75mg/m2 iv) plus pemetrexed (500mg/m2 iv) on day 1 of each 3-week cycle. In Part 2, patients responding to treatment will be randomized to receive further treatment cycles of Avastin (7.5mg/kg iv every 3 weeks) with or without pemetrexed (500mg/m2 iv every 3 weeks). Anticipated time on study treatment is until disease progression. Target sample size is <500 individuals.
RATIONALE: Radiation therapy uses high-energy x-rays to kill tumor cells. Specialized radiation therapy that delivers a high dose of radiation directly to the tumor may kill more tumor cells and cause less damage to normal tissue. It is not yet known which regimen of stereotactic body radiation therapy is more effective in treating patients with non-small cell lung cancer. PURPOSE: This randomized phase II trial is studying the side effects of two radiation therapy regimens and to see how well they work in treating patients with stage I non-small cell lung cancer.
The rationale for this multicenter, phase II trial is to examine the impact of carboplatin/paclitaxel with bevacizumab in the preoperative treatment of patients with stage IB (> 4.0 cm), II, and select stage III NSCLC. If this novel regimen proves to be safe and active in this setting, this would provide rationale for further investigation in a larger, prospective, randomized setting.
This study aims to assess both the role and cost-effectiveness of EBUS in preoperative Non small cell lung cancer staging. This controlled multicentric study will be conducted in 22 centers in France. The study design includes two prospective phases. In phase 1, one investigator in each center will prospectively be evaluated for its ability to perform EBUS, with a required goal of 9 informative samplings out of 10 consecutive patients. The phase 2 will include the medico-economic assessment of the technique in the preoperative setting. A maximum of 420 patients for each phase is forecasted.
This is a phase I/II study in Japan to evaluate the safety of EMD531444 and its effects on survival time in patients with stage III unresectable non-small cell lung cancer.
1. To establish a retrospective compilation of clinical, histopathological, treatment and follow-up (clinic pathological) data of previous non-small cell lung cancer (NSCLC) cases. 2. To establish a prospective collection of clinic pathological information from NSCLC patients with corresponding blood and tissue samples 3. To discover and validate molecular biomarkers of survival and treatment outcome in NSCLC One of the current difficulties in the management of lung cancer is the decision to treat and the type of treatment to select. Thus there is a need for additional prognostic (indicative of disease aggressiveness) and predictive (indicative of likely response to treatment) markers for lung cancer. To conduct a successful prognostic and predictive marker program, several factors are required, including: a comprehensive database linking clinical, histopathological, treatment and outcome characteristics of each case, a collection of samples linked to the database that is suitable for the testing of candidate markers, and a multi-disciplinary, interdepartmental level of expertise in the management of lung cancer. Objective 1: A review of the case records will be conducted to extract clinical, treatment and follow-up data Objective 2: Patients aged 21 years or more with newly diagnosed, untreated non-small cell lung cancer shall be approached for consent. Patients will be identified through the pathology records, and from the study investigators' clinic. After subject consent, baseline characteristics will be obtained. Follow up data on therapies received and toxicities encountered will be obtained. Tumor samples will be obtained only from patients with NSCLC undergoing surgery as part of routine clinical care. The surgical specimen will be sent to Pathology to verify the adequacy of the diagnostic sample as per usual practice. Blood will be collected at the baseline (or prior to any anti-cancer treatment) and will be sampled again at the time of relapse or disease progression. Collection will entail drawing 7ml blood into a Vacutainer CPT tube (Becton Dickinson, USA), centrifugation, extraction of a separated layer of mononuclear cells (MNC), labeling followed by storage below -80oC. The frequency of blood drawn will be about 1-5 times (7-35mls total). The number of times depends on whether the lung cancer relapses and in the advanced stage, how often the lung cancer relapses after treatment. DNA and RNA will be extracted by CSIS and stored in freezer space there. Stored samples will be used for investigation of prognostic and predictive markers of outcome and for discovery of novel molecular alterations Objective 3: Biomarker analysis of tumor and blood. Blood will be enriched for circulating tumor cells (CTC) using previously optimized methods (11) and DNA will be extracted from CTC and tumor using the Tri-Reagent (Molecular Research Center, Cincinatti, OH). DNA will be extracted from tumor, CTC and mononucleated cells and tested for somatic lung mutations by sequencing (2). Germline DNA will be analysed for genes linked to genetic risk for NSCLC and, for treatment toxicities, for genes related to NSCLC chemotherapy metabolic pathways. Tissue microarray (TMA) is a high-throughput method of analysing large numbers of formalin-fixed, paraffin-embedded tumor at a minimal cost and effort. To analyse the expression of proteins of putative relevance to EGFR function, cell proliferation, angiogenesis, apoptosis, metastasis, and hormonal, TMA will be utilised. PTEN and C/EBPa will also be analysed.
RATIONALE: Diagnostic procedures, such as positron emission tomography and computed tomography, may help learn the extent of disease and allow doctors to plan 3-dimensional conformal radiation therapy. PURPOSE: This phase II trial is studying the side effects of positron emission tomography and computed tomography and to see how well it works in planning treatment for patients undergoing 3-dimensional conformal radiation therapy for non-small cell lung cancer that cannot be removed by surgery. This is a clinical study, as the patient will be treated using the PET-CT-GTV: - The pilot study is investigating the technological feasibility - The Phase II study will be a 2-stage Phase II study
The subjects are being asked to take part in the Phase I or Phase II portion of a research study of a new investigational drug, LBH589, in combination with chemotherapeutic agents, carboplatin with etoposide. LBH589 (made by Novartis Pharmaceuticals Corp.) is considered "investigational" because it has not been approved for commercial use in the treatment of cancer by the U.S. Food and Drug Administration (FDA). Etoposide and carboplatin are chemotherapeutic agents approved by the FDA for the treatment of for small cell lung cancer. LBH589 is a drug that may slow down the growth of cancer cells or kill cancer cells by blocking certain enzymes (proteins produced by cells). LBH589 has shown effects against cancer in laboratory studies and in studies using animals; however, it is not known if this medicine will show the same activity in humans. As of May 2006, approximately 100 patients have received treatment with either an intravenous or capsule form of LBH589. Only the capsule form of LBH589 will be used in this study. The main goal during the Phase I portion of this research study is to find out the highest and safest dose of LBH589 that can be given in combination with carboplatin with etoposide in subjects with lung cancer without causing severe side effects. The main goal of the Phase II portion of this study is to find how the subject's lung cancer responds to the LBH589 in combination with carboplatin and etoposide at the highest and safest dose that was given in Phase I. The subject may be enrolled in either Phase I or Phase II of the trial, depending on when they entered the study, but they will not be enrolled in both phases. This study will also investigate how the subject's body processes the combination of LBH589 and carboplatin with etoposide. To determine this, the investigators will measure the amount of study drug in the subject's blood. This will be done with a series of blood tests, called pharmacokinetic (PK) tests. Pharmacokinetics is the study of how the study drug moves through the body. Other purposes of this study will be to sample the subject's genetic material (DNA/RNA) as well as to determine biomarkers in their blood. (For some cancers, biomarkers are a way to measure the extent of their disease or the effects of treatment.) These samples will also be stored for future studies.