View clinical trials related to Pancreatic Adenocarcinoma.
Filter by:A unique approach for cancer treatment employing intratumoral diffusing alpha radiation emitter device for advanced pancreatic cancer
This is a single arm phase II study. All patients will receive 3 cycles of the treatment of nab-paclitaxel (Days 1, 8 and 15), gemcitabine (Days 1, 8 and 15), and TTFields (worn every day for at least 18 hours). Following the initial 3 cycles of gemcitabine/nab-paclitaxel/TTFields treatment, patients will undergo restaging by CT or MRI. Patients with stable disease or better will undergo surgery for resection within 8 weeks following completion of initial chemotherapy although enrolling sites are encouraged to perform resection within 4 weeks of Cycle 3 D15 of therapy. If resection yields R0 or R1, patients will begin an additional 3 cycles of gemcitabine/nab-paclitaxel/TTFields treatment within 8 weeks of surgery. Based on available literature, it is expected that a percentage of patients will not undergo resection either due to disease progression or due to toxicities/ complications of the neoadjuvant segment of therapy. These patients will be included in the evaluable patients for both co-primary endpoints as well as the secondary endpoints including ORR, adverse events, and OS.
This is a Phase 1/2, open-label, multi-center, first-in-human, dose escalation and cohort expansion study evaluating multiple doses and schedules of subcutaneously administered JK08 in patients with unresectable locally, advanced or metastatic cancer.
This is an open-label, dose-exploration and expansion study to determine the safety, tolerability, pharmacokinetics, pharmacodynamics, and preliminary anti-tumor activity of IMM-1-104 when administered as monotherapy or in combination with approved agents in participants with RAS-mutated or RAS/MAPK activated advanced or metastatic solid tumors. The dose exploration will identify the candidate recommended Phase 2 dose (RP2D) of IMM-1-104 to further explore the anti-tumor activity of IMM-1-104 as monotherapy and in combination with approved agents in multiple Phase 2a proof-of-concept cohorts in malignancies of interest.
To explore the possibility to overcome CYP3A-mediated resistance to anticancer drugs in pancreatic cancer, we will investigate the pharmacokinetics, safety, tolerability, and efficacy of nanoparticle albumin-bound paclitaxel (nab-paclitaxel) in combination with gemcitabine and the CYP3A inhibitor cobicistat in a phase I proof-of-concept trial to determine the safety profile, the recommended dose of nab-paclitaxel in combination with gemcitabine and cobicistat, and to determine whether there is an early efficacy signal warranting a larger scale trial. The present trial is an open-label trial consisting of a dose-escalation part and an expansion part. The dose escalation part is designed to determine the safety, tolerability, and pharmacokinetics of nab-paclitaxel in combination with gemcitabine and cobicistat and will guide the dosing in the expansion part of the trial. The trial enrolls patients with unresectable locally advanced or metastatic pancreatic adenocarcinoma and adequate performance score (ECOG PS 0-2) who would usually receive gemcitabine and nab-paclitaxel according to standard of care. Primary endpoint for the phase I trial is the safety of the combination. Overall survival (OS), disease control rate (DCR), overall response rate (ORR), duration of response (DoR) and progression free survival (PFS) are secondary efficacy endpoints. Further secondary endpoints are tolerability, pharmacokinetics, pharmacodynamics, and pharmacogenomics.
This study is a non-randomized, open-label, multi-cohort, multi-site, pilot feasibility therapeutic trial. The study will enroll 20 patients across 4 cohorts (CRC, gastric, PDAC, and HCC/intra-hepatic-/extra-hepatic-, gall bladder adenocarcinomas) diagnosed with histologically confirmed GI cancers. These patients will have already completed all Standard of Care (SOC) treatments (including neoadjuvant, surgery, local therapies, and/or adjuvant therapy as applicable), as defined by the treating primary physician or research team, with curative intent but have a positive SignateraTM tumor-informed ctDNA test and NED radiographically by standard imaging within 28 days prior to enrollment and within 1 year of completing all curative-intent therapy. All patients will be treated with intravenous (IV) atezolizumab 1200 mg IV and bevacizumab 15 mg/kg on Day 1 of 21-day cycles until disease recurrence, ctDNA POD, unacceptable toxicity, or subject withdrawal of consent with a maximum 12 month total duration of study therapy. Atezolizumab and bevacizumab drug will be provided.
Pancreatic cancer (PC) is a deadly disease and surgical resection of the tumor is the only hope of cure. Approximately 20-25% of the PC patients are candidates for intended curative resection, but despite microscopically radical resection the majority of patients will have recurrent disease within 2 years. This indicates that most patients will harbour non-detected (i.e. occult) cancer cells at the time of resection. Studies suggest that free tumor cells in the peritoneum and in the blood are part of this occult disease burden, and that patients with such findings should not be operated but treated as having metastatic disease. However, the exact incidence of these tumor cells in an unselected cohort of patients undergoing pancreatic resection is unknown, and the potential impact on postoperative survival is also uncertain. In recent years, molecular biomarkers are increasingly being regarded as both predictive and prognostic tools for cancer patients. This study will use the most optimal available methods to investigate the incidence of biomarkers for tumor cells in the peritoneum and blood in PC patients, and to relate these findings to the final outcome of the resected patients. This project has become highly relevant since new treatment methods (i.e. Pressurized IntraPeritoneal Aerosol Chemotherapy (PIPAC)) may be used to eradicate free tumor cells. A recent systematic review and meta-analysis demonstrated that PC patients with positive peritoneal cytology (Cy+) had a significant poorer survival than patients with negative peritoneal cytology (Cy-) (HR 3.18), and the authors concluded that Cy+ patients should not undergo surgery. This conclusion was supported by a significant lower overall survival and a higher peritoneal recurrence rate after resection of Cy+ patients when compared to Cy- patients. Agreement that Cy+ in resectable PDAC is a negative predictor of prognosis came from another recent meta-analysis and systematic review. However, this study also indicated that the median OS was worse in patients without than in those with resection among patients with Cy+, thereby emphasizing need of further careful assessment of indications for radical resection in Cy+ patients. KRAS mutations have been detected in circulating tumor DNA (ctDNA) in the blood (liquid biopsies) from patients with metastatic PC, and ctDNA is considered a marker of poor prognosis. Similar, KRAS mutations were found in the plasma of one-third of patients with a resectable tumor, and ctDNA positive (ctDNA+) patients had a significantly poorer overall survival (13.6 months vs 27.6 months, p<0.0001). Similar conclusions were drawn in recent systematic reviews and meta-analyses, while one study failed to confirm these results. The detection of KRAS mutations in cell-free DNA has also been identified as a prognostic biomarker in PC patients. If looking at studies including all stages of PC patients, the prevalence of KRAS mutations in liquid biopsies was 40.8%, and these mutations had a negative impact on overall survival with a HR of 3.16. Different ctDNA detection methods have been used, however the recent introduction of digital droplet PCR (ddPCR), a new robust PCR method for quantifying low-abundance point mutations in cell-free circulating DNA, shows promising results and offers increased sensitivity and reproducibility relative to quantitative PCR (qPCR). The treatment of resectable, locally advanced and metastatic PC has changed significantly over the past few years. New chemotherapy regimens have improved survival in metastatic PC, and these regimens (+/- radiation therapy) are presently being tested in both resectable and locally advanced PC with promising preliminary results. In theory, these new regimens may be potentially effective against ctDNA in PC patients, whereas the effect on peritoneal lavage positive (PLF+) PC patients is more speculative due to the low intraperitoneal concentrations of systemic chemotherapy. However, the latter problem may be solved by using Pressurized IntraPeritoneal Aerosol Chemotherapy (PIPAC) which allows better intraperitoneal distribution, concentration and accumulation of chemotherapy, without the systemic side effects. It may be speculated that the highly sensitive ddPCR of KRAS may be a better tool for PLF+ detection when focusing on PC patients, as up to 95% of these harbour mutations in this gene. So far, only very few studies used PCR to evaluate KRAS mutations in PLF in PC patients. Main study aims are: 1. We aim to investigate the incidence of PLF+ and KRAS ctDNA in the blood from an unselected cohort of PC patients scheduled for attempted curative surgery. 2. Secondly, we will study the prognostic impact of PLF+ and KRAS ctDNA positivity in PC patients.
Claudin 18.2 protein, or CLDN18.2 is a protein found on cells in the digestive system. It is also found on some tumors. Researchers are looking at ways to attack CLDN18.2 to help control tumors. ASP2138 is thought to bind to 2 targets at the same time: CLDN18.2 and a protein called CD3 found on immune cells, called T-cells. ASP2138 works by binding to both the tumor cell and CD3 which "tells" the immune system to attack the tumor. ASP2138 is a potential new treatment for people with stomach cancer, gastroesophageal junction cancer, (cancer where the tube that carries food (esophagus) joins the stomach) or pancreatic cancer. Before ASP2138 is available as a treatment, the researchers need to understand how it is processed by and acts upon the body. This information will help to find a suitable dose and to check for potential medical problems from the treatment. Adults 18 years or older with stomach cancer, gastroesophageal junction cancer, or pancreatic cancer can take part. Their cancer is locally advanced unresectable or metastatic. Locally advanced means the cancer has spread to nearby tissue. Unresectable means the cancer cannot be removed by surgery. Metastatic means the cancer has spread to other parts of the body. The main aims of the study are to check the safety of ASP2138, how well it is tolerated, and to find a suitable dose of ASP2138 to be used later in this study. This is an open-label study. This means that people who take part in this study and clinic staff will know that people will receive ASP2138. The study will have 2 phases. In phase 1, different small groups of people will receive lower to higher doses of ASP2138. Any medical problems will be recorded at each dose. This is done to find suitable doses of ASP2138 to use later in the study. The first group will receive the lowest dose of ASP2138. A medical expert panel will check the results from this group and decide if the next group can receive a higher dose of ASP2138. The panel will do this for each group until all groups have received ASP2138, or until suitable doses have been selected for later in the study. Doctors will also check how each type of cancer is responding to ASP2138. In phase 1b, other different small groups will receive suitable doses of ASP2138 found from phase 1. Phase 1b will check how each type of cancer responds to ASP2138. The response to ASP2138 is measured using scans and blood tests. Doctors will continue to check for all medical problems throughout the study. ASP2138 will be given either through a vein in the arm (intravenous infusion) or just below the skin (subcutaneous injection). Treatment will be in cycles of either 7 or 14 days (1 or 2 weeks). In each treatment cycle, intravenous infusions or subcutaneous injections will either be given once a week or once every 2 weeks. People will continue to receive treatment until: their cancer gets worse; they have medical problems they can't tolerate; they ask to stop treatment; the doctors decide that continuing treatment is no longer in that person's best interest; the study is ended by the sponsor. Doctors will check if people had any medical problems from ASP2138. Other checks will include medical examinations, checking the nervous system, blood and urine tests and vital signs. Nervous system checks include checking peoples state of mind, reflexes, balance, movement and muscle strength. Vital signs include medical examinations, body temperature, breathing rate, and blood oxygen levels. Electrocardiograms (ECG) will be done to check the heart rhythm during the study. People will receive ASP2138 in a hospital. They will have blood tests and doctors will check for medical problems. People will also visit the clinic on certain days during their treatment, with extra visits during the first 3 cycles of treatment. People will visit the clinic after treatment has finished. The doctors will check for more medical problems. Other checks will include medical examinations, blood and urine tests, and vital signs. People will also have an ECG and may have CT or MRI scans. After this, people will visit the clinic for a check-up several times. The number of visits and checks done at each visit will depend on the health of each person and whether they completed their treatment or not.
Few chemotherapeutic options exist for pancreatic cancer. Moreover, objective criteria are lacking for deciding which regimen is more beneficial for patient presenting with metastases at diagnosis. This study investigates whether organoid generation from tumour samples of pancreatic cancer is a safe and feasible process for testing of multiple chemotherapy regimens in the laboratory. By participating to this study, patients will have a part of the tumour tissue retrieved and sent to the laboratory for organoid generation and drug testing. For surgically-resectable tumors, tumoral tissue samples will be collected from the main surgical specimens, before sending it for final pathological examination. In case of suspected metastatic lesion at diagnosis, curative surgery is not indicated. Therefore, we will offer patients to undergo port-a-cath implantation for chemotherapy delivery and concomitant laparoscopic surgical excisional biopsy of suspicious metastatic (either hepatic or peritoneal) lesions. At this stage of the study, the treatment that the patient will receive after surgery will not be affected by the results of the laboratory testing. In fact, all patients will receive the standard of care treatment based on the most recent oncologic guidelines and on the oncologist's clinical judgement. As part of the study, each patient will be followed for 30 days to assess possible surgical complications related to the surgical biopsy. This study will help to speed up the implementation of organoid generation in the clinical routine for the choice of the best treatment of patients affected by pancreatic cancer.
The effect of neoadjuvant chemotherapy for pancreatic cancer was gradually established. However it has been not clarified which regimen of neoadjuvant treatment for pancreatic cancer is the best.