51 Clinical Trials for Various Conditions
This phase II trial tests how well gemcitabine, cisplatin and nab-paclitaxel given before surgery (neoadjuvant) works in treating patients with pancreatic cancer that can be removed by surgery (resectable) or that is borderline resectable. The standard treatment for resectable and borderline resectable pancreatic cancer is a combination of surgery and chemotherapy. Neoadjuvant therapy has been shown to improve overall survival compared to patients receiving surgery first. Gemcitabine is a chemotherapy drug that blocks the cells from making DNA and may kill tumor cells. Cisplatin is in a class of medications known as platinum-containing compounds. It works by killing, stopping or slowing the growth of tumor cells. Nab-paclitaxel is an albumin-stabilized nanoparticle formulation of paclitaxel, an antimicrotubule agent that stops tumor cells from growing and dividing and may kill them. Nab-paclitaxel may have fewer side effects and work better than other forms of paclitaxel. Gemcitabine, cisplatin and nab-paclitaxel may be an effective neoadjuvant treatment option for patients with resectable or borderline resectable pancreatic cancer.
The goal of this study is to test whether chemotherapy guided by a new imaging method named DCE-MRI can more effectively reduce a pancreatic tumor, enabling curable surgery, over the conventional method when a tumor is categorized as borderline resectable pancreatic cancer. UAB radiological research team has been studying a cutting-edge imaging technique named dynamic contrast-enhanced magnetic resonance imaging, or DCE-MRI, for over 10 years. This technique has been globally used to calculate the blood flow of various tissues, including tumors. Blood flow often serves as a critical indicator showing a disease status. For example, a pancreatic tumor typically has low blood flow, so it can be used as an indicator to identify the presence of a pancreatic tumor. In addition, an effective therapy can result in the increase of blood flow in a pancreatic tumor during the early period of treatment. Therefore, the investigators may be able to determine whether the undergoing therapy is effective or not by measuring the change of blood flow in the pancreatic tumor and deciding whether to continue the therapy or try a different one.
This trial is a single-arm, prospective, multi-center clinical trial designed to demonstrate that stereotactic adaptive radiotherapy using an ablatively dosed (50Gy,5fx) for treatment of borderline-resectable, locally-advanced , or medically inoperable pancreatic adenocarcinoma will translate into a decreased toxicity. The study will evaluate GI toxicity, overall survival, local control, quality of life, and workflow metrics.
The purpose of this study is to collect information about treatment recommendations based on ctDNA testing and whether treatment changes based on ctDNA information result in better outcomes for patients with pancreatic cancer.
To find the recommended dose of NBTXR3 that can be given in combination with radiation therapy to patients with pancreatic cancer. To learn if the dose NBTXR3 found in Part 1 can help to control the disease.
The purpose of this study is to research the effects of delivering full-dose neoadjuvant multi-agent chemotherapy (folfirinox) followed by stereotactic body radiation therapy (SBRT) in patients with resectable pancreatic ductal adenocarcinoma (PDAC) in order to intensify local therapy and improve outcomes.
This pilot and feasibility study studies how well nivolumab and combination chemotherapy work before surgery in treating patients with pancreatic cancer that could possibly be removed by surgery. Immunotherapy with monoclonal antibodies, such as nivolumab, may help the body?s immune system attack the cancer, and may interfere with the ability of tumor cells to grow and spread. Drugs used in chemotherapy, such as fluorouracil, irinotecan hydrochloride, leucovorin calcium and oxaliplatin, work in different ways to stop the growth of tumor cells, either by killing the cells, by stopping them from dividing, or by stopping them from spreading. Giving nivolumab in combination with chemotherapy before surgery may work better in treating patients with pancreatic cancer compared to chemotherapy alone.
Using alternative neoadjuvant gemcitabine-nab-paclitaxel and nal-IRI with 5-Fluorouracil (5FU) and folinic acid (Leucovorin) regimens of localized cancer, we hope to ensure exposure of the cancer to a broader array of potentially active agents. Also, potentially improves patient tolerance and minimizes significant drug toxicity that could impair delivery of all treatment elements. Furthermore, it may enable prediction of superior to inferior treatment outcomes at an earlier point in the disease progress.
The purpose of this study is to evaluate the safety and clinical activity of FOLFIRINOX along with a whole cell vaccine with immune modulating doses of cyclophosphamide and nivolumab combined with Stereotactic Body Radiation Therapy (SBRT) in patients with pancreatic cancer.
Initial study to evaluate local control and the preferred method of attachment of the CivaSheet in the setting of suspected close or positive margins at the time of surgical tumor removal.
Unfortunately, despite the best clinical efforts and breakthroughs in biotechnology, most patients diagnosed with pancreatic cancer continue to die from the rapid progression of their disease. One primary reason for this is that the disease is typically without symptoms until significant local and/or distant spread has occurred and is often beyond the chance for cure at the time of the diagnosis. The lack of any treatment to substantially increase long term survival rates is reflected by the poor outcomes associated with this disease, specifically time to disease progression and overall survival. However, another important part of the body is now being looked at as a target for therapy against this disease - the immune system. Scientists have clearly shown that pancreatic tumor cells produce a number of defective proteins, or express normal proteins in highly uncharacteristic ways, as part of this cancer. In some cancers, these abnormalities can cause an immune response to the cancer cells much in the way one responds to infected tissue. In progressive cancers however, the immune system fails to effectively identify or respond to these abnormalities and the cancer cells are not attacked or destroyed for reasons not yet fully understood. This clinical trial proposes a new way to stimulate the immune system to recognize pancreatic cancer cells and to stimulate an immune response that destroys or blocks the growth of the cancer. This new method of treatment helps the immune system of pancreatic cancer patients to "identify" the cancerous tissue so that it can be eliminated from the body. As an example, patients with certain diseases may require an organ transplant to replace a damaged kidney or heart. After receiving their transplant, these patients receive special drugs because they are at great danger of having an immune response that destroys or "rejects" the transplanted organ. This "rejection" occurs when their immune system responds to differences between the cells of the transplanted organ and their own immune system by attacking the foreign tissue in the same way as it would attack infected tissue. When the differences between foreign tissues and the patient's body are even larger, as with the differences between organs from different species, the rejection is very rapid, highly destructive, and the immunity it generates is longlasting. This is called hyperacute rejection and the medicine used to immunize patients in this protocol tries to harness this response to teach a patient's immune system to fight their pancreatic cancer just as the body would learn to reject a transplanted organ from an animal. To do this, Algenpantucel-L immunotherapy contains human pancreatic cancer cells that contain a mouse gene that marks the cancer cells as foreign to patient's immune systems. The immune system therefore attacks these cancer cells just as they would attack any truly foreign tissue, destroying as much as it can. Additionally, the immune system is stimulated to identify differences (aside from the mouse gene) between these cancer cells and normal human tissue as foreign. This "education" of the immune system helps treat the patient because pancreatic cancer cells already present in a treated patient are believed to show some of the same differences from normal tissue as the modified pancreatic cancer cells in the product. Due to these similarities, the immune system, once "educated" by the Algenpantucel-L immunotherapy, identifies the patient's cancer as foreign and attacks. Historically, external beam radiation has been part of the treatment of pancreatic cancer, both before and after surgical resection. Recent breakthroughs in technology now allow for more intensive doses of radiation to be delivered to the body with greater precision. These newer, more precise radiation treatments, called stereotactic body radiation, deliver more intensive radiation to a locally advanced tumor and are now being employed in the treatment of pancreatic cancer. Stereotactic body radiation may increase the chances that surgery will successfully remove a pancreatic cancer. In this experimental study, all patients will be given a strong combination of antitumor chemotherapy while receiving injections of an immunotherapy drug consisting of two types of pancreatic cancer cells that have been modified to make them more easily recognized and attacked by the immune system. The investigators propose to test this new treatment paradigm along with stereotactic body radiation in patients with borderline resectable pancreatic cancer to demonstrate that treatment with this combination of therapies increases the time until the tumor progresses as well as overall survival.
The purpose of this clinical trial is to study an experimental drug called pembrolizumab or MK-3475 for use in combination with chemotherapy and radiation therapy for patients with resectable (surgical removal) or borderline resectable pancreatic cancer. In general, pancreatic cancer that cannot be removed by surgery is sometimes treated with chemotherapy and radiation therapy, called neoadjuvant treatment, to shrink the tumor so that surgery might be possible. However, this is not always effective at shrinking the tumor enough to allow it to be removed with surgery. Recent discoveries suggest that the investigators own immune system might have a role in controlling the growth of tumors. Drugs such as pembrolizumab can stimulate the immune system against cancer. The purpose of this study is to investigate whether pembrolizumab can be used safely during neoadjuvant treatment and can improve the body's immune response against pancreatic cancer. Pembrolizumab has been approved for treatment of patients with melanoma but has not been proven to be safe or helpful in patients with pancreatic cancer and is not approved by the U.S. Food and Drug Administration (FDA) for this purpose.
To evaluate the safety and effectiveness of a novel neoadjuvant treatment strategy incorporating 5-fluorouracil/leucovorin with oxaliplatin ( FOLFOX )chemotherapy in combination with chemo-radiation with gemcitabine.
This is a prospective, randomized phase II trial. Patients diagnosed with borderline resectable pancreatic adenocarcinoma will be randomly assigned to one of two treatment arms, either mFOLFIRINOX or gemcitabine and nab-paclitaxel. After three cycles of treatment in the gemcitabine/nab-paclitaxel arm and 6 cycles in the mFOLFIRINOX arm, patients will be restaged with CT scans and if they remain borderline resectable or have improvement of their disease They will then proceed to SBRT followed by surgical resection.
The investigators hypothesize that intensification of local therapy will lead to improvements in local control and survival in patients with unresectable and borderline resectable pancreatic cancer. We propose to do this by combining nab-paclitaxel concurrently with dose-escalated radiation therapy. In the first part of this phase I study (sub-trial 1), the nab-paclitaxel dose will be escalated while the radiation dose is held constant at a standardly accepted level. The use of this novel chemoradiotherapy regimen will take advantage of nab-paclitaxel's specific anti-tumor and anti-stromal properties, which may enhance the efficacy of radiation therapy, and thereby improve local control. After the MTD of nab-paclitaxel had been determined, a second arm in sub-trial 1 will evaluate the addition of paricalcitol to nab-paclitaxel concurrently with dose-escalated radiation therapy. In addition, after the MTD of the nab-paclitaxel is reached in sub-trial 1 arm A, in the second part of this study (sub-trial 2), we will administer nab-paclitaxel at the determined MTD concurrently with escalated doses of radiation. We will utilize IMRT or protons to safely deliver high doses of radiation while maximally sparing surrounding normal tissue. Patients will also preferentially have 2-3 fiducial markers placed in or around the tumor for daily localization. Chemotherapy before and/or after chemoradiotherapy may be given as per standard of care. Correlative tissue and serum biomarkers are an important, but optional, part of this study.
This phase II trial studies how well combination chemotherapy, gemcitabine hydrochloride, and radiation therapy before surgery works in treating patients with pancreatic cancer that has not spread to other places in the body and can be removed by surgery. Drugs used in chemotherapy, such as fluorouracil, leucovorin calcium, irinotecan hydrochloride, oxaliplatin, and gemcitabine hydrochloride, work in different ways to stop the growth of cancer cells, either by killing the cells or by stopping them from dividing. Fluorouracil, irinotecan hydrochloride, and gemcitabine hydrochloride may also stop the growth of tumor cells by blocking some of the enzymes needed for cell growth. Giving combination chemotherapy and gemcitabine hydrochloride with radiation therapy before surgery may make the tumor smaller and reduce the amount of normal tissue that needs to be removed.
The purpose of this study is to find out if a program of intensive chemotherapy with gemcitabine, docetaxel and capecitabine followed by an advanced form of focused radiation aimed at participant's tumor followed by more chemotherapy can increase the chances that the participant's pancreatic tumor can be removed completely.
This single arm, multi-center phase II clinical trial will assess the safety and efficacy of FOLFIRINOX in the first-line setting in patients with unresectable locally advanced (ULA) and borderline resectable (BR) pancreatic cancer.
The purpose of this study is to determine safety and to obtain preliminary estimates of the rate of major pathologic response of neoadjuvant accelerated fraction, standard dose radiation given with chemotherapy in patients with locally advanced pancreas cancer.
This study is being conducted to find out what effects (good and bad) that a combination of treatment with chemotherapy, radiation therapy and surgery has on you and your pancreatic cancer. The chemotherapy drugs to be used: Gemcitabine, Docetaxel, Oxaliplatin, 5-FU and alpha-interferon. The goal is to decrease the size of the tumor, so that removal by surgery can be performed. Current treatments for this stage of pancreas cancer offer less than ideal results, with little opportunity for treatment with curative intent.
GTI-4711-201 is designed as a Phase 2b, multicenter, randomized, double-blind, placebo-controlled study to determine the effect to OS by adding GC4711 to SBRT following chemotherapy in patients with unresectable or borderline resectable nonmetastatic
Background: Fewer than 10 percent of people with pancreas cancer can have surgery. Surgery gives the best outcome. Radiation therapy is usually used to make surgery possible. But it does not work for most people. Adding immunotherapy might help. Objective: To find a safe combined dose of Bintrafusp Alfa (M7824), NHS-IL12 (M9241, and radiation and to see if it causes pancreas cancer tumors to shrink. Eligibility: People ages 18 and older who have pancreas cancer and cannot have curative surgery Design: Participants will be screened under protocol 01-C-0129 with: Medical history Physical exam Heart, urine, and blood tests Scans. For this, participants will lie in a machine that takes pictures of the body. They may receive a contrast agent by vein. Possible tumor biopsy Participants will take the study drugs either alone or with radiation. They will get M7824 by vein every 2 weeks. They will get M9241 injected under the skin every 4 weeks. Participants who get radiation will get it 5 days in a row the first month. Participants will have visits every 2 weeks. They will repeat screening tests. If participants tumors shrink, they will have surgery. If their whole tumor is removed, they will stop treatment. They will otherwise continue treatment as long as they can tolerate it and it is helping them. Participants will have visits 1 week and 1 month after they stop treatment. Then they will be contacted by phone or email for life. If they stop treatment for a reason other than their disease getting worse, they will have scans every 12 weeks.
The investigators hypothesize that the combination of the FOLFIRINOX regimen (a combination of 5-fluorouracil, irinotecan and oxaliplatin chemotherapy) to provide maximal systemic disease control and FDR-gemcitabine chemotherapy with concurrent IMRT (Radiation therapy) to address local disease, will achieve a significant improvement R0 resection (Radiation oncology repeat surgeries) rate in borderline resectable (surgical) pancreatic cancer and enhance disease free and overall survival in this patient population.
The purpose of this study is to find out if a program of intensive chemotherapy with gemcitabine, docetaxel and capecitabine followed by an advanced form of focused radiation aimed at the patient's tumor followed by more chemotherapy can increase the chances that the patient's pancreatic tumor can be removed completely.
This phase II trial studies the effects of gemcitabine, nab-paclitaxel, durvalumab, and oleclumab in treating patients with primary pancreatic cancer that may be able to be removed by surgery (resectable/borderline resectable). Chemotherapy drugs, such as gemcitabine and nab-paclitaxel, work in different ways to stop the growth of tumor cells, either by killing the cells, by stopping them from dividing, or by stopping them from spreading. Immunotherapy with monoclonal antibodies, such as durvalumab and oleclumab, may help the body's immune system attack the cancer, and may interfere with the ability of tumor cells to grow and spread. Giving gemcitabine, nab-paclitaxel, durvalumab, and oleclumab may help control the disease in patients with resectable/borderline resectable primary pancreatic cancer.
This is a phase II study using the Bayesian platform design. There are three clinical stage groups of localized pancreatic cancer: resectable, borderline resectable, and locally advanced disease. Each stage group will have a defined standard of care chemotherapy regimen for a control arm, serving as a basis of comparison. Each group may have one or more experimental arms. Experimental arms may be added to the platform over time, and the effects of the experimental treatments will be tested against the controls for each group.
This pilot clinical trial studies stereotactic radiosurgery and metformin hydrochloride in treating patients with pancreatic cancer that may be removed (borderline-resectable) or not removed by surgery. Stereotactic radiosurgery may be able to send x-rays directly to the tumor and cause less damage to normal tissue. Metformin hydrochloride, used for diabetes, may also kill cancer cells as demonstrated in laboratory studies. Giving stereotactic radiosurgery with metformin hydrochloride may kill more tumor cells.
This phase II trial evaluates whether early switching from modified fluorouracil/irinotecan/leucovorin/oxaliplatin (mFOLFIRINOX) chemotherapy regimen to a combination of gemcitabine and nab-paclitaxel (GA) before surgery is effective in treating patients with pancreatic cancer that can be surgically removed (resectable or borderline resectable), or that has spread to nearby tissue or lymph nodes and cannot be removed by surgery (locally-advanced unresectable). Chemotherapy drugs, such as fluorouracil, irinotecan, leucovorin, oxaliplatin, gemcitabine, and nab-paclitaxel work in different ways to stop the growth of tumor cells, either by killing the cells, by stopping them from dividing, or by stopping them from spreading. The study will also evaluate the drug losartan in combination with mFOLFIRINOX or GA.
This phase I trial studies the side effects of losartan and hypofractionated radiation therapy after chemotherapy in treating patients with pancreatic cancer that may or may not be removed by surgery (borderline resectable) or has spread from its original site of growth to nearby tissues or lymph nodes and is not amenable to surgical resection (locally advanced unresectable). Losartan may improve blood flow and allows for better tissue oxygenation. Hypofractionated radiation therapy delivers higher doses of radiation therapy over a shorter period of time and may kill more tumor cells and have fewer side effects. Giving losartan and hypofractionated radiation therapy may work better in treating patients with pancreatic cancer compared to hypofractionated radiation therapy alone.
Unfortunately, despite the best clinical efforts and breakthroughs in biotechnology, most patients diagnosed with pancreatic cancer continue to die from the rapid progression of their disease. One primary reason for this is that the disease is typically without symptoms until significant local and/or distant spread has occurred and is often beyond the chance for cure at the time of the diagnosis. The lack of any treatment to substantially increase long term survival rates is reflected by the poor outcomes associated with this disease, specifically time to disease progression and overall survival. However, another important part of the body is now being looked at as a target for therapy against this disease - the immune system. Scientists have clearly shown that pancreatic tumor cells produce a number of defective proteins, or express normal proteins in highly uncharacteristic ways, as part of this cancer. In some cancers, these abnormalities can cause an immune response to the cancer cells much in the way one responds to infected tissue. In progressive cancers however, the immune system fails to effectively identify or respond to these abnormalities and the cancer cells are not attacked or destroyed for reasons not yet fully understood. This clinical trial proposes a new way to stimulate the immune system to recognize pancreatic cancer cells and to stimulate an immune response that destroys or blocks the growth of the cancer. This new method of treatment helps the immune system of pancreatic cancer patients to "identify" the cancerous tissue so that it can be eliminated from the body. As an example, most people are aware that patients with certain diseases may require an organ transplant to replace a damaged kidney or heart. After receiving their transplant, these patients receive special drugs because they are at great danger of having an immune response that destroys or "rejects" the transplanted organ. This "rejection" occurs when their immune system responds to differences between the cells of the transplanted organ and their own immune system by attacking the foreign tissue in the same way as it would attack infected tissue. When the differences between foreign tissues and the patient's body are even larger, as with the differences between organs from different species, the rejection is very rapid, highly destructive, and the immunity it generates is longlasting. This is called hyperacute rejection and the medicine used to immunize patients in this protocol tries to harness this response to teach a patient's immune system to fight their pancreatic cancer just as the body would learn to reject a transplanted organ from an animal. To do this, Algenpantucel-L immunotherapy contains human pancreatic cancer cells that contain a mouse gene that marks the cancer cells as foreign to patient's immune systems. The immune system therefore attacks these cancer cells just as they would attack any truly foreign tissue, destroying as much as it can. Additionally, the immune system is stimulated to identify differences (aside from the mouse gene) between these cancer cells and normal human tissue as foreign. This "education" of the immune system helps treat the patient because pancreatic cancer cells already present in a treated patient are believed to show some of the same differences from normal tissue as the modified pancreatic cancer cells in the product. Due to these similarities, the immune system, once "educated" by the Algenpantucel-L immunotherapy, identifies the patient's cancer as foreign and attacks. The chemotherapy combination to be used in this study has been shown to improve survival in advanced pancreatic cancer and is being combined with an experimental pancreatic cancer immunotherapy that stimulates the immune system to recognize and attack the cancer. One goal of this study is to determine whether chemotherapy and immunotherapies can work cooperatively to increase anti-tumor effects to levels beyond what would be seen with either treatment alone. In this experimental study, all patients are given a strong combination of anti-tumor chemotherapies while some patients are also given injections of an immunotherapy drug consisting of two types of pancreatic cancer cells that we have modified to make them more easily recognized and attacked by the immune system. We propose to test this new treatment protocol in patients with locally advanced pancreatic cancer to demonstrate that treatment with the immunotherapy increases the time until the tumor progresses or increases overall survival when given in combination with the current standard of care therapy for this disease.