Project description:Background: Combinations of Dendritic and Cytokine-induced Killer Cells (DC-CIK) and Cytokine-induced Killer Cells (CIK) treatment may enhance the immune response and stop cancer cells from growing. The investigators suppose that DC-CIK combined with CIK treatment will improve the prognosis of advanced solid tumors.
Objective: Phase II clinical trial to investigate the efficacy of concurrent chemotherapy with DC-CIK and CIK treatment in patients with treatment-refractory solid tumors.
Study treatment:
Patients in group A will receive 4 cycles of CIK treatments and 4 cycles of DC-CIK treatments within 8 months. Patients in group B will have no immunotherapy . chemotherapy are available in both groups.
Project description:The purpose of this study is to evaluate the efficacy of dendritic and cytokine-induced killer cells (DC-CIK) for colorectal cancer (CRC).
Project description:The purpose of this study is to evaluate the efficacy of autologous tumor lysate-pulsed dendritic and cytokine-induced killer cells (DC-CIK) for colorectal cancer (CRC).
Project description:Cytokine-induced killer cells (CIK) is an auxiliary antitumor treatment. The investigators aim to evaluate the clinical efficacy of chemotherapy combined with CIK in the treatment of postoperative colorectal cancer patients. And to provide useful reference for the clinical application of CIK in colorectal cancer patients.
Project description:The purpose of this study is to determine whether combining of radiofrequency ablation (RFA) and cytokine-induced killer cells (CIK) transfusion can prolong survival of patients with colorectal cancer liver metastases (CRCLM).
Project description:CD3+/CD56+ Natural killer (NK) cell-like T-cells (NKT-like cells) represent <5% of blood lymphocytes, display a cytotoxic phenotype, and can kill various cancers. NKT-like cells can be expanded ex vivo into cytokine-induced killer (CIK) cells, however this therapeutic cell product has had mixed results against hematological malignancies in clinical trials. The aim of this study was to determine if NKT-like cells mobilized during acute cycling exercise could be used to generate more potent anti-tumor CIK cells from healthy donors. An acute exercise bout increased NKT-like cell numbers in blood 2-fold. Single cell RNA sequencing revealed that exercise mobilized NKT-like cells have an upregulation of genes and transcriptomic programs associated with enhanced anti-tumor activity, including cytotoxicity, cytokine responsiveness, and migration. Exercise, however, did not augment the ex vivo expansion of CIK cells or alter their surface phenotypes after 21-days of culture. CIK cells expanded at rest, during exercise (at 60% and 80% VO2max) or after (1h post) were equally capable of killing leukemia, lymphoma, and multiple myeloma target cells with and without cytokine (IL-2) and antibody (OKT3) priming in vitro. We conclude that acute exercise in healthy donors mobilizes NKT-like cells with an upregulation of transcriptomic programs involved in anti-tumor activity, but does not augment the ex vivo expansion of CIK cells.
Project description:Dr. Christopher Contag lab's aim is to, investigate the molecular interactions that underlie CIK cell homing from the bloodstream to tumor tissue using a combination of gene expression profiling, flow cytometry, and in vivo molecular imaging. Collectively, these proposed experiments will define the repertoire of molecules employed in CIK cell recognition of the tumor vasculature and guide the development of improved CIK cell therapies for use in cancer patients. A promising new direction in cancer therapy is the use of cytokine-induced killer (CIK) cells as broadly active tumoricidal agents. CIK cells derive from blood samples stimulated ex vivo, and these activated immune cells are capable of recognizing and destroying a plethora of tumor targets in vivo. In fact, CIK cells have demonstrated efficacy in clinical trials to treat patients with hepatoma, renal cell cancer, and hematological malignancies. Despite the remarkable clinical promise of this therapy, little is known about the mechanisms that govern CIK cell migration to tumor tissue in vivo. Understanding the trafficking patterns of these potent immune cells is of critical importance to advancing their use in humans. I aim to investigate the molecular interactions that underlie CIK cell homing from the bloodstream to tumor tissue using a combination of gene expression profiling, flow cytometry, and in vivo molecular imaging. Collectively, these proposed experiments will define the repertoire of molecules employed in CIK cell recognition of the tumor vasculature and guide the development of improved CIK cell therapies for use in cancer patients. RNA from three groups (1,2,3) were sent to Microarray Core E. Group one samples: Splenocytes were obtained from BALB/c mice, and the T cells were isolated using a negative isolation kit (magnetic bead separation). For group 2 and 3 samples: The isolated splenocytes were treated with IFN-gamma overnight. The cells were then added to anti-CD3 coated flasks and stimulated with IL-2. Fresh IL-2 was added to the media every 3 days, and the cells were harvested 12 days post-isolation. The RNA was labeled and hybridized to Glyco_v3 arrays.
Project description:Dr. Christopher Contag lab's aim is to, investigate the molecular interactions that underlie CIK cell homing from the bloodstream to tumor tissue using a combination of gene expression profiling, flow cytometry, and in vivo molecular imaging. Collectively, these proposed experiments will define the repertoire of molecules employed in CIK cell recognition of the tumor vasculature and guide the development of improved CIK cell therapies for use in cancer patients. A promising new direction in cancer therapy is the use of cytokine-induced killer (CIK) cells as broadly active tumoricidal agents. CIK cells derive from blood samples stimulated ex vivo, and these activated immune cells are capable of recognizing and destroying a plethora of tumor targets in vivo. In fact, CIK cells have demonstrated efficacy in clinical trials to treat patients with hepatoma, renal cell cancer, and hematological malignancies. Despite the remarkable clinical promise of this therapy, little is known about the mechanisms that govern CIK cell migration to tumor tissue in vivo. Understanding the trafficking patterns of these potent immune cells is of critical importance to advancing their use in humans. I aim to investigate the molecular interactions that underlie CIK cell homing from the bloodstream to tumor tissue using a combination of gene expression profiling, flow cytometry, and in vivo molecular imaging. Collectively, these proposed experiments will define the repertoire of molecules employed in CIK cell recognition of the tumor vasculature and guide the development of improved CIK cell therapies for use in cancer patients.