Associação Brasileira de Hematologia, Hematologia, Hemoterapia e Terapia Celular Consensus on genetically modified cells. Review article: Cell therapy in solid tumors.

The use of immunotherapy in cancer treatment over the past decade has resulted in significant advances and improvements in cancer patients survival with the use of checkpoint inhibitors. Nevertheless, only a fraction of solid tumors responds to this immunotherapy modality. Another modality of immunotherapy consists of employing cell-based therapy as an adoptive therapeutic modality.

Engineered Tumor-Targeted T Cells Mediate Enhanced Anti-Tumor Efficacy Both Directly and through Activation of the Endogenous Immune System.

Chimeric antigen receptor (CAR) T cell therapy has proven clinically beneficial against B cell acute lymphoblastic leukemia and non-Hodgkin's lymphoma. However, suboptimal clinical outcomes have been associated with decreased expansion and persistence of adoptively transferred CAR T cells, antigen-negative relapses, and impairment by an immunosuppressive tumor microenvironment. Improvements in CAR T cell design are required to enhance clinical efficacy, as well as broaden the applicability of this technology.

Emerging Role of CAR T Cells in Non-Hodgkin's Lymphoma.

Adoptive T-cell therapy with chimeric antigen receptor T cells (CAR-Ts) has produced impressive clinical responses among patients with B-cell malignancies, and several groups have published positive results using anti-CD19 CAR-Ts for the treatment of B-cell acute lymphoblastic leukemia. Recently, new data from clinical trials have demonstrated the benefits of CAR-T therapy in the non-Hodgkin's lymphoma (NHL) setting. This review describes some of the most recent and promising advances in engineered T-cell therapy, with particular emphasis on the clinical benefits of NHL treatment.

A novel bioreactor and culture method drives high yields of platelets from stem cells.

Background: Platelet (PLT) transfusion is the primary treatment for thrombocytopenia. PLTs are obtained exclusively from volunteer donors, and the PLT product has only a 5-day shelf life, which can limit supply and result in PLT shortages. PLTs derived from stem cells could help to fill this clinical need.

Actin inhibition increases megakaryocyte proplatelet formation through an apoptosis-dependent mechanism.

Background: Megakaryocytes assemble and release platelets through the extension of proplatelet processes, which are cytoplasmic extensions that extrude from the megakaryocyte and form platelets at their tips. Proplatelet formation and platelet release are complex processes that require a combination of structural rearrangements. While the signals that trigger the initiation of proplatelet formation process are not completely understood, it has been shown that inhibition of cytoskeletal signaling in mature megakaryocytes induces proplatelet formation.

A novel inflammatory role for platelets in sickle cell disease.

The severe pain, ischemia and organ damage that characterizes sickle cell disease (SCD) is caused by vaso-occlusion, which is the blockage of blood vessels by heterotypic aggregates of sickled erythrocytes and other cells. Vaso-occlusion is also a vasculopathy involving endothelial cell dysfunction, leukocyte activation, platelet activation and chronic inflammation resulting in the multiple adhesive interactions between cellular elements. Since platelets mediate inflammation as well as thrombosis via release of pro- and anti-inflammatory molecules, we hypothesized that platelets may play an active inflammatory role in SCD by secreting increased amounts of cytokines.

Ex vivo production of platelets from stem cells.

Stem cell technology holds great promise for transfusion medicine, and generation of platelets from stem cells would be transformative. Platelet transfusions are life saving for millions of people and the clinical demand for platelets continues to increase: there is a real need to increase the supply of platelets. Accordingly, there is great interest in the potential of producing platelets from stem cells for clinical use.

Rho kinase inhibition drives megakaryocyte polyploidization and proplatelet formation through MYC and NFE2 downregulation.

The processes of megakaryocyte polyploidization and demarcation membrane system (DMS) formation are crucial for platelet production, but the mechanisms controlling these processes are not fully determined. Inhibition of Rho kinase (ROCK) signalling leads to increased polyploidization in umbilical cord blood-derived megakaryocytes. To extend these findings we determined the effect of ROCK inhibition on development of the DMS and on proplatelet formation.

Optimizing megakaryocyte polyploidization by targeting multiple pathways of cytokinesis.

Background: Large-scale in vitro production of platelets (PLTs) from cord blood stem cells is one goal of stem cell research. One step toward this goal will be to produce polyploid megakaryocytes capable of releasing high numbers of PLTs. Megakaryocyte polyploidization requires distinct cytoskeletal and cellular mechanisms, including actin polymerization, myosin activation, microtubule formation, and increased DNA production.