Abstract: The present invention provides methods for inducing tolerance or suppressing an immune response to an antigen by passing a cell suspension containing an immune cell through a constriction, wherein the constriction deforms the cell thereby causing a perturbation of the cell such that an antigen and/or tolerogenic factor enters the cell, thereby generating a tolerogenic and/or immunosuppressive immune cell. In some embodiments, the tolerogenic and/or immunosuppressive immune cell is delivered to an individual and presentation of the antigen induces tolerance and/or suppresses an immune response to the antigen.

Abstract: Provided herein are methods and compositions related to bacteria of genus Burkholderia useful as therapeutic agents.

Abstract: The present application provides immune cells comprising an HPV antigen and an adjuvant, methods of manufacturing such modified immune cells, and methods of using such modified immune cells for treating an HPV-associated disease, preventing an HPV-associated disease and/or for modulating an immune response in an individual with an HPV-associated disease.

Abstract: Isolating or identifying a cell based on a physical property of said cell can include providing a cell suspension; passing said suspension through a microfluidic channel that includes a constriction; passing the cell suspension through the constriction; and, contacting said cell suspension solution with a compound. The constriction can be sized to preferentially deform a relatively larger cell compared to a relatively smaller cell.

Abstract: The present application provides peripheral blood mononuclear cells comprising an antigen, methods of manufacturing such PBMCs, and methods of using such PBMCs, such as for modulating an immune response in an individual. In some embodiments, the PBMCs are conditioned by incubating the PBMC in the presence of an adjuvant.

Abstract: A microfluidic system for causing perturbations in a cell membrane, the system including a microfluidic channel defining a lumen and being configured such that a cell suspended in a buffer can pass therethrough, wherein the microfluidic channel includes a cell-deforming constriction, wherein a diameter of the constriction is a function of the diameter of the cell.

Abstract: A microfluidic system for causing perturbations in a cell membrane, the system including a microfluidic channel defining a lumen and being configured such that a cell suspended in a buffer can pass therethrough, wherein the microfluidic channel includes a cell-deforming constriction, wherein a diameter of the constriction is a function of the diameter of the cell.

Abstract: A microfluidic system for causing perturbations in a cell membrane includes (a) a microfluidic channel defining a lumen and configured such that a cell suspended in a buffer can pass there through, and (b) source or emitter of an energy field. The microfluidic channel may include a cell-deforming constriction. A diameter of the constriction may be a function of the diameter of the cell. Related apparatus, systems, techniques, and articles are also described.

Abstract: The present disclosure pertains to methods and devices for delivering a compound into a cell, including passing a cell suspension through a surface containing pores, wherein the pores deform the cell thereby causing a perturbation of the cell such that the compound enters the cell, wherein the cell suspension is contacted with the compound.

Abstract: The present invention provides methods for inducing tolerance and/or suppressing an immune response to an antigen by passing a cell suspension containing an anucleate cell through a constriction, wherein the constriction deforms the cell thereby causing a perturbation of the cell such that an antigen and/or tolerogenic factor enters the cell. In some embodiments, the anucleate cell is delivered to an individual and the antigen is delivered to and processed in a tolerogenic environment to induce tolerance and/or suppress an immune response to the antigen.

Abstract: A microfluidic system for causing perturbations in a cell membrane, the system including a microfluidic channel defining a lumen and being configured such that a cell suspended in a buffer can pass therethrough, wherein the microfluidic channel includes a cell-deforming constriction, wherein a diameter of the constriction is a function of the diameter of the cell.

Abstract: Isolating or identifying a cell based on a physical property of said cell can include providing a cell suspension; passing said suspension through a microfluidic channel that includes a constriction; passing the cell suspension through the constriction; and, contacting said cell suspension solution with a compound. The constriction can be sized to preferentially deform a relatively larger cell compared to a relatively smaller cell.

Abstract: The present invention provides methods for delivering a transient and/or reversible complex into a cell including passing a cell suspension through a constriction, wherein said constriction deforms the cell, thereby causing a perturbation of the cell such that the complex enters the cell.

Abstract: Isolating or identifying a cell based on a physical property of said cell can include providing a cell suspension; passing said suspension through a microfluidic channel that includes a constriction; passing the cell suspension through the constriction; and, contacting said cell suspension solution with a compound. The constriction can be sized to preferentially deform a relatively larger cell compared to a relatively smaller cell.

Abstract: The present disclosure pertains to methods for delivering a compound into a cell comprising a cell wall, including passing a cell suspension through a constriction, wherein said constriction deforms the cell comprising a cell wall, thereby causing a perturbation of the cell such that the compound enters the cell, wherein said cell suspension is contacted with the compound.

Abstract: The current subject matter includes methods, systems, articles, and techniques to deliver material to anucleate cells, such as red blood cells. Using a rapid deformation based microfluidic system, loading of red blood cells with macromolecules of different sizes has been shown. Although delivery to some mammalian cells, such as cancer cell lines and fibroblasts had been previously demonstrated using this technique, those designs were incompatible with RBCs that have dramatically different physical properties. Through the use of smaller constriction sizes, high speeds and different buffers successful delivery to red blood cells can be achieved. By enabling robust delivery to red blood cells in a simple, scalable manner, the current subject matter can be implemented in a diversity of applications that deliver material to study red blood cell diseases and/or use red blood cells as a therapeutic platform. Related apparatus, systems, techniques, and articles are also described.

Abstract: A method and device for preferentially delivering a compound such as an antigen to the cytosol of an immune cell. The method comprises passing a cell suspension comprising the target immune cell through a microfluidic device and contacting the suspension with the compound(s) or payload to be delivered.

Abstract: A microfluidic system for causing perturbations in a cell membrane includes (a) a microfluidic channel defining a lumen and configured such that a cell suspended in a buffer can pass there through, and (b) source or emitter of an energy field. The microfluidic channel may include a cell-deforming constriction. A diameter of the constriction may be a function of the diameter of the cell. Related apparatus, systems, techniques, and articles are also described.

Abstract: Gene editing can be performed by introducing gene-editing components into a cell by mechanical cell disruption. Related apparatus, systems, techniques, and articles are also described. The methods and systems of the invention solve the problem of intracellular delivery of gene editing components and gene editing complexes to target cells. The results described herein indicate that delivery of gene editing components, e.g., protein, ribonucleic acid (RNA), and deoxyribonucleic acid (DNA), by mechanical disruption of cell membranes leads to successful gene editing. Because intracellular delivery of gene editing materials is a current challenge, the methods provide a robust mechanism to engineer target cells without the use of potentially harmful viral vectors or electric fields.

Abstract: Isolating or identifying a cell based on a physical property of said cell can include providing a cell suspension; passing said suspension through a microfluidic channel that includes a constriction; passing the cell suspension through the constriction; and, contacting said cell suspension solution with a compound. The constriction can be sized to preferentially deform a relatively larger cell compared to a relatively smaller cell.