Abstract: The present invention relates to an apparatus, system and method for heating a fluid chamber. Devices for heating a fluid chamber, in which a temperature sensitive or temperature-initiated chemical reaction takes place, typically comprise a heater and a temperature sensor. A heater device heats a fluid container which is separable from the heater device. The device comprises one or more substrates each forming a surface of a receiving location for the fluid container. A first heater is disposed on a surface of a substrate in thermal communication with a second heat transfer surface and is spaced apart from the first heat transfer surface. A first temperature sensor is in thermal communication with the first heater and a second temperature sensor is in thermal communication with the second heater. The device is configured to conform to the shape of the fluid container such that the first and the second heat transfer surfaces come into contact with the fluid container.

Abstract: A method, device and system employs particles, such as nanoparticles, and an electric or electro-magnetic field, to cause cell death in target cells by non-thermal means. The method of causing targeted cell death comprises the steps of: introducing a particle to the interior of a target cell and exposing the target cell to a transient electromagnetic field for a sufficient time interval in order to cause cell death. Apparatus for performing the method; as well as techniques of delivering particles and for producing particles are also described.

Abstract: A method, device and system employs particles, such as nanoparticles, and an electric or electro-magnetic field, to cause cell death in target cells by non-thermal means. The method of causing targeted cell death comprises the steps of: introducing a particle to the interior of a target cell and exposing the target cell to a transient electromagnetic field for a sufficient time interval in order to cause cell death. The invention overcomes problems associated with similar methods as a result of the fact that a smaller electric field is applied because the particle enhances the effect of the electric field in its immediate vicinity, so reducing the field strength needed to achieve cell lysis and thereby reducing the risk of damage to healthy cells that may be in its vicinity. Apparatus for performing the method; as well as techniques of delivering particles and for producing particles are also described.

Abstract: A method, device and system employs particles, such as nanoparticles, and an electric or electro-magnetic field, to cause cell death in target cells by non-thermal means. The method of causing targeted cell death comprises the steps of: introducing a particle to the interior of a target cell and exposing the target cell to a transient electromagnetic field for a sufficient time interval in order to cause cell death. The invention overcomes problems associated with similar methods as a result of the fact that a smaller electric field is applied because the particle enhances the effect of the electric field in its immediate vicinity, so reducing the field strength needed to achieve cell lysis and thereby reducing the risk of damage to healthy cells that may be in its vicinity. Apparatus for performing the method; as well as techniques of delivering particles and for producing particles are also described.

Abstract: A method, apparatus and system that employs particles, e.g., nanoparticles, and an electric or electro-magnetic field, to cause electroporation in target cells at reduced fields. Electroporation may be irreversible, leading to targeted cell death, or reversible, allowing species to be introduced into the target cell. The method introduces a particle to a position adjacent to the cell membrane of a target cell and exposes the target cell to a transient electromagnetic field for a time interval to cause targeted electroporation. A smaller electric field is applied, thereby surmounting similar methods. The particle enhances the effect of the electric field in its immediate vicinity, so reducing the field strength needed to achieve electroporation and thereby reducing the risk of damage to cells through high field exposure. Electroporation can be targeted to a subset of target cells by targeting the particles to surface markers on the target cell membrane.