Micro-nozzle

The invention claimed is: 1 . An insert for a micro-nozzle, the insert comprising: a microfabricated fluidic chip having an inlet, an outlet and one or more microfluidic channels connecting the inlet and the outlet; an overmould casing overmoulded around the microfabricated fluidic chip to substantially encase the microfabricated fluidic chip, and comprising an overmould inlet that is in fluid communication with the inlet of the microfabricated fluidic chip and an overmould outlet that is in fluid communication with the outlet of the microfabricated fluidic chip; and wherein the overmould casing comprises one or more chip locating windows and/or at least one pressure transferring window, and wherein said one or more chip locating windows and/or said at least one pressure transferring window are partially or fully filled with an elastomer. 2 . The insert according to claim 1 wherein the overmould casing further comprises a retainer for mounting the insert in a housing of the micro-nozzle such that, in use, an inlet pressure at an inlet side of the overmould casing is isolated from an outlet pressure at an outlet side of the overmould casing. 3 . The insert according to claim 1 wherein the microfabricated fluidic chip comprises one or more side walls, and the overmould casing comprises the at least one pressure transferring window arranged, in use, to transfer pressure at an inlet side of the overmould casing to the one or more side walls of the microfabricated fluidic chip. 4 . The insert according to claim 1 wherein the overmould casing comprises a sub-housing at least partially encasing a porous filter adjacent to the inlet of the microfabricated fluidic chip. 5 . The insert according to claim 1 wherein the microfabricated fluidic chip is located through the one or more chip locating windows when the overmould casing is overmoulded around the microfabricated fluidic chip. 6 . The insert according to claim 1 wherein the one or more chip locating windows are located on an inlet side of the insert and, optionally, the one or more chip locating windows are arranged, in use, to transfer pressure at an overmould casing inlet to lateral surfaces of the microfabricated fluidic chip. 7 . The insert according to claim 1 wherein the one or more chip locating windows are located on an outlet side of the insert and, optionally, one or more nozzle locating windows are arranged, in use, to transfer pressure at an overmould casing outlet side of the overmould casing to the microfabricated fluidic chip. 8 . The insert according to claim 1 wherein the microfabricated fluidic chip comprises at least a first layer and a second layer, wherein a pressure transferring window in the overmould casing is arranged, in use, to transfer hydraulic pressure against the microfabricated fluidic chip to clamp the first layer and the second layers together. 9 . The insert according to claim 8 wherein the first layer comprises glass and the second layer comprises silicon. 10 . The insert according to claim 1 wherein the elastomer is arranged to transfer pressure to one or more side walls of the microfabricated fluidic chip. 11 . A micro-nozzle comprising: a female housing enclosing a nozzle chamber and having a nozzle outlet; the insert according to claim 1 positioned within the nozzle chamber such that an outlet side of the insert is adjacent to and in fluid communication with the nozzle outlet; a male housing arranged to channel fluid from a fluid source to an inlet side of the insert, the male housing having a ridge arranged to engage a flange of the insert so as to seal the insert in place within the female housing. 12 . The micro-nozzle according to claim 11 wherein the male housing and the insert engage each other via an o-ring. 13 . The micro-nozzle according to claim 11 wherein the insert comprises one or more female bores and the male housing comprises one or more protrusions which engage the one or more female bores of the insert such that the one or more protrusions fill the one or more female bores. 14 . The micro-nozzle according to claim 11 wherein the male housing comprises a sub-housing encasing a porous filter arranged to filter the fluid upstream of the insert. 15 . The micro-nozzle according to claim 11 , comprising a porous filter arranged to filter the fluid upstream of a fluidic chip and wherein the fluidic chip and porous insert are separated by a filter retaining wall. 16 . Use of the micro-nozzle according to claim 11 in a drug delivery device. 17 . A method of manufacturing a micro-nozzle, comprising: providing a fluidic chip having one or more side walls, an inlet, and an outlet; injection moulding an overmould case around the fluidic chip so as to substantially encase the fluidic chip, leaving the inlet and the outlet exposed, wherein the overmould case comprises at least one of one or more pressure transferring windows arranged, in use, to transfer pressure at an overmould casing inlet side of the overmould case to the one or more side walls of the fluidic chip, and/or one or more chip locating windows, by which the fluidic chip is located when the overmould case is injection moulded around the fluidic chip; allowing the overmould case to shrink around the fluidic chip so as to provide a tightly sealed casing around the fluidic chip, mounting the overmould case in a housing of a nozzle system; and partially or fully filling said one or more chip locating windows and/or at least one pressure transferring window with an elastomer.