초록 ▼

A microfluidic valve including a microchannel, a membrane arranged so as to seal off the microchannel and equipped with resistive units, characterized in that at least one face of the membrane includes at least one groove, and in that the resistive units are arranged in the groove and are capable, w

A microfluidic valve including a microchannel, a membrane arranged so as to seal off the microchannel and equipped with resistive units, characterized in that at least one face of the membrane includes at least one groove, and in that the resistive units are arranged in the groove and are capable, when an electric control current flows through them, of expanding sufficiently under the effect of the heat produced by the flow of the electric current to cause the rupture of at least one part of the membrane.

대표청구항 ▼

1. A microfluidic valve comprising: a substrate;a microchannel within said substrate;a membrane arranged on said substrate so as to seal off said microchannel, said membrane including a resistive element, and at least one face of said membrane including at least one groove forming a predetermined ar

1. A microfluidic valve comprising: a substrate;a microchannel within said substrate;a membrane arranged on said substrate so as to seal off said microchannel, said membrane including a resistive element, and at least one face of said membrane including at least one groove forming a predetermined area of weakness, said groove extending at least in part directly opposite said microchannel,wherein said resistive element is arranged in and extends through said groove such that, when an electric control current flows through said resistive element, said resistive element expands due to an effect of heat produced by the flow of said electric control current to cause a rupture of at least one part of said membrane. 2. The microfluidic valve according to claim 1, wherein said groove comprises two lateral faces substantially opposite to each other, delimiting a width of the groove, and connected to each other by a lower face, andsaid resistive element is in at least partial contact with said lateral faces and said lower face. 3. The microfluidic valve according to claim 1, further comprising an electric control current source connected to said resistive element. 4. The microfluidic valve according to claim 3, wherein the electric control current source controls current by electromagnetic induction, the electric control current source including a coil connected to said resistive element. 5. The microfluidic valve according to claim 1, wherein said resistive element is made of a material having a first coefficient of thermal expansion, andsaid membrane is made of a material having a second coefficient of thermal expansion substantially less than the first coefficient of thermal expansion. 6. The microfluidic valve according to claim 1, wherein said groove has an average depth between 0.2 and 0.8 times an average thickness of said membrane. 7. The microfluidic valve according to claim 1, wherein said resistive element is made of a material chosen among gold, platinum, aluminium, manganese, zinc, nickel, inconel 600, chromium, copper, and polysilicon. 8. The microfluidic valve according to claim 1, wherein said membrane is made of a material chosen among Si3N4, SiO2, and SiN. 9. The microfluidic valve according to claim 1, wherein said at least one face of the membrane is opposite to said microchannel. 10. A microfluidic device comprising: the microfluidic valve according to any one of claims 1 to 9; anda reservoir of fluid being connected to said microchannel. 11. A method for opening a microfluidic valve according to any of claims 1 to 9, comprising supplying an electrical energy of about 0.015 mJ to said resistive element. 12. The microfluidic valve according to claim 1, wherein a direction of a depth of said groove extends directly toward said microchannel.