Microfluidic device with multi-level, programmable microfluidic node

The invention claimed is: 1. A microfluidic device comprising: distinct, parallel levels, including a first level and a second level; a first microchannel, defined on the first level; a second microchannel, defined on the second level; and a node, which comprises: a cavity formed on the first level, the cavity open on a top side of the cavity, the top side of the cavity being opposite a bottom side of the cavity; an inlet port, defined on the first level, the inlet port branching from the first microchannel and communicating with the cavity through an ingress of the cavity; an outlet port, branching to the second microchannel on the second level, wherein the outlet port branches to the second microchannel at a level of a junction, the second microchannel comprising a fluid flow constriction valve on one side of the junction, the fluid flow constriction valve configured to force an aqueous liquid exhausted through the outlet port toward a direction that extends from the one side of the junction to an opposite side of the junction, and wherein the fluid flow constriction valve on the one side of the junction is formed by a first section and a second section of the second microchannel, the first section being tapered and leading to the second section, which has a larger average diameter than the first section, to provide an opening angle θ 2 in the second section, being between 60° and 160°; and a via extending from the bottom side of the cavity, down to the outlet port, for the cavity to communicate with the outlet port, wherein the cavity comprises a liquid blocking element configured to prevent an aqueous liquid filling the inlet port to reach the outlet port. 2. The microfluidic device according to claim 1 , wherein: the liquid blocking element is a liquid pinning structure formed at the ingress of the cavity, the liquid pinning structure configured to prevent the aqueous liquid filling at the ingress of the cavity. 3. The microfluidic device according to claim 2 , wherein: the liquid pinning structure is formed by an opening angle θ 1 of the cavity at a level of the ingress of the cavity, wherein the opening angle is between 60° and 160°. 4. The microfluidic device according to claim 3 , wherein: the ingress of the cavity has a width that is smaller than its depth, and a plurality of lateral walls of the cavity on one or more sides of the ingress are separated by a gap corresponding to the width, wherein the plurality of lateral walls form two opposite opening angles θ 1 in the cavity, the two opposite opening angles being between 60° and 160°. 5. The microfluidic device according to claim 1 , wherein: the liquid blocking element is an alterable element, placed in the cavity or sealing the cavity on the bottom side. 6. The microfluidic device according to claim 1 , wherein: the first microchannel and the second microchannel are non-parallel, whereby a first projection associated with the first microchannel and the second projection associated with the second microchannel on a plane separating the first level and the second level are transverse. 7. The microfluidic device according to claim 1 , wherein: the inlet port comprises a fluid flow constriction valve, configured to prevent an aqueous liquid in the second microchannel to reach the via. 8. The microfluidic device according to claim 1 , wherein: the first microchannel and the second microchannel has a depth that is between 10 and 100 μm; the first microchannel and the inlet port has a same depth; the inlet port has a width that is between 5 and 50 μm; and the via has an average diameter that is between 25 and 200 μm, as measured parallel to a mid-plane of the first level from the second level. 9. The microfluidic device according to claim 1 , wherein: the node comprises two outlet ports, including the outlet port, wherein the two outlet ports branch to a microchannel defined on the second level; and the liquid blocking element is further configured to prevent an aqueous liquid filling the inlet port to reach the two outlet ports. 10. The microfluidic device according to claim 1 , wherein: the microfluidic device comprises at least two layers; and the first microchannel, the cavity, and the inlet port are formed in a first layer of the at least two layers, whereas the second microchannel is formed in a second layer of the at least two layers. 11. The microfluidic device according to claim 10 , wherein: the microfluidic device comprises at least three layers, wherein the via is formed in an intermediate layer, between the first layer of the at least two layers and the second layer of the at least two layers. 12. The microfluidic device according to claim 1 , wherein: the first microchannel is an input microchannel; and the device further comprises: at least two distribution microchannels; at least two output microchannels; at least two microfluidic modules, connected to the at least two distribution microchannels, and further connecting to the at least two output microchannels; a first set of at least two nodes, branching from the input microchannel and further branching to the at least two distribution microchannels; a second set of at least two nodes, branching from the at least two output microchannels, and further branching to the at least two distribution microchannels, to connect an ordered pair of the at least two microfluidic modules, wherein one or more node of the first set of at least two nodes and the second set of at least two nodes comprises, respectively: a cavity formed on the first level, the cavity open on a top side of the cavity, the top side opposite a bottom side of the cavity; an inlet port, defined on the first level, the inlet port branching from the input microchannel or an output channel associated with the at least two output microchannels, the inlet port communicating with the cavity through an ingress of the cavity; an outlet port, branching to a distribution microchannel associated with the at least two distribution microchannels; and a via extending from the bottom side of the cavity, down to the outlet port, so as for the cavity to communicate with the outlet port, wherein the cavity comprises the liquid blocking element configured to prevent an aqueous liquid filling the inlet port to reach the outlet port, and liquid blocking elements of subsets of nodes of each of the first set of at least two nodes and the second set of at least two nodes are altered, compared with remaining nodes of the first set and the second set, so as for the nodes to have different liquid pinning strengths in one or more of the first set of at least two nodes and the second set of at least two nodes, such that the extent in which a liquid introduced in the input microchannel passes through one or more ordered pairs of two of the at least two microfluidic modules varies based on the different liquid pinning strengths, in operation. 13. The microfluidic device according to claim 12 , wherein: one or more nodes of the first set of at least two nodes and the second set of at least two nodes, respectively, is altered so as to either pin a liquid thereat or let a liquid pass there-through. 14. The microfluidic device according to claim 13 , wherein: the one or more nodes of the first set of at least two nodes and the second set of at least two nodes, respectively, are arranged as an array of nodes in a crossbar switch configuration.