Microfluidic devices and/or equipment for microfluidic devices

The invention claimed is: 1. A microfluidic device for separating at least one sub-population of particles from a fluid, the device having: a first microfluidic path for a first fluid, the first microfluidic path being defined in a first body of the device and extending at least in part between a first inlet for introduction of the first fluid in the first microfluidic path and a first outlet for discharging from the first microfluidic path a fluid sample enriched in a first sub-population of particles, the fluid sample being a first fraction of a mixture formed by the first fluid and an auxiliary fluid; a second inlet for introduction of the auxiliary fluid that is to mix with the first fluid, and a second outlet for discharging a second fraction of the mixture formed by the first fluid and the auxiliary fluid, the second fraction of the mixture containing at least one second sub-population of particles, the particles of the at least one second sub-population being smaller in size than the particles of the first sub-population; wherein the first path is defined in the first body between a second microfluidic path and a third microfluidic path, the second microfluidic path being in fluid communication with the second inlet to receive the auxiliary fluid and the third microfluidic path being in fluid communication with the second outlet or discharging the second fraction of the mixture; wherein the first microfluidic path is delimited laterally with respect to the second microfluidic path and the third microfluidic path by a first lateral delimitation and a second lateral delimitation, respectively, the first lateral delimitation having two opposite longitudinal ends and first passageways which connect the second microfluidic path to the first microfluidic path, the second lateral delimitation having two opposite longitudinal end and second passageways which connect the first microfluidic path to the third microfluidic path; wherein the first lateral delimitation comprises at least one array of first barrier elements upwardly protruding from an upper surface of the first body of the device, the first barrier elements being spaced from one another in a lengthwise direction of the first lateral delimitation to define each of said first passageway between two adjacent first barrier elements; wherein the second lateral delimitation comprises at least one array of second barrier elements upwardly protruding from the upper surface of the first body of the device, the second barrier elements being spaced from one another in a lengthwise direction of the second lateral delimitation to define each of said second passageways between two adjacent second barrier elements; wherein the second passageways have a size greater than the size of the particles of the at least one second sub-population and small than the size of the particles of the first sub-population, and wherein the first microfluidic path, the second microfluidic path, the third microfluidic path, the first lateral delimitation, the second lateral delimitation, the first passageways and the second passageways are arranged in such a way that a flow of the auxiliary fluid entering the first microfluid path from the second microfluidic path via the first passageways contributes to force particles of the at least one second sub-population to pass into the third microfluidic path along with said second fraction of the mixture, while the particles of the first sub-population are constrained by the first lateral delimitation and the second lateral delimitation to flow in the first microfluidic path along with the first fraction of the mixture up to the first outlet. 2. The device according to claim 1 , wherein each of the first lateral delimitation and the second lateral delimitation has a length defined by the two opposite ends thereof and wherein the first passageways and the second passageways are distributed along most of the length of the first lateral delimitation and the second lateral delimitation, respectively, for introducing in a distributed way the auxiliary fluid from the second microfluidic path to the first microfluidic path, and for evacuating in a distributed way the second fraction of the mixture from the first microfluidic path to the third microfluidic path. 3. The device according to claim 1 , further comprising at least one of: a section for collection of said first fraction of the mixture, having a respective inlet in fluid communication with the first outlet, a respective outlet opening and elements for separating the particles of said first sub-population from said first fraction of the mixture upstream of said respective outlet opening, or a section for collection of said second fraction of the mixture, having a respective inlet in fluid communication with the at least one second outlet, a respective outlet opening and elements for separating the particles of said second sub-population from said second fraction of the mixture upstream of said respective outlet opening. 4. The device according to claim 3 , wherein the section for collection is configured as a distinct unit which is separable from the first body, the section for collection comprising a second body which is mechanically and hydraulically coupled in a separable way with the first body, the second body having at least one of an electric interconnection, a mechanical interconnection and a hydraulic interconnection couplable in a separable way with a respective electric interconnection or mechanical interconnection or hydraulic interconnection of the first body. 5. The device according to claim 4 , wherein the section for collection includes a device made of semiconductor material, the device made of semiconductor material integrating at least one from among a fluidic means, an electromechanical device, an electrical device, an electronic device in miniaturized form, a device for transmitting and/or receiving signals, a device of a MEMS type, or a device of a NEMS type. 6. The device according to claim 1 , wherein at least one longitudinal portion of the first microfluidic path has a decreasing cross section and extends between a longitudinal portion of the second microfluidic path having decreasing cross section and a longitudinal portion of the third microfluidic path having an increasing cross section path. 7. The device according to claim 1 , wherein at least one of said first inlet, said first outlet, said second inlet, or said second outlet has valve means associated thereto. 8. The device according to claim 1 , wherein the first, the second and the third microfluidic paths have a development which is at least in part substantially spiral-shaped. 9. The device according to claim 1 , wherein at least one of the first inlet, the second inlet, the first outlet and the second outlet are located in a region of the first body about which the first, the second and the third microfluidic paths are wound up or develop in a spiral. 10. The device according to claim 1 , further comprising a closure body superimposed to the first body and having an inner surface facing a bottom of the first, wherein the second and the third microfluidic paths, the first barrier elements and the second barrier elements have upper sealing elements cooperating with the inner surface of the closure body to form a seal therewith. 11. The device according to claim 1 , wherein at least one of a lower supporting body and an upper closure body is associated to the first body, the at least one of the lower supporting body and the upper closure body including a printed circuit. 12. The device according to claim 1 , wherein one of the first lateral delimitation and the second lateral