Nozzle assembly for a flow cytometry system and methods of manufacture

We claim: 1. A flow cytometer system comprising: a) a nozzle assembly that receives a sample fluid containing particles and a sheath fluid, the nozzle assembly having an interior geometry that produces a fluid stream of the sheath fluid and the sample fluid along a fluid path, the nozzle assembly further comprising a nozzle seat and an orienting nozzle tip secured in the nozzle assembly; b) a receiver that magnetically couples to the nozzle seat, wherein at least one of the nozzle seat and the receiver comprises a magnet; c) a rotational alignment element formed on the nozzle seat, wherein the rotational alignment element comprises: a protrusion extending beyond a generally flat seating surface of the nozzle seat, grooves, or a surface configuration matched to a surface of the receiver; d) an alignment notch formed in the receiver that pairs with the rotational alignment element to secure the nozzle seat and the orienting nozzle tip in a predetermined rotational orientation relative to the receiver when the nozzle seat and the receiver are magnetically engaged and the rotational alignment element and the alignment notch are coupled; e) an excitation source for interrogating particles within the fluid stream at an inspection zone; f) one or more detectors for producing signals representative of emitted or reflected electromagnetic radiation at the inspection zone; and g) an analyzer for analyzing the signals produced by the one or more detectors and for making a sort decision. 2. The flow cytometer system as claimed in claim 1 , wherein the nozzle seat comprises a material selected from a group consisting of: a metal, a magnet, a material having magnetic properties, a material having electromagnetic properties, and combinations thereof. 3. The flow cytometer system as claimed in claim 1 , wherein the receiver of the flow cytometer system comprises the magnet. 4. The flow cytometer system as claimed in claim 1 , wherein the nozzle assembly further comprises: a) a nozzle housing enclosing a nozzle cavity; b) a sample inlet formed in the nozzle housing; c) an injection tube having a sample outlet, the injection tube being mounted with the nozzle housing and extending along the nozzle cavity, wherein the injection tube comprises a flow path providing fluid communication between the sample inlet and the sample outlet; d) one or more sheath inlets in fluid communication with the nozzle cavity; and e) a nozzle exit orifice downstream of the sample outlet. 5. The flow cytometer system as claimed in claim 4 , wherein the injection tube has an outer diameter less than 2 mm. 6. The flow cytometer system as claimed in claim 4 , wherein the nozzle assembly injection tube further comprises a geometry for producing a ribbon core stream. 7. The flow cytometer system as claimed in claim 4 , wherein the flow path between the sample inlet and the sample outlet is located on a single flow axis. 8. The flow cytometer system as claimed in claim 7 , wherein the orienting nozzle tip comprises an internal geometry, wherein said internal geometry begins as an elliptical cross section which tapers down to a circular cross section along the single flow axis. 9. The flow cytometer system as claimed in claim 4 , wherein the injection tube is formed from an extruded polymer. 10. The flow cytometer system as claimed in claim 4 , wherein the nozzle cavity comprises an angle of taper greater than 15 degrees.