Instruments, modules, and methods for improved detection of edited sequences in live cells

We claim: 1. A method of growing cells in a solid wall isolation, incubation and normalization (SWIIN) module comprising: providing a SWIIN module comprising: a retentate member comprising; an upper surface and a lower surface and a first and second end, an upper portion of a serpentine channel defined by raised areas on the lower surface of the retentate member, wherein the upper portion of the serpentine channel traverses the lower surface of the retentate member for about 50% to about 90% of a length and width of the lower surface of the retentate member; at least retentate one port fluidically connected to the upper portion of the serpentine channel; and a reservoir cover at the first end of the retentate member; a permeate member disposed under the retentate member comprising: an upper surface and a lower surface and a first and second end, a lower portion of a serpentine channel defined by raised areas on the upper surface of the permeate member, wherein the lower portion of the serpentine channel traverses the upper surface of the permeate member for about 50% to about 90% of a length and width of the upper surface of the permeate member, and wherein the lower portion of the serpentine channel and the upper portion of the serpentine channel together form the serpentine channel; at least one permeate port fluidically connected to the lower portion of the serpentine channel; a first and second reservoir at the first end of the permeate member, wherein the first reservoir is fluidically connected to the at least one retentate port in the retentate member and the second reservoir is fluidically connected to the at least one permeate port in the permeate member; a perforated member comprising at least 25,000 perforations disposed under and adjacent to the retentate member; a filter disposed under and adjacent to the perforated member and above and adjacent to the permeate member; and a gasket disposed on top of the reservoir cover of the retentate member, wherein the gasket comprises for each of the first and second reservoirs a reservoir access aperture configured to provide fluid access to the first or second reservoir and a pneumatic access aperture configured to provide pneumatic access to the first or second reservoir; loading cells in medium into the upper portion of the serpentine channel in the retentate member to deliver cells and medium into the perforated member; loading oil into the lower portion of the serpentine channel in the permeate member; and flowing oil into the upper portion of the serpentine channel in the retentate member wherein the oil covers the medium thereby isolating medium in each perforation. 2. The method of growing cells according to claim 1 , wherein the cells are yeast cells. 3. The method of growing cells according to claim 2 , wherein the yeast cells are S. cerevisiae cells. 4. The method of growing cells according to claim 1 , wherein the cells comprise a single editing vector. 5. The method of growing cells according to claim 4 , wherein the single editing vector comprises a gRNA sequence to be transcribed, a donor nucleic acid sequence to be transcribed and a coding sequence for a nuclease to be expressed. 6. The method of growing cells according to claim 1 , wherein the SWIIN module further comprises a third and a fourth reservoir wherein the third reservoir is 1) fluidically coupled to a second port in the retentate member, 2) fluidically coupled to a third reservoir access aperture in the gasket into which fluids and/or cells flow from outside the SWIIN module into the third reservoir, and 3) pneumatically coupled to a pressure source via a third pneumatic access aperture in the gasket; and wherein the fourth reservoir is 1) fluidically coupled to a second port in the permeate member, 2) fluidically coupled to a fourth reservoir access aperture in the gasket into which fluids and/or cells flow from outside the SWIIN module into the fourth reservoir, and 3) pneumatically coupled to a pressure source via a fourth pneumatic access aperture in the gasket. 7. The method of growing cells according to claim 1 , wherein the perforated member comprises at least 100,000 perforations. 8. The method of growing cells according to claim 7 , wherein the perforated member comprises at least 200,000 perforations. 9. The method of growing cells according to claim 8 , wherein the perforated member comprises at least 400,000 perforations. 10. The method of growing cells according to claim 1 , wherein oil loaded into the lower portion of the serpentine channel and flowed into the upper portion of the serpentine channel is immiscible in the medium and is biocompatible with the cells. 11. The method of growing cells according to claim 1 , further comprising, after the flowing step, steps of incubating the cells in the SWIIN module to allow editing and harvesting the cells from the SWIIN module. 12. The method of growing cells according to claim 1 , wherein the volume of the mated serpentine channel is from 4 to 40 mL. 13. The method of growing cells according to claim 1 , wherein the volume of a well formed by one of the perforations is from 1 to 5 nL. 14. A method of growing cells in a solid wall isolation, incubation and normalization (SWIIN) module comprising: providing a SWIIN module comprising a retentate member comprising; an upper surface and a lower surface and a first and second end, an upper portion of a serpentine channel defined by raised areas on the lower surface of the retentate member, wherein the upper portion of the serpentine channel traverses the lower surface of the retentate member for about 50% to about 90% of a length and width of the lower surface of the retentate member; at least retentate one port fluidically connected to the upper portion of the serpentine channel; and a reservoir cover at the first end of the retentate member; a permeate member disposed under the retentate member comprising: an upper surface and a lower surface and a first and second end, a lower portion of a serpentine channel defined by raised areas on the upper surface of the permeate member, wherein the lower portion of the serpentine channel traverses the upper surface of the permeate member for about 50% to about 90% of a length and width of the upper surface of the permeate member, and wherein the lower portion of the serpentine channel and the upper portion of the serpentine channel together form the serpentine channel; at least one permeate port fluidically connected to the lower portion of the serpentine channel; a first and second reservoir at the first end of the permeate member, wherein the first reservoir is fluidically connected to the at least one retentate port in the retentate member and the second reservoir is fluidically connected to the at least one permeate port in the permeate member; a perforated member comprising at least 25,000 perforations disposed under and adjacent to the retentate member; a filter disposed under and adjacent to the perforated member and above and adjacent to the permeate member; and a gasket disposed on top of the reservoir cover of the retentate member, wherein the gasket comprises for each of the first and second reservoirs a reservoir access aperture configured to provide fluid access to the first or second reservoir and a pneumatic access aperture configured to provide pneumatic access to the first or second reservoir; loading cells in medium into the upper portion of the serpentine channel in the retentate member to deliver cells and medium into the perforated member; loading oil into the lower portion of the serpentine channel