Methods for controlling the growth of prokaryotic and eukaryotic cells

We claim: 1. A cell growth device comprising: a housing; a motor; a thermal control device; a spectrophotometer; a processor; an electrical connection configured to be electrically coupled to the thermal control device; and a rotating growth vial comprising a vial; a drive engagement mechanism configured to engage with the motor to spin the vial; and a light path through the vial for a light beam generated by the spectrophotometer, wherein the spectrophotometer is configured to measure and deliver to the processor an optical density of cells in the vial; wherein the processor accepts input from a user, receives from the spectrophotometer the optical density of the cells in the vial, and through the electrical connection directs the thermal control device to adjust the temperature of the vial to grow the cells to a target value at a target time. 2. The cell growth device of claim 1 , wherein optical density is measured at a pre-programmed wavelength. 3. The cell growth device of claim 1 , wherein optical density is measured at a wavelength selected by a user. 4. The cell growth device of claim 1 , wherein the optical density is measured continuously. 5. The cell growth device of claim 1 , wherein the optical density is measured at intervals specified by the user or programmed into the processor. 6. The cell growth device of claim 1 , wherein the processor notifies a user when a desired optical density is reached. 7. The cell growth device of claim 1 , wherein the vial volume is 2-100 ml. 8. The cell growth device of claim 7 , wherein the vial volume is 12-35 ml. 9. The cell growth device of claim 1 , wherein the vial is fabricated from polycarbonate or polypropylene. 10. The cell growth device of claim 9 , wherein the vial is fabricated by injection molding. 11. A cell growth device comprising: a housing; a motor; a thermal control device; a spectrophotometer; a processor; an electrical connection configured to be electrically coupled to the thermal control device; and a disposable rotating cell growth vial comprising a vial; a barcode; a drive engagement mechanism connected to the motor and configured to spin the vial; and a first light path through the vial to measure the optical density of cells in the vial via the spectrophotometer; wherein the processor accepts input from a user, receives from the spectrophotometer the optical density of the cells, and through the electrical connection directs the thermal device to adjust the temperature of the vial to grow the cells to a target optical density value at a target time. 12. The cell growth device of claim 11 , wherein optical density is measured at a pre-programmed wavelength. 13. The cell growth device of claim 11 , wherein optical density is measured at a wavelength selected by a user. 14. The cell growth device of claim 11 , wherein the optical density is measured continuously. 15. The cell growth device of claim 11 , wherein the optical density is measured at intervals specified by the user or programmed into the processor. 16. The cell growth device of claim 11 , wherein the processor notifies a user when a desired optical density is reached. 17. The cell growth device of claim 11 , wherein the rotating growth vial comprises 2-6 paddles. 18. The cell growth device of claim 17 , wherein the paddles extend from the center of the rotating growth vial. 19. The cell growth device of claim 17 , wherein the paddles extend from the inner wall of the rotating growth vial. 20. The cell growth device of claim 11 , comprising a second light path.