Bombardment of intact cells and tissue with DNA-coated microprojectiles represents a novel approach to the genetic transformation of biological material. In this thesis, a gas propulsion particle gun is developed for such a purpose. The particle gun utilises gas dynamics to control particle velocity and spread, thereby enabling optimisation of transformation efficiencies for varying types of target material. The dynamics associated with particle acceleration are shown to relate to transient, shock tube flow. Measurements from schlieren high-speed video photographs of the shock structure of an underexpanded jet demonstrate good agreement with empirical correlations of previous researchers; pitot tube measurements of the nozzle exit Mach number are made and shown to be in good agreement with theoretical contact surface velocities. A novel optical particle velocimeter is used to measure particle time-offlight between axial locations in the system's target chamber, providing a consistent, distance-averaged measurement of particle velocities. Particle velocities are measured for a range of system pressure ratios and driver gases. Variation in particle velocities is seen to be similar to theoretical variation in contact surface velocities. Analytical theory is used to predict small gas-particle velocity lag. Particle velocities with helium as a driver gas are shown to be considerably higher than those with air. High speed video recording of chalk particles exiting the nozzle is used to visualise the spatial and temporal variation in particle spread as a function of nozzle pressure ratio. This technique demonstrates that particle spread increases with increasing nozzle pressure ratio, as gas dynamics theory indicates. Conditions for bombardment of maize suspension cells are experimentally optimised. Significant rates of transient genetic expression are achieved with both air and helium as driver gases. High levels of transient genetic expression are also found with bombardment of maize coleoptiles and the leaves of various dicot species. Transformation efficiencies for bombardment of HL60 human leukaemia cells show dramatic increases over efficiencies seen with conventional techniques not involving cell bombardment. For other cell types the gas propulsion device described here appears to give rates of transient genetic expression similar to those reported for commercial systems using microprojectiles. Other data for the performance of such systems are too limited at present to allow comparisons of controllability and reproducibility of bombardment efficiency.
| Identifer | oai:union.ndltd.org:bl.uk/oai:ethos.bl.uk:333401 |
| Date | January 1992 |
| Creators | Sarphie, David F. |
| Publisher | University of Oxford |
| Source Sets | Ethos UK |
| Detected Language | English |
| Type | Electronic Thesis or Dissertation |
| Source | https://ora.ox.ac.uk/objects/uuid:c78bb189-665d-4199-8a0b-ce0b439389c7 |
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