Sf21 Cells in Grace's

The following protocol describes a general procedure for thawing cryopreserved cells. For detailed protocols, always refer to the cell-specific product insert.

1. Remove the cryovial containing the frozen cells from liquid nitrogen storage and immediately place it into a 37°C water bath.
2. Quickly thaw the cells (< 1 minute) by gently swirling the vial in the 37°C water bath until there is just a small bit of ice left in the vial.
3. Transfer the vial into a laminar flow hood. Before opening, wipe the outside of the vial with 70% ethanol.
4. Transfer the desired amount of pre-warmed complete growth medium appropriate for your cell line dropwise into the centrifuge tube containing the thawed cells.
5. Centrifuge the cell suspension at approximately 200 x g for 5-10 minutes. The actual centrifugation speed and duration varies depending on the cell type.
6. After the centrifugation, check the clarity of supernatant and visibility of a complete pellet. Aseptically decant the supernatant without disturbing the cell pellet.
7. Gently resuspend the cells in complete growth medium, and transfer them into the appropriate culture vessel and into the recommended culture environment.

Note: The appropriate flask size depends on the number of cells frozen in the cryovial, and the culture environment varies based on the cell and media type.

Insect cells do not require CO2 or high humidity to grow, they can grow in a lab drawer at room temperature. We recommend this so people don't waste CO2 and other resources necessary for maintaining a tissue culture incubator. It should be noted, however, that the cells will grow in a humidified incubator.

Sf9 and Sf21 cells should be lightly adherent cells. However, there are some Sf9 and Sf21 cells that attach to culture vessels very tightly. The use of enzymes such as trypsin, collagenase, hyaluronidase, TrypLE Express, and TrypLE Select have been tried without success for passaging cells. The main problem is that the cells do not attach well after having dissociated with the enzymes.

The best method to use is to culture cells in a T-flask. Close cap tightly and hold flask with cap pointing towards the ceiling. Hit the bottom of the flask over a counter 2-3 times with medium force. Cell detachment may be 60-80% and not 100%. This will allow for detachment of enough cells for passaging. If tapping the flask over the counter is performed with too harsh of a force or too many times, cell viability will be greatly affected.

If possible, we recommend that you culture cells in suspension conditions. Cells in suspension cultures can be passaged directly into adherent conditions when needed. The culture of cells in suspension conditions will allow for higher cell densities as cell growth is not limited to the surface area.

If the cell density is too low and the cells have been in culture for 4-5 days, we recommend concentrating the cells by centrifuging them at 100 X g for 5 minutes and resuspending them in fresh medium. Cells should not be left in the same medium for more than 4-5 days as nutrients in the medium will have been used up by the cells in that period, and the medium itself degraded due to prolonged exposure to warm temperatures. Cells should also be centrifuged and concentrated if a lot of cell debris is observed in culture.

Insect cells are much more fragile than a lot of mammalian cell lines. They suffer much more damage than mammalian cells from overgrowth and over-splitting. Never let cells go above 8 x 10E6 cells/mL or grow at densities less than 0.5 x 10E6 cells/mL in suspension. Insect cells require a little more osmotic pressure than mammalian cells (340 µOsM). Insect cells use a lot of O2, especially during protein expression. Insect cell culture media is more acidic than mammalian media (pH 6.0-6.4). The insect cell culture media is phosphate buffer based. Therefore, no CO² is needed to maintain the pH.