Table 5.1. cell types, settings, and conditions, 2 vacuum level in bombardment chamber, 3 helium pressure / rupture disk selection – Bio-Rad PDS-1000 / He™ and Hepta™ Systems User Manual

Table 5.1. Cell Types, Settings, and Conditions

Target

Helium

Cell

Growth Cell

Vacuum

Distance Pressure Particle

Type

Phase

Density Osmoticum

(inches Hg) (cm)

(psi)

Size

Bacteria

Late log 10

8

–10

9

per 0.75 M sorbitol

29

6

1,100

M5

to early

100 mm

tungsten

stationary plate

Yeast

Early

10

8

–10

9

per 0.75 M sorbitol

28

6

1,300

0.6 µ

stationary 100 mm

and 0.75 M

gold

plate

manitol

Algae

Log

10

8

–10

9

per

29

6

1,300

0.6 µ

100 mm

gold

plate

Plant
• embryos –

10 explants None

28

6

1,300

1.0 µ

per 100 mm

gold

plate

• callus or Log

0.75 ml

None

28

9

1,100

1.0 µ

cell culture

packed cell

gold

volume

Subcellular Mid-log 5 x 10

7

per None

28

6

1,300

0.6 µ

Organelles

100 mm

gold

plate

Animal
• tissue

Log

50–80%

None

15

3

1,100

1.6 µ

culture

confluent

gold

on 35 mm

plates

• tissue

1 hr–4 days400 µm

None

25

9

1,100

1.6 µ

sections

post-

sections

gold

excision

5.2 Vacuum Level in Bombardment Chamber

The vacuum in the bombardment chamber reduces the frictional drag of the microcarri-

ers as they are accelerated toward the target cells. The unit should be connected to a vacuum

system (see previous section) that can evacuate the bombardment chamber to 28–29 inches

Hg in less than 30 seconds. This level of vacuum is useful for most plant and microbial

cells/tissues. Mammalian cells/tissue should be bombarded at approximately 15 inches Hg.

Helium gas enters the evacuated bombardment chamber once the rupture disk bursts. The

use of low molecular weight helium minimizes the deceleration of the microcarriers as they

pass through helium and also reduces the force of the gas shock wave that hits the target cells.

This reduced impact will help minimize target tissue damage.

5.3 Helium Pressure / Rupture Disk Selection

Each of the nine different rupture disks available ruptures at a specific pressure, ranging in

rating from 450 to 2,200 psi. The rupture pressure determines the power of the shock wave

entering the bombardment chamber. Increasing helium pressure will increase particle acceler-

ation and subsequent target tissue penetration by the DNA-coated microcarriers. Since the

shock wave or resulting acoustic wave may cause damage to the target cells or tissue, use the

lowest helium pressure used that gives high transformation efficiency.

31