Some fundamentals of Medical
Device Packaging HOME
Many Sterile Medical Devices are transported by air or sea or rail, all
will travel by road for at least part of their journey from manufacturer to the
eventual user.
Further package handling takes place as pallet loads are first broken
down into smaller units for stacking on shelves in distribution warehouses and
then picked off the shelves to assemble mixed product loads that meet customer
needs.
This means that packages and their contents will be subjected to: -
All sterile packages must meet, inter-alia, the criteria listed below:
·
Sterility must be maintained for the duration of the specified shelf
life.
·
Normal distribution hazards must be tolerated without product or
package damage.
·
Product must tolerate physical contact with the package without adverse
reaction.
·
Packages must not impede product sterilisation nor be significantly
adversely affected by the process.
·
Packages must tolerate the climatic conditions that prevail in the
market area.
·
The package surface must be of suitable material to accept labelling
and have sufficient area.
·
Comply with Environmental impact regulations.
Medical Devices are generally first packaged then terminally
sterilised. Sterility is maintained by the use of package materials and closure
mechanisms that resist the passage of microorganisms. Materials used for
sterile packages generally fall into one of two categories
e.g. Gas ‘barriers’ or a filter material.
Pinhole free aluminium foil and plastic films may act as gas
‘barriers’.
Dupont's Tyvekâ and appropriate medical
grade papers both function as filters that resist the passage of microorganisms
when used as a pouch component or as a blister pack lid.
Packages must tolerate the vibration and shock hazards that will be encountered
during distribution without allowing this vibration to cause oscillation of the
product.
Product oscillation can lead to seal failure and cracking of blisters.
Scuffing of labels and decorated surfaces due to the effects of vibration can
be a problem. Shrink-wrapping the cartons readily prevents this.
Some years ago I tracked a consignment of devices from Shannon Ireland
via Heathrow Airport to a London distribution warehouse. En-route some cases
fell eight feet onto the tarmac. As a result of this experience, I now
recommend that sterile device packages be designed to tolerate a 3-metre drop
test.
Sharp points on a product should be protected to remove the risk of
penetration of the sterile barrier. The package must locate the device so that
product movement is not allowed to abrade the internal package surface and thus
avoid the generation of undesirable debris.
Plastics must not contain any additive that may be subject to migration
or leaching on to the product.
If sterilisation is to be by Gamma or Electron beam radiation then
plastic packaging materials should be chosen that have a good resistance to
irradiation.
For Eto sterilisation consideration must be given to the rate of
penetration of water vapour.
Eto sterilisation does not work in a very low humidity environment.
The reduction in atmospheric pressure that occurs at high altitudes
should not be overlooked.
Medical devices may be used in an emergency at a mountain rescue site.
Hospitals exist at high altitudes such as prevail in the Bolivian
mountains.
Packages may be stressed during an emergency ascent to avoid bad weather when being conveyed in an unpressurised aircraft. See Fig 1 for table of altitude and mean atmospheric pressure.
IATA Dangerous Goods
'Regulations' advise those shipping dangerous goods by Air
·
That "the extremes of temperature that may be
encountered in international transportation are in the order of minus 40°C and
plus 55°C".
·
"due to altitude, pressure reductions will be
experienced under flight conditions which may in extreme conditions be in the
order of 68kPa
(0.68 bar, 10lb/ sq. in.)"
Such pressure reductions may lead to "bursting of the receptacles
or packages during flight".
If a package is to tolerate such conditions then the design must either
allow for equalisation of the internal and external pressure or the seal must be
of such strength that the closure will remain in place despite the pressure
differential.
If products are to be transported or stored under high altitude
conditions then the package designer must consider the potential for seal creep
or even package explosion.
Peelable seals on film pouches or blister packs with an impervious lid
of foil or film must only be specified after consideration of the potential bursting force that will be
encountered. Multiplying the area of a blister opening by the expected pressure
reduction enables an estimation of the force that the package seals must resist
to prevent failure.
The seal strength chosen should not exceed the opening force that it is
reasonable to expect a nurse to apply when wearing two pairs of surgical gloves
with the added impediment of body fluid contamination.
Generally the strength of peel seals falls in the range of 400 to 1500
mg per 25mm width (measured at 180° peel angle and 300mm crosshead speed).
There are two approaches to avoid seal stress when a none breathable
package will be subjected to major changes in altitude: -
·
Minimise the presence of air within the package
·
Design the package so that its capacity can increase to accommodate
expansion of its contained air.
When packaging a liquid into a plastic pot with an impermeable lid, a
common approach to prevent lids blowing, is to totally fill the pot so that
there isn't any air to expand.
Some years ago, a UK yoghurt producer took delivery of a new production
line for filling and sealing his product. Following successful trials he was
dismayed to find a high percentage of seal failures during air transport.
Initially the blister sealing machine manufacturer was held to be responsible.
The real cause was soon found to be a decision to improve the profit margin by
reducing the amount of yoghurt in each pot. An air filled space was left above
the Yoghurt. The trapped air expanded when the air pressure on the outside of
the lid was reduced as the aircraft climbed. The messy result was spilt Yoghurt
in an aircraft's hold when the lids blew open. Filling each pot completely
without headspace eliminated leakage problems.
A very strong seal is required to keep the lids in place.
An example of a package that can change volume as its contents expand
is a loose fitting pouch from which the air is partially evacuated after the
product is inserted and before sealing the closure. With this type of flexible
package, when the internal pressure exceeds the external atmospheric pressure,
the pouch will inflate thus reducing the internal pressure and minimising the
strain on the pouch seals.
Elevated temperatures during distribution can cause a reduction in the
strength of peel seals
(see Fig.2). Normal seal strength generally returns when the
temperature falls. If packages are closed by welded seals, then temperatures
below the plastics melting point are not likely to affect the seal.
Many plastics become more brittle as their temperature falls, leading
to brittle packages that regain their usual strength when normal temperature is
restored.
Table showing relationship between Altitudes above
Sea level and Atmospheric Pressure.
|
Altitude (Feet) |
Pressure |
|||
|
psi |
mbar |
mm of Hg |
in of Hg |
|
|
-1,000 |
15.25 |
1,051 |
787.9 |
31.02 |
|
-500 |
14.94 |
1,030 |
773.8 |
30.47 |
|
Sea Level |
14.70 |
1,013 |
760.0 |
29.92 |
|
500 |
14.43 |
995 |
746.4 |
28.38 |
|
1,000 |
14.18 |
978 |
732.9 |
28.86 |
|
1,500 |
13.90 |
958 |
719.7 |
28.33 |
|
2,000 |
13.67 |
942 |
706.6 |
27.82 |
|
3,000 |
13.19 |
909 |
681.1 |
26.81 |
|
4,000 |
12.70 |
876 |
656.3 |
25.84 |
|
5,000 |
12.23 |
843 |
632.3 |
24.89 |
|
10,000 |
10.10 |
696 |
522.6 |
20.58 |
|
15,000 |
8.28 |
571 |
428.8 |
16.88 |
|
20,000 |
6.75 |
465 |
349.1 |
13.75 |
|
30,000 |
4.36 |
301 |
225.6 |
8.88 |
|
40,000 |
2.72 |
188 |
140.7 |
5.54 |
|
50,000 |
1.69 |
117 |
87.3 |
3.43 |
Fig.2
Peel seal strength
measured at three different temperatures.
|
|
Seal strength, effect of measurement
temperature |
||
|
Test temperature |
22°C |
40°C |
55°C |
|
Autoclavable paper pouch |
3.858 Newtons |
3.488 Newtons |
3.427 Newtons |
|
Tyvek® Coating A Breather pouch |
2.041 Newtons |
1.957 Newtons |
1.844 Newtons |
|
Tyvek® Coating B Chevron pouch |
5.504 Newtons |
2.936 Newtons |
2.881 Newtons |
Paper labels like to stay flat! Contact adhesives tend to allow creep. Be careful that labels applied to a curved surface are produced from material that will not lead to ‘flagging’ in long term storage.
Comply with Environmental impact regulations.
The EU Packaging and Packaging Waste Directive applies to our industry.
Prepared by: Rolande E. Hall,
M Inst Pkg., MIIE.
HOME Revised 4th
December 2000