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MODULE 9 INSPECTION, ASSEMBLY AND PACKAGER (IAP)

Assembly area is a clean area of the CSSD where surgical instruments are
inspected for intactness, cleanliness and functionality. The job in this preparation
area is critical as the surgical instruments will be handled for the last time before
being dispensed to OR rooms or clinics. Therefore, this job must be carried out
by trained decontamination specialists and technicians, in accordance with
manufacturer’s IFU. The area where inspection takes place is designated and
controlled to optimize the effect of the sterilization process and minimize the risk of
contamination of the RMD sets.
Environmental Requirements for IAP:
Ventilation for the inspection, assembly and packing room meets clean room
standards according to ISO 14644-1: 1999 Class 8 or other internationally accepted
equivalent standard. This room must be maintained under positive pressure to
ensure that the air flows outward instead of into the work area whenever the doors of
the assembly place are opened to reduce the risk of airborne bacteria introduction to
the IAP.
As outlined in module
1, all rooms in the department are ventilated and controlled to provide a comfortable
working environment of 20–23C and a relative humidity within the range 30–60%.
Environmental cleaning must follow policies and procedures that have been approved by the
hospital.
infection control committee.
All furniture in this area must be made of smooth non-porous
easy to clean materials.
Fine fibers that compose lint can be carried by air current and
settle on the clean surgical instruments. When lint is introduced
to the sterile field it can cause infection to the patients’ wounds.
Hence, environmental cleaning must be carried out on daily
basis in accordance to the hospital infection control policies and
procedures.
A dedicated cleaning room is located within the IAP room to clean this area—no
outside areas should be cleaned from this location.
Microbiological monitoring is carried out in this room according to hospital infection
control policies. This monitoring is used as an early warning system to alert staff
when environmental quality is drifting out of control. One method of monitoring234
involves placing contact or settle plates in pre-planned locations in the room and
then sending them to the lab for culturing and analysis.
The results of the analysis are then compared to baseline counts of microorganisms
(accepted levels of contamination) predetermined by either the microbiologist or a
contracted specialist. Testing results should be the same or better than this baseline.
To determine how well the IAP room is being cleaned and give you a good idea of
contamination during traffic flows and peak periods, part of the sampling program
should be carried out when the facility is unoccupied to achieve a baseline
contamination level prior to sampling when occupied.
Dress Code Requirement:
Staff movement, between dirty and clean areas is not possible without
passing through a clothing change and hand-wash area.
Protective clothing is worn by personnel entering the IAP room to reduce
the risk of possible contamination of the clean reusable medical devices
and the environment. Managers ensure that protective clothing is
available and all personnel are responsible for correct use and disposal.
Specialists working in the IAP wear:
1/A freshly laundered scrub suit
Scrub suits (Figure M6–6) are low-linting attire that minimize bacterial
shedding and provide comfort and a professional appearance. Freshly
laundered attire is changed daily or whenever it becomes visibly soiled or
wet. Appropriate clothing is used by anyone entering this area, including
staff involved in the maintenance of reprocessing equipment, and visitors.
2/ Head/Hair Cover
A clean, single-use, low lint surgical hat or hood that confines all hair is
always worn in IAP. The hat or hood must be designed so that microbial
dispersal is minimized with all head and facial hair confined as well as
covered. After use, headgear and beard masks should be discarded in the
appropriate waste stream. Stud earrings may be worn as long as they are
totally confined within the head cover. Make-up and jewelry, apart from a
wedding band, are not worn in the IAP.
3/ shoes
Dedicated sturdy shoes should be worn inside the IAP and
never be used out-side. Those shoes should be able to protect
the feet from the items that may in an indeliberate manner fall
from work area. Shoes cover should be worn even if the shoes235
are dedicated to department use only to protect shoes from
contamination.
 WASHER-DISINFECTOR (WD) TO STERILIZER
Following on from module 5 we are now ready to unload the washer-disinfector
containing clean, disinfected surgical instruments and accessories. Depending on
your specific equipment this may be an automated process using conveyor belt-type
unloading mechanisms.
If not automated, the washer carriage can be manually removed from the
chamber taking care to wear heat-resistant gloves if necessary—
remember the temperature in the chamber can reach over 90c. Be careful
with utensils like gallipots or kidney dishes that may have turned upside
down during the washing process and contain hot water. When unloading,
quality checks are carried out before any further processing. Quality
checks consist of:
Correct cycle—for example, if a container cycle was inadvertently used
for instruments then the load should be rejected and sent back for
reprocessing.
Spray arms not blocked — If arms were blocked by RMD during cycle
the load must be rejected as correct cleaning and disinfection may not
have occurred.
Soil or stain — any soil or staining seen on visual inspection is rejected
and items must be sent back for reprocessing.
Excessive wetness — excessive wetness could be caused by blocked arms,
incorrect loading or problems with the WD settings so should be investigated.
Damage due to configuration — for example if items were impacted by
spray arms or the the RMD was not compatible for WD processing.
Devices correctly disassembled — If items were not disassembled,
adequate cleaning would not have occurred so the full set should be
returned for reprocessing.
Completed documentation — load contents and any non-conformances
and rejected loads must be documented and reported to the line
manager. For example, you may notice a device that was not properly
disassembled in the wash area, so the entire tray must be considered
contaminated and sent back to the wash area via the transfer hatch or
chamber. A more serious issue may be where the specialist notices the
spray arm rotation has been hindered and therefore the whole load has236
been compromised and must be returned for re-processing. These non-
conformances must be documented and reported to the line manager
immediately.
Local Policy Checks After Unloading (MUST BE DELETED DUE TO
REPETETION)
What happens to the load next depends entirely on local policies, procedures and
guidelines. These are some standard processes that should also take place:
Check that the chart record for the cycle conforms to the information established
during validation and that all recorded variables are within the parameters
permitted.
Check that the operating cycle selected is in accordance with the specification for
the
load e.g. surgical instruments or anesthetic equipment would need different cycle
types.
Make a visual inspection of the load in order to ensure that there is no obvious
damage, staining or residue.
If staining and/or residue are present, this may be due to the configuration of the
load,
overloaded cart or malfunction in the washing cycle.
Make a visual inspection of the load for dryness.
Unless there is clear indication why a small percentage of RMD in a load were not
cleaned and/or dried effectively, the entire load should be returned for re-
processing.
Manually Cleaned Device Acceptance
Quality checks must also be carried out when accepting items that were
not processed in a WD. These quality checks consist of:
Soil or staining—any visible soil or staining is rejected and items must
be sent back for reprocessing.
Excessive wetness—items that have been manually cleaned and
disinfected must be dry before moving to the IAP room.
Damage—if the item was handled incorrectly or immersed in fluid when it
should not have been it must be reported immediately to the line
manager.
Correctly disassembled devices—if items were not disassembled,
adequate cleaning would not have occurred so the item is returned for
reprocessing.Documentation completed—manually cleaned items and any non-
conformances and rejected items must be documented and reported to
the line manager.
Inspection and Function Testing
All surgical devices unloaded from the washer-disinfector must be inspected for
cleanliness, stains, corrosion, cracks, breakage, and stiffness of movable parts
before being placed in device sets. Where possible, devices should be checked237
under magnification because small pieces of bioburden or debris can otherwise be
difficult to see.
Inspect each RMD from a set separately.
Critically inspect all areas of the devices e.g., box joints, serrations and
crevices, for cleanliness.
Check hinges (such as artery forceps and clamps)
for ease of movement.
Check jaws and teeth (such as found on Kocker- Mosquito forceps, Figure
M6–9) for alignment.
Check ratchets (Figure M6–10) for easy closure and firm hold.
Report any damaged, incomplete or malfunctioning devices immediately to
the supervisor.
Check cannulated devices to ensure channel is patent (clear).
Function check telescopes and light cables as per the manufacturer’s
instructions.
Check each device set for completeness.
Check cutting edges (such as scissors, rongeurs, chisels, curettes) for
sharpness, see device sharpness testing, module 3.
Devices that have an outer insulation coating, for example diathermy
forceps (Figure M6– 11), require close inspection to ensure that the
insulation remains intact.
Check insulated devices using a diathermy pin point tester. Damaged surfaces allow
dirt
and bacteria to collect, and can also lead to a potential burn risk for the patient and/or
the
user.
Check each device for free movement of all part and non-sticking joints. A water-based
lubricant may be used if required (read IFU for dilutions and application).
Check that the edges of clamping RMD meet with no overlap and that teeth mesh together properly.
Check all screws on jointed RMD for tightness as they may become loose during the
cleaning process.

ASSEMBLY AND CHECKING
Once the devices have been inspected and function-tested they are now ready to be
assembled into their respective trays. Many CSSDs today areswitching to one of the
many types of computerized track and trace systems on the market. These systems
are now accepted as one of the most essential requirements in the modern CSSD.
The system allows for the accurate tracking of the devices and device trays through
the whole decontamination process. In the IAP room the track and trace system238
usually consists of handheld barcode readers (Figure M6–12) connected to PC’s that
log and store the information for each tray.
Once the barcode label is scanned by the specialist preparing the tray it
automatically produces a packing list (Figure M6–13) and also generates
a unique barcode label (Figure M6–14) which contains the serial number
specific to that tray and process. Once a new processing cycle begins, a
new unique unit number is produced each and every time. For those CSSDs
that do not have such a computerized system in place, a manual system may
be used. This usually consists of a pre-printed tray checklist and a manual
label gun (Figure M6–15).
There are some general rules when it comes to assembling devices into
trays. Most often items are arranged from left to right in accordance to when
they will be required in a procedure, for example, the scalpel handle used to
make the initial incision is the first device on the left and the needle holders
used to close the wound are on the far right. They can also be arranged by
size so they don’t get tangled or from Surgeon and OR Nurses preferences,
but the most important aspect is to have an accurate checklist that all
specialists follow to ensure consistency. All contents of a specific
surgical instrument tray must be checked and verified
against it’s checklist. Forceps should be placed on instrument pins to
hold them together and reduce tangling. (Figure M6–16A) This can also be
done using a forceps but isn’t recommended. (Figure M6–16B)
Follow the manufacturer’s IFU for devices that should be sterilized in a
particular way or disassembled. This ensures that all surfaces are
presented to the sterilants. Aim to leave all forceps with ratchets open but
if stringers are not available close devices with ratchets on the first
ratchet only, to ensure that steam can penetrate all surfaces. Spread
devices evenly by weight over the tray surface to help prevent
condensate flowing together. Evenly place plastic items in the tray; avoid
collecting them in one area as this may also lead to moisture collection
post-sterilization. Validated tip protectors (Figure M6–17) should be
placed on delicate or sharp items. Tray liners (Figure
M6–18) or silicone mats (Figure M6–19) may also be used to protect
delicate devices but placing them in a manner that protects them,
especially away from heavy devices, is also very important.
Any missing or extra devices found while assembling the tray should be reported to
the supervisor for further action and a non-conformance documented. This is an239
extremely important matter as an incorrect count may lead to long delays in the OR if
an item is found to be missing before or after the case.
Don’t create overcrowded or overweight trays as it leads to
possible issues related to drying and sterility failure.
Additionally, heavy trays can be ergonomic challenge for those
who lift the trays during loading the sterilizers or transportation.
ANSI/AAMI ST77 containment devices for reusable medical
devices sterilization and ANSI/ AAMI ST79, comprehensive
guide to steam sterilization and sterility assurance in health
care facility, recommend that the maximum weight of surgical
instrument sets trays is 25 pounds, this include the weight of
the instruments and the instruments containers.
When processing metal basin, make sure you position them in
a way allows moisture to drain during sterilization. When steam
touches metal it cools down allowing water droplets to form.
This can be avoided by using wicking material such as surgical
towels to facilitate drainage and drying. There should be 1 inch
in size difference When processing multiple basins to avoid
condensation accumulation.
Packaging
Let’s recap the steps completed—so far we have:
Checked that the Washer-disinfector cycle has been successful and the load
is released
Removed the tray of devices from the washer carriage
Placed the tray on a clean workbench surface
Inspected each individual device for cleanliness and functionality
Assembled the devices that were disassembled for washing
Laid the tray out in a manner that ensures good presentation of the devices
and that they are protected against damage in accordance with the tray list.
So now we are ready to wrap or package the tray and prepare it for
sterilization. The two main considerations here are the type of wrap or
packaging chosen and the packaging techniques applied. The packaging
material and packaging techniques are designed to hold and protect the
devices in order to facilitate sterilization and to maintain sterility. As a barrier
material used in the perioperative practice setting, packaging material must
provide an effective barrier to microbial penetration, protect the packaged240
items from contamination during handling, and allow aseptic delivery of the
contents to the sterile field. Re-usable linen is old practice and completely
discouraged due to strike-through risk and also leads to linting which can be
a serious risk for cross-contamination. Today there are many different types
of packaging materials that are used but the most common are:
1/ Rigid containers
2/ Peel Pouches of plastic and/or paper
3/ Sterilization Wraps
While most hospitals use all of these packaging options, the most commonly
used method is sterilization wraps. Choosing the type of241
wrapping material will depend on the items to be
packaged and the sterilization process to be used.
As a minimum, materials used must comply with EN ISO 11607-1 and EN
ISO 11607-2, 2006 and EN 868 parts 2-10, inclusive. Regardless of the type
of packaging chosen the main requirements are that the packaging will:
Provide an adequate barrier to microorganisms and particulates
Be suitable for the items being sterilized
Maintain the sterility of the contents until the package is opened
Allow the sterilants to penetrate, and come into direct contact with the item
and surfaces
Permit removal of the sterilant
Permit aseptic delivery of the contents to the sterile field with minimal
wrap memory (when opened they stay open, without closing back along
crease lines).
Allow for complete and secure enclosure of the item(s)
Protect the contents of the package from physical
damage as far as possible due to stacking or
compression
Allow a method of sealing that results in a complete
seal and provide adequate seal integrity
Be resistant to tears, abrasions and punctures
Ensure the seal is tamper-proof and able to seal only once
Permit adequate air removal
1/ Sterilization Flat Wrap
Is made of nonwoven Spunbond-meltblown-spunbond
(SMS) fabrics and designed as single use product. They
are available in a variety of sizes and weights.
Flat Wrapping Technique:
1/ Sequential Wrapping
Sequential wrapping refers to when two layers of wrap material are
wrapped individually using a fold technique. A single layer is folded242
completely and then sequentially followed with a second sheet of wrap
material and repeating
the wrap sequence to form a package within a package.
2/ Simultaneous Wrapping
Simultaneous wrapping refers to when both layers of wrap material are wrapped
together simultaneously. Two single-layer wrappers or one bonded double-layer
wrapper can be used. Both methods are acceptable but sequential wrapping is
the most commonly used in CSSD.
Square Fold Technique
The items to be wrapped are placed on the table parallel to the wrapper. This
method is generally preferred with heavier items. Figure M6–25
Envelope Fold Technique
The items to be wrapped are placed on the table in a diamond shape to the wrapper.
This method is frequently used for smaller items. Figure M6–26
Both square and envelope fold techniques are used with the
sequential and simultaneous wrap method.
2/ Containers
Rigid reusable containers are making a comeback recently. Very popular
in the 70’s and 80’s they can be seen in many CSSDs today. The
technology has improved significantly and containers are far more user
friendly and can be very cost effective if used properly.
As a barrier, rigid containers are almost indestructible, providing sterility
and customer reassurance if handled and maintained as per the
manufacturer’s instructions. Some things to consider when using
containers are that they are:
Easily disassembled for cleaning, drying and storage
Suitable for the method of sterilization being used
Compatible with the cleaning method and cleaning agent being used
Suitable for the storage configuration
Lockable, tamperproof and non-resealable
Packed in a manner which allows for penetration of the sterilizing agent
Able to remove contents without the risk of contamination of the
contents
Rigid containers have filter and/or valve systems that are secure and
must be in proper working order before sterilization. Examine the filter
plate for integrity both before use and after the sterilization process. If
the filter is damaged or dislodged or has holes, tears, or punctures,
consider the contents contaminated. Clean containers between each use;243
preferably in an automated process, and check the seal between the base
and the lid for possible damage. Containers should be serviced regularly
by the manufacturer as per the IFUs.
Disadvantage of using containers
1/ Creates ergonomics challenge to those who will lift
them due to heaviness.
2/ Requires additional space to store them as they are
larger than wrapped trays
3/ longer cycle time may be required to avoid issues
associated with excessively wet packs
4/ entails extra effort since the containers must be
cleaned between uses.
5/potential risk of filter dislodge leading to instruments
contamination.
3/ Pouches and Reels
There are a variety of packaging materials available for individual surgical
instruments,
depending on the item to be packaged. Peel-apart pouches with a see-through front
and
paper backing are often used for single devices or small loads. They come in reels
of
various sizes where both ends need to be sealed or as single form of various sizes
for
self-seal.
Sealing peel-apart pouches is essential to ensure that the product remains sterile
after
autoclaving. In self-sealing pouches, adhesive is manufactured into the open end of
the
bag or plain top and either a heat sealing machine or autoclave tape is then
required to
create a seal.
The see-through peel packaging is a time-saving concept. It is fast and easy to
pack an
item into a pouch and to close it with a heat sealer (Figure M6–28) or self-seal.
Recommended sealing temperatures and pressures and other technical advice
should be
followed carefully. The identification of packed device(s) is easy because of the
transparent plastic film.
Peel pouches are used to pack small lightweight single
instruments. They can be made of medical grad (kraft244
type) paper/plastic or spunbond polyolefin- plastic
(Tyvek pouch).
The choice of what type of pouch to use depends on
the sterilization method being used.
Paper pouches are used for Steam and Ethylene Oxide
sterilization methods while Tyvek pouches are used
when sterilizing instruments by hydrogen peroxide.
Peel pouches are available in rolls allowing the
specialist to cut off the desired length for each packed
instrument. They are also available in precut sizes. Peel
pouches can be heat sealed or contain self-adhesive
seal that does not require heat. The plastic side of the
pouch allows for fast and easy identification of the
packed item.
Instruments should be packed inside the pouch with
opened hinge to ensure complete sterilant contact to
surfaces of the surgical instruments. Leave about ¼’’
space on each side of the package to facilitate air
removal and sterilant penetration and avoid package
rupture during any of the sterilization phases. It’s
important to remove excessive air from the pouch
before sealing since the trapped air interfere with
proper sterilization. Pouch labeling must be only on the
plastic side using approved pen for the sterilization. It
is recommended to use tip protector to prevent
instruments from puncturing the pouch during
sterilization or normal handling.
Double pouching is required for aseptic presentation of
the items inside the sterile field. It is created by placing
an item inside a proper pouch then sealed. This pouch
is then placed inside another pouch that is slightly245
larger, then sealed. Avoid folding the inner pouch as it
affects air removal and sterilant penetration. Make sure
to use a proper temperature when sealing Tyvek or
medical grade paper pouch.

PACKAGE LABELING
It is necessary that all packages be labeled before sterilization.
Complete and accurate labeling helps the end user to select
the correct pack.
Label should include the following information:
Package contents
Lot number
Sterilization date
Pack complete name
Assembler / packager name
The requesting department
Sterilizer number and used cycle
Labeling information should be written on sterilization tape,
commercially available adhesive labels or in the plastic side ofpeel pouches.