Disinfection_and_sterilisation of laboratory materials.ppt

Disinfection and sterilisation

Antiseptics
 (Greek αντι, against, and σηπτικος, putrefactive) are
antimicrobial substances that are applied to living
tissue/skin to reduce the possibility of infection,
sepsis, or putrefaction. They should generally be
distinguished from antibiotics that destroy
microorganisms within the body, and from
disinfectants, which destroy microorganisms found on
non-living objects. Some antiseptics are true
germicides, capable of destroying microbes
(bacteriocidal), whilst others are bacteriostatic and
only prevent or inhibit their growth. Antibacterials are
antiseptics that only act against bacteria.

Some common antiseptics
 Alcohols
 Quaternary ammonium compounds
 Boric acid
 Chlorhexidine Gluconate
 Hydrogen peroxide
 Iodine
 Mercurochrome
 Octenidine dihydrochloride
 Phenol (carbolic acid) compounds
 Sodium chloride
 Sodium hypochlorite

Disinfectants
 are antimicrobial agents that are applied to non-living
objects to destroy microorganisms, the process of
which is known as disinfection. Disinfectants should
generally be distinguished from antibiotics that
destroy microorganisms within the body, and from
antiseptics, which destroy microorganisms on living
tissue. Sanitisers are high level disinfectants that kill
over 99.9% of a target microorganism in applicable
situations. Very few disinfectants and sanitisers can
sterilise (the complete elimination of all
microorganisms), and those that can depend entirely
on their mode of application. Bacterial endospores
are most resistant to disinfectants, however some
viruses and bacteria also possess some tolerance.

Types of disinfectants
 Alcohols
 Aldehydes
 Halogens
 Oxidising agents
 Quaternary ammonium compounds
 Other

Alcohols
 Alcohols, usually ethanol or isopropanol, are
wiped over benches and skin and allowed to
evaporate for quick disinfection. They have
wide microbiocidal activity, are non corrosive,
but can be a fire hazard. They also have
limited residual activity due to evaporation,
and have a limited activity in the presence of
organic material. Alcohols are more effective
combined with water—70% alcohol is more
effective than 95% alcohol. Alcohol is not
effective against fungal or bacterial spores.

Aldehydes
 Aldehydes, such as Glutaraldehyde,
have a wide microbiocidal activity and
are sporocidal and fungicidal. They are
partly inactivated by organic matter and
have slight residual activity

Halogens
 Chloramine is used in drinking water treatment instead of chlorine
because it produces less disinfection byproducts.
 Chlorine is used to disinfect swimming pools, and is added in small
quantities to drinking water to reduce waterborne diseases.
 Hypochlorites (Sodium hypochlorite), often in the form of common
household bleach, are used in the home to disinfect drains, and toilets.
Other hypochlorites such as calcium hypochlorite are also used,
especially as a swimming pool additive. Hypochlorites yield an aqueous
solution of hypochlorous acid that is the true disinfectant. Hypobromite
solutions are also sometimes used.
 Iodine is usually dissolved in an organic solvent or as Lugol's iodine
solution. It is used in the poultry industry. It is added to the birds'
drinking water. Although no longer recommended because it increases
scar tissue formation and increases healing time, tincture of iodine has
also been used as an antiseptic for skin cuts and scrapes.

Oxidising agents
 act by oxidising the cell membrane of microorganisms, which results in a loss of structure and leads to cell
lysis and death.
 Chlorine dioxide is used as an advanced disinfectant for drinking water to reduce waterborne diseases. In
certain parts of the world, it has largely replaced chlorine because it forms fewer byproducts. Sodium
chlorite, sodium chlorate, and potassium chlorate are used as precursors for generating chlorine dioxide.
 Hydrogen peroxide is used in hospitals to disinfect surfaces. It is sometimes mixed with colloidal silver. It
is often preferred because it causes far fewer allergic reactions than alternative disinfectants. Also used in
the food packaging industry to disinfect foil containers. A 3% solution is also used as an antiseptic. When
hydrogen peroxide comes into contact with the catalase enzyme in cells it is broken down into water and a
hydroxyl free radical. It is the damage caused by the oxygen free radical that kills bacteria. However, recent
studies have shown hydrogen peroxide to be toxic to growing cells as well as bacteria; its use as an
antiseptic is no longer recommended.[citation needed]
 Ozone is a gas that can be added to water for sanitation.
 Acidic Electrolyzed Water is a strong oxidising solution made from the electrolysis of ordinary tap water in
the presence of a specific amount of salt, generally sodium chloride. Anolyte has a typical pH range of 3.5
to 8.5 and an Oxidation-Reduction Potential (ORP) of +600 to +1200 mV. The most powerful anolyte
disinfecting solution is that produced at a controlled 5.0 to 6.3 pH where the predominant oxchlorine
species is hypochlorous acid. This environmentally-responsible disinfectant is highly efficacious against
bacteria, fungus, mold, spores and other micro-organisms, in very short contact times. It may be applied as
liquid, fog or ice.
 Peracetic acid is a disinfectant produced by reacting hydrogen peroxide with acetic acid. It is broadly
effective against microorganisms and is not deactivated by catalase and peroxidase, the enzymes which
break down hydrogen peroxide. It also breaks down to food safe and environmentally friendly residues
(acetic acid and hydrogen peroxide), and therefore can be used in non-rinse applications. It can be used
over a wide temperature range (0-40°C), wide pH range (3.0-7.5), in clean-in-place (CIP) processes, in
hard water conditions, and is not affected by protein residues.
 Potassium permanganate (KMnO4) is a red crystalline powder that colours everything it touches, and is
used to disinfect aquariums. It is also used widely in community swimming pools to disinfect ones feet
before entering the pool. Typically, a large shallow basin of KMnO4/water solution is kept near the pool
ladder. Participants are required to step in the basin and then go into the pool. Additionally, it is widely used
to disinfect community water ponds and wells in tropical countries, as well as to disinfect the mouth before
pulling out teeth. It can be applied to wounds in dilute solution; potassium permanganate is a very useful
disinfectant.

Phenolics
 Phenolics are the active ingredient in most bottles of
"household disinfectant". They are also found in
some mouthwashes and in disinfectant soap and
handwashes. Phenol is probably the oldest known
disinfectant as it was first used by Lister, when it was
called carbolic acid. It is rather corrosive to the skin
and sometimes toxic to sensitive people, so the
somewhat less corrosive phenolic o-phenylphenol is
often used in favour. Hexachlorophene is a phenolic
which was once used as a germicidal additive to
some household products but was banned due to
suspected harmful effects.

Quaternary ammonium compounds
 Quaternary ammonium compounds (Quats), such
as benzalkonium chloride, are a large group of
related compounds. Some have been used as low
level disinfectants. They are effective against
bacteria, but not against some species of
Pseudomonas bacteria or bacterial spores. Quats are
biocides which also kill algae and are used as an
additive in large-scale industrial water systems to
minimize undesired biological growth. Quaternary
ammonium compounds can also be effective
disinfectants against enveloped viruses.

Other
 Dettol is used to disinfect surfaces at home. It kills the majority
of bacteria. It is one of the few disinfectants useful against
viruses.[citation needed]
 Virkon is a wide-spectrum disinfectant used in labs. It kills
bacteria, viruses, and fungi. It is used as a 1% solution in water,
and keeps for one week once it is made up. It is expensive, but
very effective, its pink colour fades as it is used up so it is
possible to see at a glance if it is still fresh.
 High-intensity ultraviolet light can be used for disinfecting
smooth surfaces such as dental tools, but not porous materials
that are opaque to the light such as wood or foam. Ultraviolet
light fixtures are often present in microbiology labs, and are
activated only when there are no occupants in a room (e.g., at
night).

Disinfection
 a reduction in the number of viable
organisms
 Can be achieved by:
 Low-temperature steam
 Boiling water
 Chemical disinfectants

Low-temperature steam
 Most bacteria and viruses are killed by
exposure to moist heat
 Usually achieved with dry saturated steam at
73 C for greater than 10 minutes
 Effective and reliable and suitable for
instrument with a lumen
 Unsuitable for heat-sensitive items

Chemical disinfectants
 Destroys microorganisms by chemical or physicochemical
means
 Different organisms vary in their sensitivity
– Gram-positive - highly sensitive
– Gram-negative - relatively resistant
– Clostridial & mycobacterial species - very resistant
– Slow viruses - highly resistant
 Disinfectants are suitable for heat-sensitive items
 Less effective than heat
 Chemicals used include:
– Clear soluble phenolics
– Hypochlorites
– Alcohols
– Quaternary ammonium compounds

Sterilisation
 Removal of viable microorganisms including
spores and viruses
 Can be achieved by:
– Autoclaves
– Hot air ovens
– Ethylene oxide
– Low-temperature steam and formaldehyde
– Sporicidal chemicals
– Irradiation
– Gas plasma

Autoclaves
 Steam under pressure has a higher temperature than
100 C
 To be effective against viruses and spore forming
bacteria need to
 Have steam in direct contact with material
 Vacuum has to be created
 Need to autoclave for 3 min at 134 C or 15 min at
121 C
 Check performance by colour changes on indicator
tape
 Autoclaves are highly effective and inexpensive
 Unsuitable for heat-sensitive objects

Hot ovens
 Inefficient compared to autoclaves
 Requires temperatures of 160 C for 2
hours or 180 C for 30 min

Ethylene oxide
 Highly-penetrative and active against
bacteria, spores and viruses
 Also flammable, toxic and expensive
 Leaves toxic residue on sterilised items
 Instruments therefore need to be stored
for prolonged period before use
 Suitable for heat-sensitive items

Sporicidal chemicals
 Often used as disinfectants but can also
sterilise instruments if used for prolonged
period
 Inexpensive and suitable for heat-sensitive
items
 Toxic and irritants
 2% Gluteraldehyde is most widely used liquid
sporicidal chemical
 Most bacteria and viruses killed within 10
minutes
 Spores can survive several hours

Irradiation
 Gamma rays and accelerated electrons
are excellent at sterilisation
 Used as an industrial rather than
hospital based method

Sterilization (or sterilisation)
 is the elimination of all transmissible
agents (such as bacteria, prions and
viruses) from a surface, a piece of
equipment, food or biological culture
medium. This is different from
disinfection, where only organisms that
can cause disease are removed by a
disinfectant

 In general, any instrument that enters an already
sterile part of the body (such as the blood, or beneath
the skin) should be sterilized. This includes
equipment like scalpels, hypodermic needles and
artificial pacemakers. This is also essential in the
manufacture of many sterile pharmaceuticals.
 Heat sterilization is known to have been in used in
Ancient Rome, but it mostly disappeared throughout
the Middle Ages where sanitation was not usually a
concern.
 The preferred principle for sterilization is through
heat. There are also chemical methods of
sterilization.

Heat sterilization
 Autoclaves
 A widely-used method for heat sterilization is
the autoclave. Autoclaves commonly use
steam heated to 121°C (250°F), at 103 kPa
(15 psi) above atmospheric pressure, for 15
minutes. The steam and pressure transfer
sufficient heat into organisms to kill them.
 Proper autoclave treatment will inactivate all
fungi, bacteria, viruses and also bacterial
spores, which can be quite resistant. It will not
necessarily eliminate all prions (discussed
later).

 Other Methods
 Other heat methods include flaming,
incineration, boiling, tindalization, and
using dry heat.

Flaming
 is done to loops and straight-wires in
microbiology labs. Leaving the loop in a
Bunsen burner flame until it glows red
ensures that any infectious agent gets
inactivated. This is commonly used for
small metal or glass objects, but not for
large objects (see Incineration below).

Incineration
 will also burn any organism to ash. It is
used to sanitize medical and other
biohazardous waste before its ash goes
to the tip.
 Incineration is a waste treatment technology that involves the
combustion of waste at high temperatures[1]. Incineration and other
high temperature waste treatment systems are described as "thermal
treatment". In effect, incineration of waste materials converts the waste
into heat (that can be used to generate electricity), sends gaseous
emissions to the atmosphere, and makes residual ash.

Boiling in water
 for 15 minutes will kill most bacteria and
viruses, but boiling is ineffective against
prions and many bacterial spores; therefore
boiling is unsuitable for sterilization. However,
since boiling does kill most bacteria and
viruses, it is useful if no better method is
available. Boiling is a simple and familiar
enough process, and is an option available to
most anyone most anywhere, requiring only
water, enough heat, and a container that can
withstand the heat; however, boiling can be
hazardous and cumbersome.

Tindalization
 is a cumbersome process designed to reduce the
level of activity of sporolating bacteria that are left by
a simple boiling-in-water method. The process
involves boiling for 20 minutes, cooling, incubating for
a day, boiling for 20 minutes, cooling, incubating for a
day, boiling for 20 minutes, cooling, incubating for a
day, and finally boiling for 20 minutes again. The
three incubation periods are to allow spores formed
by bacteria in the previous boiling period to produce
the heat-sensitive bacterial stage, which are killed by
the next boiling step. Tindalization is ineffective
against prions.

Dry heat
 can be used to sterilize items, but as the heat takes
much longer to be transferred to the organism, both
the time and the temperature must usually be
increased, unless forced ventilation of the hot air is
used. The standard setting for a hot air oven is at
least two hours at 160°C (320°F). A rapid method
heats air to 190°C (374°F) for 6 minutes for
unwrapped objects and 12 minutes for wrapped
objects. Dry heat has the advantage that it can be
used on powders and other heat-stable items that are
adversely affected by steam (for instance, it does not
cause rusting of steel objects).

Chemical sterilization
 Chemicals are also used for
sterilization. Although heating provides
the most effective way to rid an object of
all transmissible agents, it is not always
appropriate, because it destroys objects
such as most fiber optics, most
electronics, and some plastics.

Ethylene oxid (EO)
 gas is commonly used to sterilize objects that cannot
survive temperatures greater than 60°C such as
plastics, optics and electrics. Ethylene oxide
treatment is generally carried out between 30°C and
60°C with relative humidity above 30% and a gas
concentration between 200mg/l and 800mg/l for at
least 3 hours. Ethylene oxide penetrates very well,
moving through paper, cloth, and some plastic films
and is highly effective. Ethylene oxide however is
highly flammable, and requires a longer time to
sterilize than any heat treatment. The process also
requires time for aeration post sterilization to remove
toxic residues. Ethylene oxide is widely used and
sterilizes around 50% of all disposable medical
devices.

Ozone
 is used in industrial settings to sterilize
water and air, as well as a disinfectant
for surfaces. It has the benefit of being
able to oxidize most organic matter. On
the other hand, it is a toxic and unstable
gas that must be produced on-site, so it
is not practical to use in many settings.

Bleach
 is another accepted liquid sterilizing agent. Household bleach,
also used in hospitals and biological research laboratories,
consists of 5.25% sodium hypochlorite. At this concentration it is
most stable for storage, but not most active. According to the
Beth Israel Deaconess Medical Center Biosafety Manual (2004
edition), in most cases, it should be diluted to 1/10 of its storage
concentration immediately before use; however, it should be
diluted only to 1/5 of the storage concentration to kill
Mycobacterium tuberculosis. This dilution factor must take into
account the volume of any liquid waste that it is being used to
sterilize. Bleach will kill many organisms immediately, but should
be allowed to incubate for 20 minutes for full sterilization. Bleach
will kill many spores, but is ineffective against certain extremely
resistant spores. It is highly corrosive, even causing rust of
stainless steel surgical implements.

Glutaraldehyde, formaldehyde
 Glutaraldehyde and formaldehyde solutions (also used as
fixatives) are additional accepted liquid sterilizing agents,
provided that the immersion time is long enough – it can take
up to 12 hours for glutaraldehyde to kill all spores, and even
longer for formaldehyde. (This assumes that a liquid not
containing large solid particles is being sterilized. Sterilization
of large blocks of tissue can take much longer, due to the time
required for the fixative to penetrate.) Glutaraldehyde and
formaldehyde are volatile, and toxic by both skin contact and
inhalation. Glutaraldehyde has quite a short shelf life
(<2 weeks), and is expensive. Formaldehyde is less expensive
and has a much longer shelf life if some methanol is added to
inhibit polymerization to paraformaldehyde, but is much more
volatile. Formaldehyde is also used as a gaseous sterilizing
agent; in this case, it is prepared on-site by depolymerization
of solid paraformaldehyde.

Ortho-phthalaldehyde (OPA)
 is a sterilizing chemical which received Food
and Drug Administration (FDA) clearance in
late 1999. Typically used in a 0.55% solution,
OPA shows better myco-bactericidal activity
than glutaraldehyde. It also is effective
against glutaraldehyde-resistant spores. OPA
has superior stability, is less volatile, and
does not irritate skin or eyes, and it acts more
quickly than glutaraldehyde. On the other
hand, it is more expensive, and will stain
proteins (including skin) gray in color.

Hydrogen peroxid
 It is relatively non-toxic once diluted to low concentrations
(although a dangerous oxidizer at high concentrations), and
leaves no residue.
 The Sterrad 50 and other Sterrad sterilization chambers use
hydrogen peroxide vapor to sterilize heat-sensitive equipment
such as rigid endoscopes. The Sterrad 50 sterilizes in 45
minutes and also penetrates some lumen devices. The most
recent Sterrad model, Sterrad NX, can sterilize most hospital
loads in as little as 20 minutes and has greatly expanded lumen
claims compared to earlier models. The Sterrad has limitations
with processing certain materials such as paper/linens and long
thin lumens. Paper products cannot be sterilized in the Sterrad
system because of a process called cellulostics, in which the
hydrogen peroxide would be completely absorbed by the paper
product.

Dry sterilization process (DSP)
 is a process originally designed for the sterilization of
plastic bottles in the beverage industry. It uses
hydrogen peroxide with a concentration of 30-35%
and runs under vacuum conditions. Using the
common reference germs for hydrogen peroxide
sterilization processes, endospores of different
strains of bacillus subtilis and bacillus
stearothermophilus, the Dry Sterilization Process
achieves a germ reduction of 106...108. The
complete cycle time of the process is 6 seconds. The
surface temperature of the sterilized items is only
slightly increased during the process by 10°-15°.
Particularly due to the high germ reduction and the
slight temperature increase the Dry Sterilization
Process is also useful for medical and
pharmaceutical applications

Radiation sterilization
 Methods exist to sterilize using radiation such as X-rays, gamma rays,
or subatomic particles. Gamma rays are very penetrating, but as a
result require bulky shielding for the safety of the operators of the
gamma irradiation facility; they also require storage of a radioisotope,
which continuously emits gamma rays (it cannot be turned off, and
therefore always presents a hazard in the area of the facility). X-rays
are less penetrating and tend to require longer exposure times, but
require less shielding, and are generated by an X-ray machine that can
be turned off for servicing. Subatomic particles may be more or less
penetrating, and may be generated by a radioisotope or a device,
depending upon the type of particle. Irradiation with X-rays or gamma
rays does not make materials radioactive. Irradiation with particles may
make materials radioactive, depending upon the type of particles and
their energy, and the type of target material: neutrons and very high-
energy particles can make materials radioactive, but have good
penetration, whereas lower energy particles (other than neutrons)
cannot make materials radioactive, but have poorer penetration.
 Devices to irradiate objects are used, for example, by the United States
Postal Service to sterilize mail in the Washington, DC area. Also, some
foods are irradiated for sterilization.

Ultraviolet light
 (UV, from a germicidal lamp) can also be used for
irradiation, but only on surfaces and some
transparent objects (note that many objects that are
transparent to visible light actually absorb UV). It is
routinely used to sterilize the interiors of biological
safety cabinets between uses, but is ineffective in
shaded areas, including areas under dirt (which may
become polymerized after prolonged irradiation, so
that it is very difficult to remove). It also damages
many plastics, as can be seen if one forgets a
polystyrene foam object in the cabinet with the
germicidal lamp turned on overnight.

Disinfection_and_sterilisation of laboratory materials.ppt

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