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What
are BioAccess made of? |
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BioAccess is an engineered
formulation of different bacterial stains. They have been found
to be most effective in digesting organic wastes that cause malodours
and block pipelines in drain and sewer systems. BioAccess is likewise
a multi-bacterial strain formula, but it is specially fortified
with enzymes and cleaning agents to speedily solve a wide range
of problems caused by organic waste. |
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How
do BioAccess work? |
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Once released into
an environment where organic waste are present, these biological
formulations quickly breakdown the waste metabolically. The bacteria
secrete powerful enzymes which liquefy waste. The liquefied waste
matter serve as food for the bacterial which continue multiplying
until all organic waste is consumed. Eventually, the bacteria degrades
into harmless carbon dioxide and water. |
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How
safe are BioAccess? |
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The bacterial cultures
present in BioAccess have been produced in the United States under
controlled conditions. These strains, which are similar to those
found in the earth’s soil, are harmless to humans and animals.
They are guaranteed to be pure, and free of pathogenic or disease-causing
organisms. The active ingredient in BioAccess are approved by the
US Department of Agriculture (USDA). Always consult the product
label and MSDS, and use only as directed and read label and safety
information before using. |
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How
about urine smells in the washroom? |
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Urine is largely
made up of urea, which degrades into ammonia. It is this ammonia
which when released into the atmosphere, contribute to the urine
odour problems often found in washrooms. The bacterial strains in
BioAccess prevent the release of ammonia by utilizing its soluble
form as its sole source of nitrogen in the process of growth. Thus,
urine is broken down, but no malodour causing ammonia is given out. |
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Will
BioAccess remove urine stains? |
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Although BioAccess
enzymes are used in stain removing products – it is not advertised
as a “Stain Remover.” Why? Because stains can be very
difficult or impossible to remove, no matter what some products
may claim. Sometimes the “stain” is not stain, but a
permanent discoloration of the material due to a chemical reaction
caused by the urine. |
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Will
BioAccess work on sub floors? |
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Yes, BioAccess work
on any surface or material the solution comes into contact with.
The solution must be allowed to penetrate into the wood pores just
as the urine had penetrated. This is only recommended for small,
localized spot treatments. |
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Will
BioAccess remove urine from concrete? |
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Yes, BioAccess works
on any surface or material the solution comes into contact with.
Concrete is a porous just like wood. Just pour the solution on the
concrete and let dry. |
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Can
BioAccess be used in carpet cleaning machines? |
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BioAccess is recommended
for use in any type of cleaning machine. Dilute with cleaning chemicals
with pH between 5 – 10. To effectively eliminate odors, BioAccess
must be applied full strength. |
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Will
BioAccess work on chairs, or mattresses? |
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Yes, after removing
the soiling such as faeces, vomit, grease and organic compounds,
we recommend as “pre-treatment” to remove the odor where
places very difficult to reach and treat successfully. |
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Will
BioAccess remove urine odors from the padding underneath the carpet
or will I have to replace the padding? |
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BioAccess will even
remove the odors from the padding without having to remove the carpet.
When BioAccess enzymes solution is poured onto the carpet, the solution
will saturate the carpet, penetrating the carpet padding, and the
sub floor – just as the urine did. By saturating the carpet,
the solution comes into contact with all the urine residue, eliminating
the urine odors. There is no requirement to lift the carpet up to
expose the padding, besides, the carpet itself has urine stains. |
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Can
BioAccess kill flying and crawling insects? |
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No, but will see
LESS of them around. BioAccess are not disinfectant cleaner and
does not kill bacteria, it often outperforms many disinfectants
because it attacks and eliminates the “HOST MATERIAL”
that causes the proliferation of bacteria the disinfectants are
designed to kill. Although enzymes are Non Hazardous to both humans
and animals, are not compatible to the insect’s simple digestive
systems and some might dies. |
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What
is bio-enzyme technology and How does it work? |
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To begin with, you
must differentiate between enzymes and micro-organisms (microbes).
Microbes are cells which replicate approximately every 20 minutes
and release enzymes to do the cleaning or degrading work. Enzymes
are by-product of a micro-organism and the degrading, digesting
and cleaning is done by enzymes.
So, micro-organism are single cell organisms which
produce enzymes to degrade their food and human beings are multi-cell
organism producing enzymes to break down their food. Anything that
is organic can be degraded by enzymes.
Micro-organism are particularly useful for sub-surface
cleaning jobs such as drains, pipe-work, in WCs and urinals etc,
as well as in greasetraps, septic and interceptor tanks. Sophisticated
micro-organisms stick to the linings of these surfaces releasing
enzymes to continually digest wastes, fats, greases and scale.
Enzymes, and by this I mean extracted from the
micro-organism, stabilized within the cleaning products targeted
at a specific dire problem, denatured (i.e dead) once they’ve
done their job, are used for cleaning on the surface – any
surface almost anywhere. |
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What
are the main ways that it differs from the action of traditional
cleaning chemicals? |
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Traditional methods
of cleaning just “lift the dirt” usually only emulsifying
a problem which then requires a further job of cleaning the mess
up and disposing of it. These are non-degradable materials, wastes
and biocides which are sent downstream for someone else to sort
out.
Enzymes will partially degrade or breakdown the
effluent into an easily degradable form, digestible nutrients and
other useful enzymes. What is left is water soluble and can be safely
returned to the environment.
Traditional, conventional cleaners only “slice
off” the surface layer of dirt. However, without extensive
mechanical effort or repeated applications they do not penetrate
into cracks, crevices, surface scratches or carpet pile roots. These
are the very areas where bacteria and parasites can form and multiply.
Bio-active cleaners are designed to penetrate more
deeply and clean more thoroughly. Kept moist, the enzymes and microbes
will go on working until all organic waste (the food source for
bacteria and potential pathogens) is consumed. As a result bacteria
counts are kept lower for longer and surfaces are clean enough to
accept final surface sanitizing without additional preparation.
Enzymes whilst cleaning more hygienically than
traditional chemicals are also very gentle with no damage or erosion
to surface materials.
Enzymes work as quickly as chemical cleaners but
in addition they don’t stop working until they have consumed
all traces of targeted waste. In other words, give an enzyme good
working conditions such as moisture and lots of food/nutrients and
you’ve got a happy, very hard working, long lasting bio-worker
on your team. |
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What
are its applications and Where is it currently being used? |
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Bio-active cleaning
and hygiene products can be used almost anywhere there is organic
soiling. It will have a big impact where there is lot of organic
matter and waste; where there is odour or blockage problem and where
exceptional cleanliness is required. Typical areas might be in a
factory where there is oil and grease, in warehouses, garages, workshops,
railway stations and petrol forecourts. The hospitality trade, clinics
and nursing homes, sandwich bars, fast food outlets, pubs, clubs
and cinemas and sports stadium are cleaned using enzymes as are
hospitals, theatres and concert halls. The list itself is endless
but boils down to “If you’ve got a polluting, dirty
problem there is probably an enzyme that can digest it away for
you”
Enzymes can be used on porous surfaces, like concrete,
some tiles or wood; hard surfaces like painted walls, metals, parquet
flooring, sealed floors, porcelain or melamine for example. Soft
surfaces like carpets and upholstery are also ideal surface to clean
using enzymes.
Enzymes can be used on deep or maintenance cleans
and will produce a more powerful, rapid, effective, and deeper sanitizing
clean than most other legal contemporary cleaners. It also goes
without saying that micro-organisms are now quite widely accepted
as cleaners in urinals, WC’s, sewers, pipeworks, washrooms,
greasetraps, septics and interceptor tanks.
There are many contract cleaners, carpet cleaners,
drain maintenance operatives, car valeters, vets and domestic users
of enzymes and micro-organisms and the list grows. |
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What
growth has the bio industry experienced in the cleaning market over
the last two years? |
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Over the last two
years the main growth in bio-active products has come in sub-surface
products, mainly drain, sewers, pipework, septics, and greasetraps.
This would also include urinal and washroom pipeworks. Enzymatic
surface cleaning is just beginning to take off. It should be said
that in USA, France, Germany and several other market leading countries
the bio-cleaning industry is thriving and growing. The UK is, usual
more conservative and takes lt’s time to make it’s mind
up. |
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What
growth has the bio industry experienced in the cleaning market over
the last two years? |
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Over the last two
years the main growth in bio-active products has come in sub-surface
products, mainly drain, sewers, pipework, septics, and greasetraps.
This would also include urinal and washroom pipeworks. Enzymatic
surface cleaning is just beginning to take off. It should be said
that in USA, France, Germany and several other market leading countries
the bio-cleaning industry is thriving and growing. The UK is, usual
more conservative and takes lt’s time to make it’s mind
up. |
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What
impact does it have on the environment and is it really as ecological
as it appears? |
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Enzymes cause no
damage to the environment. In fact they can only help the environment,
being Nature’s way of cleaning up.
All we are doing with enzymatic cleaning is concentrating
, millions of times, the power of nature targeted at a particular
dirt or pollution problem. There are billions of enzymes available
to digest dirt in a single, level teaspoon of product to which you
would add several liters of your water – further diluting
them.
Cleaning with enzymes and micro-organisms is totally
environmentally responsible and truly “green” cleaning.
This can only be a better solution to cleaning problems as the degraded
dirt and residual enzymes in the water can be flushed to drain and
will help water treatment plants further down the sewer line.
With microbes and enzymes you can obtain a cleaner
discharge and out-flow waste is purer (BOD – Biological Oxygen
Demand and COD – Chemical Oxygen Demand is substantially reduced).
As a result discharge costs are lowered and drainage systems are
better maintained.
A good thought to remember is that the waste water
that goes down the drain is going to be recycled and drunk tomorrow
– it follows that you want it as clean as possible with no
harmful products in it. |
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Is
the traditional cleaning chemical industry feeling any impact from
biotechnology? |
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Not at the moment,
just look at the the cleaning industry figures. The major chemical
brands are well established and the average user has been indoctrinated
into believing “bleach or a chemical is king”. It will
be very interesting, if as is possible, the EU outlaws bleach type
products to see just what the majors and their marketing departments
will do. But the main cry is brand protection at the moment to the
exclusion of bio-active products.
There are some well know names manufacturing sub-surface
micro-organisms, e.g drain cleaning and greasetrap maintenance but
none are yet marketing true enzymatic surface cleaning products.
However, it would also be a very short-sighted major chemical manufacturer
that has not got his biocleaning enzyme armoury ready for a future
launch.
enzymes. |
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Why
Bacteria are not Enzymes, and other Essentials? |
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Many products today
contain bacteria or enzymes that can clear blocked pipes, break
down oil or grease and remediate the environment. To appreciate
and understand the potential of these products, we need basic information
about bacteria and enzymes to be aware of their benefits and uses.
Historically, we have been using bacteria and other
enzyme-producing microorganisms to our advantage for many years.
Within the food industry, we have created wines that are made by
the enzymatic actions of microbes on grapes, and in grounds care
we mulch our grass and leaves by allowing the microbes to break
them down to a usable fertilizer.
In the environment, we use the action of microbes
to degrade our sewage, and even in environmental pollution, like
oil spills, microbes are used as a partial measure to break down
the oil that pollutes water. |
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What
is the difference between Bacteria and Enzymes? |
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Bacteria are not
enzymes. Like all living cells, bacteria produce and use enzymes
to break down or assimilate (put together) chemical compounds necessary
for cell survival. Some scientists refer to bacteria as "sacks
of enzymes."
Enzymes are termed "biological catalysts"
because they are chemicals (mainly protein) that bind with another
chemical (referred to as the substrate) that is then broken down.
Because of their enzymes, bacterial organisms vary in their abilities
to withstand environmental conditions and break down compounds.
Some of these organisms can withstand temperatures
of 212 degrees Fahrenheit or minus 200 F. Some live in extremely
acidic or alkaline conditions, and some are able to use oil (hydrocarbons)
or lipids (fat) for food. These survival characteristics are governed
by the bacteria's ability to make and use various enzymes.
Factors that are important for enzyme action alone,
or for bacterial action via enzymes, are temperature, pH (degree
of acidity or alkalinity) and solubilization of the substrates.
Most bacteria are active in an environment of 90 to 100 F with a
neutral pH.
Pure enzymes vary in pH requirements and stability
(see table). When pure enzymes are added to a building environment
such as a drain, the enzyme is usually short-lived due to the fragile
nature of the enzyme under those conditions. The solubility of the
substrate can be improved by the presence of surfactants (detergent-like
substances) added to the enzyme cleaning solution. |
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What
is Pure Enzymes? |
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An example of the
beneficial action of an enzyme is the production of lipase in the
presence of cooking grease. Under the appropriate conditions, bacteria
release lipase enzymes that bind to lipids, which may have been
rendered soluble by surfactants.
A lipid is a complicated structure that usually
contains fatty acids that are bound to a basic glycerol structure.
The lipase enzyme attacks the lipid, releasing the fatty acids.
These fatty acids can then be broken down to smaller compounds by
enzymes from other bacteria or from the same bacterium.
This same bacterium, or other bacteria, may produce
protease enzymes (that break down protein from the meat that is
present in the grease) and amylase enzymes (that break down starch
from the flour that is present). The grease, which is a combination
of lipids, proteins and starch, is broken down to more soluble compounds
that flow more readily.
Pure enzyme solutions are made by extracting enzymes
from animal tissues, the broth in which microorganisms grow or from
lysed microbial cells. The stabilization of enzymes is sometimes
difficult because they have to be packaged at the correct pH level
with a chelating agent, which protects the enzymes from binding
to certain metals and becoming inactive.
Some enzymes are offered in commercial products
to help clear drains or partially break down proteins. The disadvantage
in using enzyme solutions alone is that pure enzymes will disintegrate
in a short period of time, while bacteria are capable of colonizing
and will reproduce to produce more enzymes. |
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