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III.
IV. THE CHEMICAL PROPERTIES OF ELEMENTAL AND NANOCRYSTAL
SILVER
Silver
is a noble metal meaning that it can be found free in nature.
The chemical symbol or abbreviation for silver is derived from
the Latin word for silver (argentium).
Of all the metals, silver is the number one conductor
of heat and electricity. Silver is a soft metal second only to gold in terms of
malleability. Pure
silver is relatively inactive chemically.
It does not react with water or oxygen at normal
temperatures and is not soluble in dilute acids or bases.
These properties have contributed to its historic use
in coinage. However,
silver will react with concentrated acids, e.g. nitric acid or
hydrochloric acid to form salts which are chemically active.(25)
Silver
salts and other chemically active silver compounds are used
for their antimicrobial properties as previously described.
When placed in aqueous solution the silver ion,
responsible for antimicrobial effects, is released.
Silver, because of its antimicrobial activity, has been
impregnated into the plastic of vascular catheters,
toothbrushes, air conditioning systems and may other products.
However
silver, when used as a topical antimicrobial, with the
exception of burn injury, has not been the agent of choice in
other wounds due to the rapid deactivation of the silver by
tissue proteins or chloride anions. Most silver products are rapidly deactivated.
A continuous silver release would be a much more
effective use of silver ions.
In addition, release of other silver radicals, not so
readily neutralized by tissue protein, would be of benefit.
Until recent nano-technologic advances, such a silver
delivery system was not available.
Benefits of Silver Nanocrystals
Nanotechnology is a
general term referring to a new frontier in technology.
The prefix “nano” refers to one-billionth. A nanometer is one billionth of a meter, a nanogram one
billionth of a gram. Ten
hydrogen atoms placed side by side would equal one nanometer
in length.(23-25)
Nanotechnology is
concerned with building products very precisely in very small
sizes. One
advantageous property is that as crystals get smaller, their
surface area to volume ratio increases.
Decreasing the volume
of a crystal i.e., a nanocrystal increases the proportion of
atoms on the surface compared to internal atoms. Increasing
surface area of materials, such as a silver membrane, is
important as chemical reactions take place between molecules
on the surface, thus the larger the surface area, the more
reactions can take place in a shorter time. The properties of the material are markedly amplified in
nanocrystalline metals.
Nanotechnology has
provided a method to achieve the ideal delivery system for
silver to tissues for antimicrobial activity.
Prior to nanocrystals, silver had to be delivered in a
chemically combined form.
A method of depositing pure silver as a nanoparticle or
crystal cation onto a high density polyethylene mesh has
provided a way to deliver the pure silver cation and its
radicals.
The nanocrystal silver
is much more reactive to water and oxygen due to the increased
surface area for reaction, thereby releasing silver cations
very rapidly and for long periods, i.e. days.
This rapid and sustained release has considerable
advantages over the other available silver products,
especially the presence of silver radicals.
Reactive Species of Silver Released from Silver
Products
|
Medical
Name |
Initial
forms of
Silver |
Silver
Species in
Solution |
Conc.
Silver* after
24 hrs |
|
Nanocrystal
Silver Delivery |
Metallic
Ag Nanocrystal |
Ag+ AgO/Ag+
clusters |
50-100μg/ml |
|
1% SSD |
Ag+ |
Ag+ |
30μg/ml |
|
(0.5%)
Silver Nitrate |
Ag+ |
Ag+ |
30μg/ml |
|
Arglaes |
AgKaPO4 |
Ag+ |
20μg/ml |
|
Silverion |
Ag
Metal |
Ag+ |
<1µg/ml |
*
concentration of silver in solution (one square inch of
surface / 5 ml water)
With nanocrystals there is an
increase in the speed of silver delivery to the bacterial wall
resulting in a much more rapid kill. In addition, the
improvement in antibacterial properties, compared to other
available silver products, strongly suggest the nanocrystals
are providing new reactive silver species. To date several
silver radicals have been identified with silver nanocrystals
and more are likely. One appears to be a cluster of silver
cations and radicals identified using a scanning electron
microscope. These silver radicals which are much more reactive
than silver cations have only been observed with the
nanocrystalline silver delivery.(23-28)
In summary, based on advances made in
nanotechnology, a new nanocrystalline silver delivery system
product has been produced which has more potent antimicrobial
properties than other silver products. This advance may also
produce other effects of silver, which have been described,
mainly pro-healing and anti-inflammatory properties.
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