|
I am going to break with
the “tradition” this time!
Can you believe that?! … I, Maurizio Bertoli,
the guy who invented the politically incorrect “ROCKING THE
BOAT” column, am going to be on the same side of the
“salesmen” that I so passionately fight all the time!
Which goes to prove that, ultimately, I’m not
against the stone industry establishment for what it is (I
elected to be a part of it myself, after all!) I am simply
and exclusively against lies, wherever the may come from.
So, at the end, I’m not on the side of the “salesmen”. The
only difference is that this time I’m fighting “salesmen”
from another industry!
And the “lie of the day” is:
“Granite
Harbors
Bacteria!”
It is a fact that despite all the wrongdoing
carried on by the “salesmen” who, unchecked, run the stone
show, and the consequent bad reputation that in many cases
they eventually get to (deservedly) “enjoy”, our ancestral
attraction to natural stone is too strong an enticement to
dissuade consumers from buying it. Hence, no matter what,
the demand for natural stone products is expanding.
This fact, of course, bothers some interest
groups that see their market shares cut into by the always
imitated but never matched beauty of natural stone. Zeroing
in the widespread use of granite as a material for kitchen
countertops, I’m talking about manufacturers of competing,
manmade products, namely the so called “solid surfaces”,
which is nothing but a fancy way of saying: PLASTIC. The
manufacturers of other materials, such as laminated
(“Formica” and such) don’t worry too much: they are quite
cheaper than natural stone; therefore they cater to a
totally different market sector. When it comes to solid
plastic (“Corian” and such), however, their makers do worry,
and very much so. In fact their prices are not much cheaper
than natural granite and, basically they cater to the same
market sector. Since comparing the two materials is not a
fair fight, to defend the inherently inferior quality of
their products they have to fight dirty. And dirty they
fight, by making up vicious lies.
The first lie that came around (we go back, I
believe, 7 or 8 years ago) was about the Radon emission of
granite. It didn’t last long, though. I mean, even
unsophisticated consumers know that radon – inasmuch as
definitely dangerous – is a very volatile gas that comes
from the earth but doesn’t stick around, nor is it stored to
or into anything. In fact, if a household is “infested” by
radon, all it’s required to eliminate any possible health
hazard, is to keep the basement windows open! Now, even
assuming that some granite quarry is sitting on an area rich
with radon gas, how much of it can be stored into a slab
that goes through the following processing: 1. Quarried off
the mountain, in the open air. 2. Hauled on open
truck’s beds. 3. Sliced into slabs by huge gang-saws
featuring incredible blades that cut into the block at a
remarkable speed, but at glacier pace (it may take more than
one day to slab a large block), while using rivers of water
all along. 4. Calibrated, ground, honed and polished
on one side, again using rivers of waters. 5. Stored
in open yards or huge warehouses. How much radon can
still be present in a slab of granite? No instrument known
to man could possibly measure it!
I distinctly remember that when an article
(unsigned! …) was published by a certain magazine, which, by
a “strange” coincidence, was totally sponsored by the solid
plastic industry, warning potential consumers against the
risk of exposure to radon gas by having a granite counter
top installed in their homes, many scientists were outraged
by such a malicious blatant lie and gave the stone industry
their total support, producing solid scientific evidence.
One of those scientists in particular stated that granite,
in fact, could be considered the best insulating material to
protect any given environment from radon gas!
That took care of that! But the “salesmen”
(no matter in which industry they operate) are a resilient
species indeed! They had to come up with something else!
Taking the idea from the fact that many a
“granite” do have natural fissures and crevices, they
started spreading the word that granite harbors bacteria.
Did they ever do any serious homework to support that? Of
course not! The only homework that “salesmen” do every day
is to study easier ways to “sell it”! Like wildfire the word
was spread around, and concerned consumers started worrying
that there could be some truth in the rumor. Some of them,
before making a decision, inquired with a few stone industry
web sites that offer forum-like pages, so that consumers can
post gripes and ask questions, which in turn will be
answered by stone experts (or alleged experts).
The following posting (bulletin #0 of
www.stoneindustry.com) was
volunteered by a microbiologist and medical technologist.
I’m hereby reporting it totally unedited:
| |
|
I
have read several messages in this forum
that ask about bacteria with respect to
granite countertops Vs
"corian"-type countertops. (I am a
microbiologist and medical technologist.)
There is a web site,
http://www.hi-tm.com/Documents/Countertops.html,
which shows the results of a study comparing
6 different countertop materials (laminate,
wood, tile, concrete, stainless steel, and
granite) and how much they retained the
bacteria Escherichia coli (E. coli).
According to this study, the best two
materials were stainless steel and
GRANITE. Also,
keep in mind that from a microbiological
perspective, slab is much better than tile
for a countertop. Tile is a poor choice for
a countertop because of the tendency of
grout (if not sealed religiously) to harbor
bacteria.
I have also checked the FDA Food Code
for 2001 (at
http://www.cfsan.fda.gov/~dms/fc01-4.html)
and there is no reference to "corian" type
products being specifically endorsed. (If
anyone has a specific reference I would like
to see it.)
Hope this helps everyone,
--Kim” |
|
|
Here is also reported
the result of the study Kim is making reference to. I took
in its entirety from the web site that Kim mentions in her
message.
| |
|
THE REDUCTION OF E. COLI ON VARIOUS
COUNTERTOP SURFACES
O. Peter Snyder, Jr., Ph.D.
Hospitality Institute of
Technology and Management
March 22, 1999
Introduction
The purpose of this study was to determine
the cleanability of six countertop surfaces.
1. Laminate
2. Wood
3. Tile
4. Concrete
5. Stainless steel
6. Granite
These materials are
commonly used in home kitchen countertop
construction. Today, it is understood that
many food items that we purchase are highly
contaminated with pathogenic microorganisms,
and it is necessary for the home cook to
make these foods safe. Often, the first step
in food preparation is cutting and
manipulating the food to get it ready. It is
essential that the countertop be cleaned
after raw food has touched the surface.
Otherwise, there can be cross-contamination,
and the people eating the food prepared on
the cross-contaminated surface can become
ill. This study identifies the cleanability
of these six different countertop materials.
Methods
The countertop materials
were supplied by Porter Novelli (1120
Connecticut Avenue NW; Washington, DC
20036-3902). The countertop sources are as
follows.
1. Laminate: Wilson
Art #4557-60; color-dakota ridge
2. Wood: maple, class 65 woods
3. Tile: Daytona tile, grade 5 (no
stock information; made in Italy); ceramic
clay tile fired from 9-1,300ºC with a single
glaze
4. Concrete: custom sample; no
specific information
5. Stainless steel: type 304, number
4 finish
6. Granite: custom sample;
Lelajaross, 2-cm-thick sample
The procedure for doing the experiments was
as follows.
E. coli
ATTC# 25922, a non-pathogenic E. coli,
was used as the marker organism. It was
grown overnight at 35ºC in a static culture
of M broth (Intermational Bioproducts; 14780
NE 95th Street, Redmond, WA 98052) to an
inoculum of approximately 1,000,000,000
organisms per ml.
An area of 81 square
inches of each countertop was inoculated
with 1 ml of this culture in M broth. The
cleaning procedure was as follows. First,
the surface was washed with a dishcloth and
2 liters of detergent (Jefco Yellow
Dishsoap; Unisource / Jefco Group, Inc.;
1040 North Halsted Street; Chicago, IL
60622) water in a stainless steel bowl. The
surface was then rinsed, using a second bowl
with 2,000 ml of clear water and a second
dishcloth. The cleaning process entailed
rubbing the dishcloth left to right over the
surface, rinsing it out, then, rubbing up
and down and rinsing it out. The rinse step
followed the wash step, using the same
left-to-right and up-and-down strokes.
After the surfaces were
washed and rinsed, they were swabbed, using
a sponge swab over the entire 81 square
inches of inoculated surface to find the
mean reduction. The sponge swab was cultured
using Violet Red Bile agar plates
(International Bioproducts) and incubated
overnight at 35ºC.
Following the wash and
rinse, the surfaces were wiped with a 10%
solution of white household vinegar (1 cup
5% vinegar in 9 cups tap water). The
surfaces were allowed to dry for 15 minutes.
They were then sponge-swabbed over the 81
square inches once more, and cultured, using
VRB agar to determine how many E. coli
had been destroyed by the vinegar.
Results
The results of the
experiment are shown in
Table 1 as logarithms of counts per 81
square inches of surface. In the column,
"Real number," the logarithms of the average
are converted to real numbers. In each
experiment, the first column presents the
log mean count of the organisms recovered.
The second column under each experiment
shows the log reduction in bacteria due to
the wash-and rinse process or due to the
vinegar application. The results are also
shown in
Figure 1.
The retention of the E.
coli was from most retained to most
removed as follows.
1. Laminate
2. Wood
3. Tile
4. Concrete
5. Stainless steel
6. Granite
For the laminate,
washing and rinsing reduced the bacterial
counts by about 285 to 1, as shown in the
summary column. When the vinegar was
applied, the overall reduction was increased
to about 500,000 to 1.
For the wood,
washing and rinsing reduced the bacterial
counts by about 500 to 1, as shown in the
summary column. When the vinegar was
applied, the overall reduction was increased
to about 2,000 to 1.
For the tile,
washing and rinsing reduced the bacterial
counts by about 900 to 1, as shown in the
summary column. When the vinegar was
applied, the overall reduction was increased
to about 233,000 to 1.
For the concrete,
washing and rinsing reduced the bacterial
counts by about 2,400 to 1, as shown in the
summary column. When the vinegar was
applied, the overall reduction was increased
to about 30,600 to 1.
For the stainless steel,
washing and rinsing reduced the bacterial
counts by about 4,000 to 1, as shown in the
summary column. When the vinegar was
applied, the overall reduction was increased
to about 230,000,000 to 1.
For the granite,
washing and rinsing reduced the bacterial
counts by about 36,000 to 1, as shown in the
summary column. When the vinegar was
applied, the overall reduction was increased
to about 80,000,000 to 1.
Discussion
This experiment has shown
that every countertop will have a different
cleanability. This experiment was done with
new samples. When some of these samples
become worn, the reduction will probably not
be as significant, except for stainless
steel, which should change the least.
While granite showed the
greatest reduction in washing, overall,
after the vinegar sanitizing, the stainless
steel had the greatest reduction.
Conclusion
It is very important in food
safety for the designer to consider the
countertop material. In this case, the
stainless steel counter showed the greatest
overall reduction after the wash, rinse, and
sanitize processes.
Table 1.
Log Reduction Comparison of Non-pathogenic
Escherichia coli on Surfaces [CFU /
81 sq. in.] as Affected by Surface
Composition, Washing and Rinsing, and
Sanitizing with Vinegar
|
|
|
Expt. 1 |
|
Expt. 2 |
|
Expt. 3 |
|
Expt. 4 |
|
Expt. 5 |
|
Summary |
|
|
|
Material |
Trmt. |
Mean |
Rdtn. |
Mean |
Rdtn. |
Mean |
Rdtn. |
Mean |
Rdtn. |
Mean |
Rdtn. |
Log avg. rdtn. |
Numerical value |
Std. dev. |
|
Innoculum |
9.18 |
|
9.33 |
|
9.34 |
|
9.25 |
|
9.26 |
|
9.27 |
1,862,087,137 |
0.07 |
|
Laminate |
W & R |
4.85 |
4.33 |
6.38 |
2.95 |
6.25 |
3.09 |
8.35 |
0.90 |
8.25 |
1.01 |
2.46 |
286 |
1.32 |
|
|
Vinegar |
3.65 |
5.53 |
3.43 |
5.90 |
3.25 |
6.09 |
3.84 |
5.41 |
3.70 |
5.56 |
5.70 |
498,884 |
0.25 |
|
Wood |
W & R |
6.38 |
2.80 |
6.89 |
2.44 |
6.76 |
2.58 |
6.62 |
2.63 |
6.55 |
2.71 |
2.63 |
429 |
0.12 |
|
|
Vinegar |
5.82 |
3.36 |
6.00 |
3.33 |
5.98 |
3.36 |
6.04 |
3.21 |
5.93 |
3.33 |
3.32 |
2,080 |
0.06 |
|
Tile |
W & R |
6.23 |
2.95 |
6.19 |
3.14 |
6.41 |
2.93 |
6.34 |
2.91 |
6.39 |
2.87 |
2.96 |
912 |
0.09 |
|
|
Vinegar |
4.33 |
4.85 |
3.28 |
6.05 |
2.30 |
7.04 |
4.51 |
4.74 |
4.60 |
4.66 |
5.47 |
293,765 |
0.94 |
|
Concrete |
W & R |
5.81 |
3.37 |
5.89 |
3.44 |
6.29 |
3.05 |
5.80 |
3.45 |
5.69 |
3.57 |
3.38 |
2,377 |
0.18 |
|
|
Vinegar |
4.28 |
4.9 |
4.73 |
4.60 |
4.85 |
4.49 |
4.92 |
4.33 |
5.00 |
4.26 |
4.52 |
32,810 |
0.23 |
|
Granite |
W & R |
4.86 |
4.32 |
4.26 |
5.07 |
4.76 |
4.58 |
4.78 |
4.47 |
4.93 |
4.33 |
4.55 |
35,810 |
0.28 |
|
|
Vinegar |
0 |
9.18 |
1.24 |
8.09 |
0 |
9.34 |
2.88 |
6.37 |
2.74 |
6.52 |
7.90 |
79,432,823 |
1.26 |
|
Stain.Stl. |
W & R |
5.22 |
3.96 |
6.28 |
3.05 |
5.84 |
3.5 |
5.48 |
3.77 |
5.55 |
3.71 |
3.60 |
3,963 |
0.31 |
|
|
Vinegar |
0 |
9.18 |
1.30 |
8.03 |
3.26 |
6.08 |
0 |
9.25 |
2.15 |
7.11 |
7.93 |
85,113,804 |
1.22 |
Figure 1.
Rdtn =
reduction 0 = <100
|
|
|
The
Defense Rests.
|
