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Chromatography
-- A Window on Nature
Author; Matt Adams
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Since
2004 I have been practising the art of round filter paper
chromatography (or chroma). The method was adapted and developed by E.
Pfeiffer
back in the mid 20th century as an holistic tool for assessing the more
subtle
processes and substances found within soil, compost and plants. I am
using it
as a tool to aid my investigation into the link between micro-biology
of soils
and the increased uptake of essential nutrients (including vitality)
into
plants. After five years of research, to which chromas have added a
fascinating
and useful addition, I can now show pictures which represent the many
subtle
process going on in Nature and the relationship between a healthy soil
and a
nutritious plant. Our
understanding of soil and nutrition is still limited. I
believe chromas can help change this. A recent comment by Fred Pearce
of the
Environment Agency said: ‘we
know more about the
moon than we do about soil life’. When
you
consider that in a handful of fertile soil there can be more individual
living
creatures than there are humans on this planet you get the feel for
something
big. Further, within this same handful of soil can be a diversity of
species
that runs into thousands, all with a specific role to play from the
bottom to
the top of the soil profile and horizontally stretching across miles of
land.
It’s a vast ecosystem. Dr
McCarrison (an early pioneer of the organic movement) in the
early 20th century was impressed with the health and vitality of the
Hunza tribe,
in what is now Pakistan. He was a medical doctor and in a lecture given
to the
Royal Society many years ago spoke about the quality of their food “There
is something in the freshness and quality of food which is
not accounted for by the known chemical ingredients of food – proteins,
fats,
carbohydrates, minerals and vitamins.” Others,
including
Steiner have suggested there is more to nutrition than just physical
nutrients.
There are hidden qualities we just cannot see. This is why Steiner
encouraged
Pfeiffer to develop picture forming methods, so they could help us see! One
of the issues associated with soil and nutrition studies is
that what we are looking for is either very small or is of a nature
that
current equipment and methods cannot detect. Because of this they can
easily be
missed or ignored! Modern intensive chemical farming, for example, was
born out
of a flawed experiment that failed to record and measure trace elements
when
trying to determine ‘what makes a plant grow’. Today, according to
government
records, we have lost over 40% of key minerals from the food chain
since the
1940s and, almost certainly, an unknown quantity of trace elements.
Could this
be linked to a collapse in the soil ecosystem? To
find out we must begin to see more. Typically this requires
investment in laboratory equipment e.g. a powerful microscope. For the
average
farmer or gardener this is just not an option. Chromas, originally
referred to
by Pfeiffer as the inexpensive microscope, can be used by almost
anyone. However,
I may be the only person in the UK practising this picture forming
method. In
Europe, particularly Austria and Germany, I believe it is more common.
If you
are already doing it or would like to learn how to I would be pleased
to hear
from you as I plan to begin running workshops in 2010. Some dedicated
time is
required but the process is relatively easy and costs are low. To help
understand what’s involved I have described the process. A rough guide to making a chroma:
Prepare
your sample Soil
is dried and ground, plants are chopped and mashed in a
mortar and pestle. This is then transferred to a flask and submersed in
an
extraction fluid of sodium hydroxide and distilled water (a weak mix)
for up to
six hours. This extracts the many substances present in soil and plants
into a
liquid form. The picture shows carrot samples submerged in sodium
hydroxide.
Prepare
a 15cm filter
paper with silver nitrate. A
hole is made in the
middle so a wick can be inserted and the paper is marked at 4cm and 6cm
from
the centre. The filter paper is then impregnated with the silver
nitrate which
comes up the wick in the centre and moves radially outwards until it
reaches
the first mark (4cm). The paper is then allowed to dry in the dark.
Note, I
have exposed this paper to the light to show the area covered. It also
demonstrates the absence of any pattern if no extraction liquid is
introduced.
Prepare
the chroma
developing box. This
is used to control
temperature between 25oC and 28oC and humidity at 80% plus which is
easily done
using the teapot and dishes of hot water. The picture I hope conveys
the ‘we
can all do this at home’ image. The box I made myself. Once
the extraction process is complete a small amount of the
liquid is taken and poured into a small dish, set within a petri-dish.
The
prepared filter paper is fitted with a new wick and placed into the
solution.
The extraction liquid is drawn up the wick and moves radially outwards
interacting with the silver nitrate as it moves. This is allowed to go
past the
4cm mark until it reaches the 6cm mark. Typically this takes around 15
minutes.
How
the chroma works In
the only
reference book I have found to date, written by Pfeiffer, he suggests
that
within a soil, compost or plant there can be hundreds or even thousands
of
processes taking place at the same time, creating many substances. The
chroma
method uses the property of filter paper to separate different
substances
(which are extracted in a solution) by way of capillary action. It then
needs a
reagent (silver nitrate) to ‘fix’ the fractions and make them visible.
For
example proteins are a substance, the quantity and quality of which are
represented in a chroma by the spokes. Pfeiffer states “…they
(proteins) are also an expression of life, for in ‘dead’
materials they disappear.” Compare
pictures 5 and 6. Picture 5) Good results for:
Picture 6) Poor results for:
How
to read a chroma The
chroma can provide a window from which to view and appreciate
the complexity of Nature. Whilst the process of producing a chroma can
be done
by nearly anyone, to interpret the information is more difficult. This
can take
years of experience and I confess that today I am still learning. The
expert is
Angelika Lübke of CMC (Controlled Microbial Composting), Austria. Some
time after Pfeiffer’s death in 1961 the Lübke family were
allowed access to his personal library and as a result carried on his
work to
become possibly the world’s leading experts in round filter paper
chromatography. Over the years Angelika has acted as my ‘chroma guru’
from
afar. She has helped and encouraged me in my own work by providing
improved
method sheets and interpretation guides. The following guide was
provided by
Angelika. Within
each chroma there are four zones of information which relate
to the following (working from the centre to the outside) for Soil: 1)
organic
matter and physical structure, 2) fungal activity and mineral content,
3)
bacterial activity, protein digestion and content and enzymatic
activity, 4)
Nutrient potential and carbon sources. In plants the zones relate to:
1)
vitamins, 2) mineral content and essential oils, 3) protein content and
amino acids,
4) Enzymatic activity and sugars. Qualities
are recognised by patterns (or form) and also by colour.
For example desirable forms and colours include green, brown, orange,
yellow
and red. Cone-shaped patterns that show regularity, radial lines with
good
definition and fine wavy lines (within the coneshaped patterns) are
good.
Undesirable colours and forms include grey, blue, black and purple.
Lumpy
formation of the cone-shaped pattern, solid radial lines and general
lack of patterns
and formation are not good. A picture paints a thousand words. Pictures 5 and 6 are examples of good and bad chromas. When compared we immediately see a difference between them. The general lack of patterns and formation in picture 6 suggest these soils and plants are very low in the potential to provide good health. The soil and potato chromas in both pictures 5 and 6 are related. I include pictures (7 & 8) of where they came from. Can you guess which chromas belong to which picture? In both cases the quality of soil has influenced the quality of the potato.
Picture 7) A conventional potato farm. Picture 8) GREEN a Bio-Dynamic research garden
The carrot chromas are not from the same
soil but
are included as good and bad examples. The carrot chroma in picture 5
is
healthy with lots of form and pattern. In picture 6 there is a general
lack of
form and complexity. The carrot sample used to produce this had
suffered severe
attacks of carrot root fly. It was definitely dead! Its nutritional
value is
nil. Conclusion It
was Goethe many years ago who coined the saying “The
whole is more than the sum total of its parts.” From
these pictures we can see this to be true. When we look at
both carrot and potato chromas, the ones with the most form
theoretically will
contain good quality proteins, fats, sugars, vitamins and minerals.
When this
occurs we also see a whole, complete picture that looks vital and
fresh. To
achieve this requires a healthy soil ecosystem and I believe the
chromas are
showing this. Therefore, I believe, the welfare of our soils can be
shown to be
directly related to our health. The
chemical revolution in agriculture bypassed many natural processes
to show very quickly a significant increase in yields. Seeing is
believing! The
impact of intensive farming and growing methods has led to the
systematic
destruction or alteration of the soil habitat. Connected to this
appears to be
the decline in physical and non-physical nutrients in our food and
subsequent increase
in degenerative disease for all developed and developing
nations. According to the McCarrison Society, “…brain
disorders have now overtaken all other burdens of ill
health” recently
overtaking heart disease
and cancer, as a result of poor nutrition. In part this may be
connected to
food choices, processing and lifestyle which is related to the way
society
thinks and the values we hold. Central to this are the issues
surrounding food
quality. To
date I have carried out over two hundred of these tests in
various research projects I am involved with. These are designed to
consider
the link between a soils micro-ecology and the uptake of essential
nutrients.
The chroma is a subjective test but I use it to compliment other more
conventional
testing such as soil and plant chemistry and soil biology. Together
this helps
build the bigger picture because the chroma relates directly to these
tests. From
the chromas I have developed I can begin to use them in many
ways. First of all to verify and show that the chroma method can work.
Secondly
to develop a set of standards or guides that I can then use to
correlate with
further testing such as soil micro-biology and the presence and quality
of
nutrients in foods. There is also my own personal development which
comes from practising
this art form and being inspired to think about the many things we
cannot see. Other
picture forming methods are of interest. Sensitive
crystallisation (also developed by Pfeiffer), championed by Food
Quality Health
(a European network of Universities) is interesting and well advanced
in
achieving scientific acceptance; however the set up for this is costly.
The Rising
Pictures method dealt with recently in an excellent book by Janet
Barker is
also good, as is Kirlian photography. For me however, the chroma
remains the
method of choice at present. I
have used chromas that show easily seen differences to put
forward my ideas. In practice the differences are not always so clear
to see,
or what we might expect. They do however, always make me think. The
wider
context for these studies is to promote a better understanding and
improved
relationship with Nature. No easy task! - but one I believe will be of
increasing importance in the future as we begin to see and learn more
about
soils, nutrition and health. Useful
References. Pfeiffer,
Ehrenfried E. Chromatography
Applied to Quality Testing, 1984,
Bio-Dynamic Literature. Available through BDAA Office,
Stroud. Bio-Dynamic
Agricultural Association
www.biodynamic.org.uk CMC
Austria www.landmanagement.net Good
Gardeners Association
www.goodgardeners.org.uk McCarrison
Society www.mccarrisonsociety.org.uk Matt
Adams is the Director/Coordinator of the Good Gardeners Association
which
promotes no-dig gardening and the growing of food for nutrition. He is
a
principle founder of GREEN (Gardens for Research Experiential Education
and Nutrition)
which began in 2004. Based in Stroud nr Gloucester this is a
partnership
initiative supported by the Hiram Trust and involves the Bio-dynamic
Agricultural Association and the Good Gardeners Association. Research
designed and implemented by Matt for this project is attempting to
track the
flow of nutrients from soil to crop to help learn more about the role
of soil
micro-life in the uptake and quality of nutrients. In a bio-dynamic
garden using
different methods of cultivation there are no-dig, single dig and
double dig
plots. Therefore the only difference between them is the deliberate
disturbance
of the soil eco-system (or not, in the case of no-dig) to the
corresponding depths
of either one spade or two. The
research is ongoing and the concept of GREEN is developing. In 2010 as
part of
a seasonal programme of events related to experiential nutrition Matt
is
planning to run workshops on chromatography. Anyone interested in
learning more
about this method or GREEN in general is welcome to contact him.
matt@goodgardeners.org.uk
01453
520322. |
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