MS: Probable Cause and Best Bet Treatment
by Ashton
F. Embry
12/20/96
ABSTRACT
Multiple Sclerosis is an autoimmune disease in which the immune system
causes damage to tissues in the central nervous system. The disease results
from both genetic and environmental factors. Studies of identical twins
demonstrate that MS develops only in genetically susceptible individuals due to
one or more environmental influences.
The epidemiology of MS provides a number of important constraints
for the interpretation of the environmental factor which can be regarded as the
main cause of MS. The disease has a very uneven geographic extent and occurs
mainly in USA, Canada, western Europe, New Zealand and Australia where
prevalences are generally greater than 50 per 100,000 population. In these
areas there is a noticeable north/south gradient with MS being more prevalent
in higher latitude, temperate regions. Also within individual countries there
are significant differences in MS prevalence and incidence.
Other important constraints are the sudden increase in prevalence
in the Faroe Islands following World War II occupation by British troops and
the fact that residency in Hawaii increases the risk of MS for those of
Japanese descent while simultaneously decreasing the risk for Caucasians.
Studies have also shown that MS cannot be transmitted by person to person
contact or by blood transfusion. Finally MS is a modern disease which appeared
about 175 years ago. The prevalence has steadily increased from that time.
The various proposed environmental causes of MS can be tested
against the epidemiological data base to see if they are compatible with the
various constraints. All but one of the proposed causes, including a specific
infectious agent (virus, bacteria) and common infectious agents (e.g. influenza
virus), can be eliminated due to various incompatibilities with the established
data. The only environmental factor which reasonably fits all the
epidemiological constraints is diet.
The main disease processes in MS are breaches in the blood-brain
barrier and the passage of activated and inactivated immune cells into the CNS.
These cells initiate a variety of immune reactions which eventually destroy the
myelin wraps on nerve axons. Myelin loss results in various physical
disabilities which increase with progressive destruction of myelin.
The diet factors which can result in such disease processes are
the ingestion of hypersensitive food and large amounts of saturated fats. Food
hypersensitivities reduce the effectiveness of the blood-brain barrier through
Type I (activation of basophils and mast cells) and Type III (deposition of
immune complexes) reactions. T-cells are activated against CNS proteins (Type
IV reaction) by both molecular mimicry of CNS self proteins by food proteins
outside the CNS and by exposure of autoreactive T-cells to previously
sequestered CNS proteins following passage of immune elements through a damaged
blood- brain barrier. Saturated fats contribute to the disease process by
promoting the formation of micro- emboli which also damage the blood-brain
barrier.
Abundant anecdotal data indicate that many people have achieved
either a permanent remission or a significant slowdown in disease progress
through diet revision involving the elimination of hypersensitive food and a
great reduction in saturated fat intake.
The most common foods which result in immune reactions and
eventual MS are dairy, cereal grains, eggs, yeast and legumes. These are all
foods which have been introduced into the human diet relatively recently and
are genetically difficult to tolerate for some individuals. The steadily
increasing prevalence of MS in the last 50 years is due to the greatly
increased consumption of these problematic foods through the popularity of
"fast foods".
The most effective treatment for MS is the elimination of all
dairy, cereal grains, eggs, yeast and legumes as well as all foods which are
shown to be hypersensitive by a blood allergy test for IgE and IgG4. Saturated
fat intake should be limited to less than 15 g a day and polyunsaturated fat
intake, including both omega 3 and omega 6 essential fatty acids, should be
increased. A variety of supplements including vitamins, minerals, antioxidants
and oils is also essential for healing and strengthening the blood- brain
barrier, CNS tissue, immune cells and the intestinal wall. Strick adherence to
this dietary regime will likely greatly reduce or eliminate exacerbations and
lead to a partial or complete recovery.
Currently no research is being promoted or done on the
relationship between dietary factors and MS. This is very unfortunate and is
definitely not in the best interests of persons with MS. MS society officials
must be informed of the major links between diet and MS and the great need for
strong support of research efforts in this field. A major clinical trial which
tests the efficacy of a hypersensitive food-free, low saturated fat diet is
urgently required.
INTRODUCTION
In June, 1995 my 18 year old son was diagnosed with multiple
sclerosis (MS) with confirmation coming a month later with a Magnetic-resonance
imaging (MRI) scan. Since that time I have been reading books, symposium
volumes and journal articles on various aspects of this disease as well as
visiting many informative websites. From the late 60s I have been a geological
research scientist and this has served me well for analyzing the voluminous
data and many interpretations and speculations for MS found in the literature.
In geology I have dealt mainly with large, multifactorial problems (e.g. origin
of the Arctic Ocean, geological history of the Canadian Arctic over a 200
million year time span) for which varied and mainly circumstantial evidence is
available. I have spent much of my career synthesizing large, diverse and
sometimes conflicting data sets into hypotheses and theories of earth history.
In geology we are never absolutely sure we have the "right" answer
but we never shy away from making an interpretation. For this we choose the
simplest hypothesis which fits the data. This hypothesis becomes the accepted
right answer ("truth") until a better (simpler) hypothesis is
proposed or new data require a modification or outright rejection of the
currently accepted answer. I have provided this background because a
geologist's approach to finding an answer to a large, multifactorial problem
such as MS differs significantly from that of the medical scientist. In medical
research there seems to be only a "100% sure interpretation" or a
"don't know" approach.
My approach to the problem of MS has been to try to find the most
probable cause of the disease by using published data on MS epidemiology (who
gets and who doesn't), MS pathogenesis (how the damage to the body happens) and
MS recovery (who has recovered from MS and how they did it). Surprisingly I
could not find a single article or book which took this same systematic
approach to solving the MS puzzle.
The relevant data on MS epidemiology are presented in the first
main section. In the next section all the proposed causes are listed and each
is tested against the established epidemiological constraints to see if it is
compatible with the data or can be rejected as a probable cause. This has led
to the identification of a single factor, diet, which satisfies the
epidemiological constraints.
The basic disease process (pathogenesis) is presented in the next
section. This is followed by a discussion which demonstrates that dietary
factors can result in the known disease process. Finally a number of anecdotal
accounts of recovery are noted and it is shown that diet revision played a
major role in each of these recovery stories. This section is concluded with a
recent first person account of an impressive recovery which was based on the
diet revision suggestions presented in an earlier version of this essay.
The next part of the paper deals with a suggested treatment which is
based on the need for identifying pathogenic foods and eliminating them from
one's diet. The treatment, which consists of diet revision and supplements,
basically counters the effect of a harmful diet and helps repair the already
sustained damage. In this section other environmental factors which likely
contribute to MS and other treatments which may be helpful are discussed.
I conclude the essay with my subjective views of current
deficiencies in the MS research effort and what I believe needs to be done to
remedy this unfortunate situation. I must emphasize this is my best
interpretation given all the data I have found and it is open to revision or
rejection when more data are obtained. The reader is encouraged to critically
evaluate my arguments and interpretations and to decide if my conclusions have
merit or not.
WHAT IS MS?
There is solid evidence that MS is an autoimmune disease which means it is the
result of the actions of one's own immune system on specific tissues in the
body. For example when the immune system attacks collagen in the joints the
autoimmune disease is called rheumatoid arthritis. There are almost 100
different autoimmune diseases with each one being characterized by
immune-mediated damage to specific tissues. MS is characterized by chronic
inflammation and damage to tissues in the central nervous system (CNS) due to
immune responses (Van Oosten et al., 1995). More details of the disease process
are presented in a later section.
CONSTRAINTS ON INTERPRETATIONS OF THE CAUSE OF MULTIPLE SCLEROSIS
There are two different aspects to a possible cause of multiple sclerosis. One
is a genetic cause and the other is an environmental cause. The importance of
both of these factors can be understood when one considers the research which
has been done on identical twins. Current data from Europe and North America,
which are both high risk areas for MS, indicate that, for identical twins with
MS, about 20- 30% of such twins both have MS (Ebers et al., 1986; Mumford et
al., 1994). This compares with only 2% of affected fraternal twins both having
MS (Ebers et al., 1986). The fact that MS is more prevalent in women than men
(~1.5/1) also demonstrates the role of genes in MS. Thus there is little doubt
that there is a genetic factor in MS and it is likely that only genetically
susceptible individuals have the possibility of getting the disease. This
interpretation was recently confirmed by Ebers et al. (1995). However, it
appears that there is no one dominant gene which determines genetic susceptibility
and that many genes, each with a small influence, are involved (Ebers, 1996).
Not much more can be said about the genetic factor and the best we can do is
accept the fact that it exists.
Importantly the twin data also convincingly show that, in high prevalence
areas, only about 50-60% of individuals (5 of 8 identical twins) who are
genetically capable of getting MS, actually contract the disease. Thus almost
half the people in high prevalence areas who are "genetically
programmed" for MS don't get it. In low prevalence areas it would seem
that less than 10% of susceptible individuals have MS. This demonstrates that
there is at least one dominant environmental factor which results in a
genetically susceptible individual being afflicted with MS. These are very
important constraints on interpreting the environmental factor which can be
regarded as the "ultimate cause of MS". It must be so common that it
occurs over much of the world but it has to be very specific such that only
half or less of susceptible people are affected by it. Furthermore this
environmental factor must be much more prevalent or effective in certain areas
of the world.
Another important facet of MS research has been the investigation
into the timing of the action of the environmental factor on the individual.
Immigration data have been used to elucidate this question (Alter et al., 1966;
Dean and Kurtzke, 1971). It has been determined that adult immigrants retain
the risk factor of their country of origin whereas their children tend towards
the risk factor of the country they have immigrated to. This has been
interpreted to indicate that the environmental factor only affects an
individual before puberty (approx. age 15). The more obvious interpretation,
that the adults do not experience the same environmental influences as their
children do in the new country, was seemingly ignored.
The data on identical twins also provide insight into the question
of timing. Twins share essentially the same environment until they leave home
(16-21). Thus, the fact that only 25% of identical twins both have MS, is good
evidence for the interpretation that the environmental factor comes into play
mainly after age 18. Thus we have an apparent paradox. Immigration data
apparently indicate the environmental factor acts before age 15 whereas
identical twin data indicate that it acts mainly after age 18. Any interpreted
cause of MS must explain this paradox.
Another area of research which yields important constraints for
interpretation is the global variance in MS prevalence (the number of people
having MS which is usually recorded as the number for each 100,000 population)
and incidence (the number of people who get MS per year, again recorded as the
number for each 100,000 population). As alluded to earlier, the world can be
divided into a high prevalence (risk) area which encompasses Europe, Canada,
United States, Australia and New Zealand and a low prevalence (risk) area which
encompasses the rest of the world (Kurtzke, 1980). In the high risk area
prevalences between 50 and 100 per hundred thousand people are common. In the
low risk areas MS prevalences are an order of magnitude less (Kurtzke, 1980).
This distribution is in part due to the genetic factor because all the high
risk areas are dominantly populated by individuals of European origin (Poser,
1994). However, the environmental factor is also responsible for the occurrence
of these two very different risk regions. One line of evidence for this is the
fact that immigrants to London, U.K. from areas of low risk (e.g. West Indies)
have a low prevalence but their British-born children have the same high
prevalence as British Caucasians (Elian et al., 1990). An interpretation of the
environmental factor must take into account these two different risk areas with
the factor being much more common or active in the high risk area.
There are also lower order geographic trends in MS prevalence. One
of the most oft quoted trends is the occurrence of a north/south gradient
within the areas of high prevalence. For Canada and USA, prevalences are lowest
in the southern USA, become higher in the northern states and are highest in
Canada (Kurtzke, 1980). In western Europe the gradient is not as well expressed
but prevalences are higher in the nordic countries and Britain than in the more
southerly Mediterranean countries (Rosati, 1994). The north/south gradient is
well expressed in Australia and New Zealand with the highest prevalences in the
temperate, southern portions of these countries (Sadovnick and Ebers, 1993). In
all these cases genetics cannot explain the north/south gradient and it is
clear that the environmental factor is primarily responsible for this general
increase in MS in areas of higher latitude. Any interpretation of the
environmental factor must be compatible with the north/south gradient of MS
prevalences.
MS also shows large differences in prevalence within some
individual countries in the high risk area. For example in Norway MS is up to
five times more common in the inland farming areas than in the relatively
nearby coastal fishing areas (Alter, 1977). Similarly in Canada, MS is at least
twice as prevalent in the Prairie provinces (100-225) as it is on the island of
Newfoundland (50) (Sadovnick and Ebers, 1993). In these cases genetics has no
bearing on this distribution (Newfoundland has a higher percentage of
Caucasians) and the environmental factor must be primarily responsible for such
drastic differences. This conclusion has been recently confirmed by Rosati
(1994) who states in his review of MS in Europe "variations in both
prevalence and incidence rates in ethnically homogeneous populations confirm
the importance of environmental factors". These macro and micro
differences of MS prevalence in the world must be explained by any interpretation
of the environmental factor.
Crucial data for constraining the nature of the environmental
factor come from prevalences for both those of Japanese and Caucasian descent
in Hawaii. Those of Japanese descent have a prevalence of 6.5 (i.e. 6.5
Japanese with MS per 100,000 Japanese in Hawaii) which is over three times that
of Japan (2.1) (Kuroiwa et al., 1983; Alter et al., 1971). Conversely the
Caucasians who were born and raised in Hawaii have a prevalence of 10.5 which
is only one third that of the Caucasians of California (29.9) (Poser, 1994).
Thus we have another paradox concerning the environmental factor. In Hawaii it
acts such that it adversely affects those of Japanese descent whereas at the
very same time it has a very beneficial effect on Caucasians. This puzzling
paradox must be regarded as a critical constraint for an objective
interpretation of the environmental factor.
One of the most interesting and widely quoted epidemiological
studies of MS is that of the greatly increased prevalence of MS in the Faroe
Islands (North Atlantic, west of Norway) following the occupation by 1500-2000
British troops between 1941 and 1944 (Kurtzke, 1977, 1980, 1995). Kurtzke has
classified this increase as an epidemic although other authors have challenged
this view (Benedikz et al., 1994, Poser et al. 1988). Regardless, there can be
no doubt that MS prevalence substantially increased in the Faroes following the
British occupation. Furthermore, the relationship between MS in the Faroe
islanders and the presence of British soldiers is strongly supported by the
fact the cases of MS all occurred in islanders who lived close to British bases
(Kurtzke, 1980, fig. 15). This is an extremely important constraint because it
demonstrates that the environmental factor is not solely indigenous and can
transported from one area to another. Any interpretation of the cause of MS
must satisfactorily explain the sudden increased prevalence in the Faroes and
the mobility of the environmental factor.
Recently another very important epidemiological study was
published by Ebers et al. (1995). These authors were able to demonstrate that
children, who were raised in families in which non-blood relatives (step
parents, step brothers and sisters, adoptees, etc.) had MS, had no increased
risk of MS. This provided good evidence of the genetic factor in MS but more
importantly demonstrated that MS is not transmitted by person to person
contact. An earlier study which involved spouses of persons with MS also
demonstrated this.
Another important piece of evidence for determining MS cause is
the fact that there is no recorded case of MS having been transmitted to
another person through a blood transfusion (Theofilopoulos, 1995a).
Finally it is important to note that MS is a relatively new
disease with the first recorded case being from the beginning of the nineteenth
century (Swank and Dugan, 1987). As argued by Swank and Dugan (1987), MS is
basically a "disease of modern times" although it is possible a few
cases occurred earlier than 1800. There is no doubt that incidence and
prevalence of the disease has been increasing over the last century. Thus the
cause of the disease must be due to an environmental factor(s) which is
progressively having more effect over the last 100 years.
In summary an acceptable interpretation of the environmental
factor, which plays a critical role in the onset and progression of MS, must
explain the following constraining data.
1. It must be found throughout the world but be specific enough to
affect only half or less of the susceptible individuals.
2. It must affect immigrant children more than it does immigrant
adults. On the other hand it must affect susceptible identical twins mainly
when they are adults rather than when they are children.
3. It must be much more common or effective in northwestern
Europe, Canada, United States, Australia and New Zealand than in the rest of
the world.
4. It must be more common or effective in higher latitude areas so
as to create a pronounced north/south gradient of MS prevalence.
5. It must have enough variation so as to create significant MS
prevalence and incidence differences within ethnically homogeneous populations
over relatively short distances.
6. In Hawaii it must adversely affect those of Japanese origin
whereas at the same time have a positive effect on Caucasians.
7. It must be transportable so as to explain the sudden increase
in MS prevalence in the Faroes following British troop occupation during World
War II.
8. It cannot be transmitted by either person to person contact or
by a blood transfusion.
9. It must be increasingly more widespread and effective over the
last 100 years.
THE MOST REASONABLE INTERPRETATION
FOR THE ENVIRONMENTAL FACTOR WHICH CAUSES MULTIPLE SCLEROSIS
The nine constraints listed above are key to testing if a proposed cause of MS
can be taken seriously or not. Clearly if a proposed cause is not compatible
with one or more of these constraints then it must be rejected as the probable
cause. Only factors which are compatible with all of these constraints can be
considered as a probable cause of MS. All of the environmental factors proposed
as a cause of MS have been compiled and these include specific virus or
bacteria, common virus or bacteria, heavy metal poisoning, industrial
pollution, sanitation, diet, sunlight, altitude, climate (temperature),
microwave radiation and cosmic radiation. These factors can be placed into
three main groups:
indigenous factors: sunlight, atlitude, climate, cosmic radiation,
microwave radiation
infections: specific virus or bacteria, common virus or bacteria
transportable, non-infectious factors: heavy metals, pollution,
sanitation, diet
First of all, the indigenous factors can be readily eliminated on the
basis of the Faroe Islands data. These data clearly demonstrated that the
environmental factor is not indigenous but can be brought into an area (e.g.
the Faroes).
The infectious causes seem to be the most commonly quoted
explanation for the environmental factor. The reason for this appears to
emanate from an a priori assumption that unexplained diseases are caused by an
infectious agent with viruses preferred over bacteria due to their
"difficult to detect" nature. The constraints listed above indicate
that it is highly unlikely that either a specific virus or bacteria which
infects the CNS is responsible for MS. The main reasons for rejecting a
specific infectious agent are:
1. The constraints show that MS is not transmitted either person
to person or through a blood transfusion.
2. The significant variation in MS prevalence and incidence in
ethnically homogenous populations over relatively small areas is hard to
reconcile with a specific infectious cause of MS.
3. No physical evidence of a specific MS virus or bacteria has
ever been found in the CNS of persons with MS despite a very long and concerted
effort to find such material (Poser, 1993).
Before leaving this topic it is important to note that the main
evidence which is usually quoted by those advocating a specific viral cause of
MS is the greatly increased incidence of MS in the Faroes following British
troop occupation. The standard interpretation of these data follows Kurtzke
(1977) and is that some of the British troops were infected with the MS virus
and that they subsequently infected the Faroe islanders. At first glance such
an interpretation seems plausible but a more penetrating analysis of the data,
coupled with other constraints, makes the viral hypothesis of the Faroes
increased prevalence very unlikely.
First of all, there were less than 2000 British troops in the
Faroes and, given the 90/100,000 prevalence of MS in Britain, there were, at
best, 2 troops with MS. Furthermore, given that any soldier exhibiting
neurological disease would have likely been sent home, it is highly unlikely
that there were enough troops to infect the islanders. Kurtzke (1995) has
countered this argument by claiming that many people may be carriers of the MS
virus but not have the disease themselves. There is certainly no evidence of
such a phenomenon and Kurtzke's speculation is unsupportable.
Furthermore, as has been mentioned previously, there is no
increased prevalence of MS in children with step brothers and sisters with MS
or in individuals whose spouse has MS. These data clearly indicate that a
specific viral cause of MS is highly unlikely and that any suggestion that one
or two British troops transmitted a MS virus to the Faroe islanders is entirely
unsupportable.
With the rejection of the Faroe Islands evidence for a viral
cause, the interpretation of a specific virus being the main environmental
factor which results in MS does not appear to be tenable. This conclusion was
also reached by Poser (1993) who stated "the constant failure to confirm
the role of a specific organism in the pathogenesis of MS has raised grave
doubts about its existence".
It has also been postulated that common viral and bacterial
infections cause MS through a phenomenon called molecular mimicry
(Theofilopoulos, 1995b). For this to happen a part of the molecular structure
of the infectious agent must closely resemble part of the molecular structure
of one or more self-proteins in the CNS. Thus when the immune system is
activated against the virus it may also attack the similar self-proteins in the
CNS. In support of this it has been demonstrated that some viruses do have
molecular sequences similar to those of CNS proteins (Wucherpfennig et al.,
1995). Also Sibley et al. (1985) demonstrated a weak correlation between viral
infections and MS exacerbations. However it must be mentioned that in Sibley et
al's study many exacerbations occurred in the absence of infection and many
viral infections did not trigger an exacerbation. Also, as shown by MRI studies
(Lai et al., 1996), disease activity is essentially continuous in many cases
and viral infections certainly are not.
A constraint which strongly indicates that common viral and/or
bacterial infections are not the main cause of MS is the prevalence data for
Japanese and Caucasians in Hawaii. The prevalence of common infections in
Japan, Hawaii and California is very similar, being perhaps highest in Japan
due to high population density. Thus, given that MS is three times more common
in Japanese in Hawaii than in Japan, clearly demonstrates that common
infectious agents are not the main cause of MS. Another constraint which
demonstrates that common infections are not the main cause of MS is the
north/south gradient of prevalence in many areas. The occurrence of common
infections shows little variation within these areas and thus cannot explain
such a pronounced gradient. Other constraints, such as the much higher
prevalence of MS on the Canadian Prairies than in Newfoundland, also argue
strongly against a common virus for the main cause.
Of the transported, non-infectious factors, heavy metals,
industrial pollution and sanitation can also be rejected. The most convincing
constraint for this conclusion again is the greatly increased prevalence of MS
for Japanese living in Hawaii versus Japan where these factors are much more
common than in Hawaii. The Faroe Islands data, as well as the much higher
prevalence of MS on the Canadian Prairies than in the highly industrialized
area of southern Ontario, also are not compatible with these factors.
This leaves us with one remaining factor which is DIET. Diet is
certainly not a new interpretation for the key environmental factor responsible
for MS although it tends to be arbitrarily dismissed by numerous authors.
However a close reading of the arguments against diet leads to the conclusion
that diet has not been rejected on scientific grounds, but rather on rhetorical
ones (e.g. Sibley, 1992) . Statements like "diet has not been proven to
affect the disease (McIlroy, pers. comm., 1993)" and "no controlled
scientific study has proven without doubt that the course of MS can be modified
by dietary changes (Girard, pers. comm., 1991)" are commonly quoted but,
in effect, add nothing to the question of the role of diet. Such statements
really mean "we have no idea if diet plays a role in MS". Notably no
sound scientific argument has ever been presented against the possible effects
of diet. For this analysis, I have looked at diet in the light of the nine
constraints detailed earlier. I have found that diet fits all nine constraints
and thus I currently believe the main environmental factor which is the prime
cause of MS indeed is diet. In regard to the nine constraints:
1. It must be found throughout the world but be specific enough to
affect only half or less of the susceptible individuals.
2. It must affect immigrant children more than it does immigrant
adults. On the other hand it must affect susceptible identical twins mainly
when they are adults rather than when they are children.
3. It must be much more common or effective in northwestern
Europe, Canada, United States, Australia and New Zealand than in the rest of
the world.
4. It must be more common or effective in higher latitude areas so
as to create a pronounced north/south gradient of MS prevalence.
5. It must have enough variation so as to create significant MS
prevalence and incidence differences within ethnically homogeneous populations
over relatively short distances.
6. In Hawaii it must adversely affect those of Japanese origin
whereas at the same time have a positive effect on Caucasians.
7. It must be transportable so as to explain the sudden increase
in MS prevalence in the Faroes following British troop occupation during World
War II.
8. It cannot be transmitted by either person to person contact or
by a blood transfusion.
9. It must be increasingly more widespread and effective over the
last 100 years.
THE MOST REASONABLE
INTERPRETATION FOR THE ENVIRONMENTAL FACTOR WHICH CAUSES MULTIPLE SCLEROSIS
The nine constraints listed above are key to testing if a proposed
cause of MS can be taken seriously or not. Clearly if a proposed cause is not
compatible with one or more of these constraints then it must be rejected as
the probable cause. Only factors which are compatible with all of these
constraints can be considered as a probable cause of MS. All of the
environmental factors proposed as a cause of MS have been compiled and these
include specific virus or bacteria, common virus or bacteria, heavy metal
poisoning, industrial pollution, sanitation, diet, sunlight, altitude, climate
(temperature), microwave radiation and cosmic radiation. These factors can be
placed into three main groups:
indigenous factors: sunlight, atlitude, climate, cosmic radiation,
microwave radiation
infections: specific virus or bacteria, common virus or bacteria
transportable, non-infectious factors: heavy metals, pollution,
sanitation, diet
First of all, the indigenous factors can be readily eliminated on
the basis of the Faroe Islands data. These data clearly demonstrated that the
environmental factor is not indigenous but can be brought into an area (e.g.
the Faroes).
The infectious causes seem to be the most commonly quoted
explanation for the environmental factor. The reason for this appears to
emanate from an a priori assumption that unexplained diseases are caused by an
infectious agent with viruses preferred over bacteria due to their
"difficult to detect" nature. The constraints listed above indicate
that it is highly unlikely that either a specific virus or bacteria which
infects the CNS is responsible for MS. The main reasons for rejecting a
specific infectious agent are:
1. The constraints show that MS is not transmitted either person
to person or through a blood transfusion.
2. The significant variation in MS prevalence and incidence in
ethnically homogenous populations over relatively small areas is hard to
reconcile with a specific infectious cause of MS.
3. No physical evidence of a specific MS virus or bacteria has
ever been found in the CNS of persons with MS despite a very long and concerted
effort to find such material (Poser, 1993).
Before leaving this topic it is important to note that the main
evidence which is usually quoted by those advocating a specific viral cause of
MS is the greatly increased incidence of MS in the Faroes following British
troop occupation. The standard interpretation of these data follows Kurtzke
(1977) and is that some of the British troops were infected with the MS virus
and that they subsequently infected the Faroe islanders. At first glance such
an interpretation seems plausible but a more penetrating analysis of the data,
coupled with other constraints, makes the viral hypothesis of the Faroes
increased prevalence very unlikely.
First of all, there were less than 2000 British troops in the
Faroes and, given the 90/100,000 prevalence of MS in Britain, there were, at
best, 2 troops with MS. Furthermore, given that any soldier exhibiting
neurological disease would have likely been sent home, it is highly unlikely
that there were enough troops to infect the islanders. Kurtzke (1995) has
countered this argument by claiming that many people may be carriers of the MS
virus but not have the disease themselves. There is certainly no evidence of
such a phenomenon and Kurtzke's speculation is unsupportable.
Furthermore, as has been mentioned previously, there is no
increased prevalence of MS in children with step brothers and sisters with MS
or in individuals whose spouse has MS. These data clearly indicate that a
specific viral cause of MS is highly unlikely and that any suggestion that one
or two British troops transmitted a MS virus to the Faroe islanders is entirely
unsupportable.
With the rejection of the Faroe Islands evidence for a viral
cause, the interpretation of a specific virus being the main environmental
factor which results in MS does not appear to be tenable. This conclusion was
also reached by Poser (1993) who stated "the constant failure to confirm
the role of a specific organism in the pathogenesis of MS has raised grave
doubts about its existence".
It has also been postulated that common viral and bacterial
infections cause MS through a phenomenon called molecular mimicry
(Theofilopoulos, 1995b). For this to happen a part of the molecular structure
of the infectious agent must closely resemble part of the molecular structure
of one or more self-proteins in the CNS. Thus when the immune system is
activated against the virus it may also attack the similar self-proteins in the
CNS. In support of this it has been demonstrated that some viruses do have
molecular sequences similar to those of CNS proteins (Wucherpfennig et al.,
1995). Also Sibley et al. (1985) demonstrated a weak correlation between viral
infections and MS exacerbations. However it must be mentioned that in Sibley et
al's study many exacerbations occurred in the absence of infection and many
viral infections did not trigger an exacerbation. Also, as shown by MRI studies
(Lai et al., 1996), disease activity is essentially continuous in many cases
and viral infections certainly are not.
A constraint which strongly indicates that common viral and/or
bacterial infections are not the main cause of MS is the prevalence data for
Japanese and Caucasians in Hawaii. The prevalence of common infections in
Japan, Hawaii and California is very similar, being perhaps highest in Japan
due to high population density. Thus, given that MS is three times more common
in Japanese in Hawaii than in Japan, clearly demonstrates that common
infectious agents are not the main cause of MS. Another constraint which
demonstrates that common infections are not the main cause of MS is the
north/south gradient of prevalence in many areas. The occurrence of common
infections shows little variation within these areas and thus cannot explain
such a pronounced gradient. Other constraints, such as the much higher
prevalence of MS on the Canadian Prairies than in Newfoundland, also argue
strongly against a common virus for the main cause.
Of the transported, non-infectious factors, heavy metals,
industrial pollution and sanitation can also be rejected. The most convincing
constraint for this conclusion again is the greatly increased prevalence of MS
for Japanese living in Hawaii versus Japan where these factors are much more
common than in Hawaii. The Faroe Islands data, as well as the much higher
prevalence of MS on the Canadian Prairies than in the highly industrialized
area of southern Ontario, also are not compatible with these factors.
This leaves us with one remaining factor which is DIET. Diet is
certainly not a new interpretation for the key environmental factor responsible
for MS although it tends to be arbitrarily dismissed by numerous authors.
However a close reading of the arguments against diet leads to the conclusion
that diet has not been rejected on scientific grounds, but rather on rhetorical
ones (e.g. Sibley, 1992) . Statements like "diet has not been proven to
affect the disease (McIlroy, pers. comm., 1993)" and "no controlled
scientific study has proven without doubt that the course of MS can be modified
by dietary changes (Girard, pers. comm., 1991)" are commonly quoted but,
in effect, add nothing to the question of the role of diet. Such statements
really mean "we have no idea if diet plays a role in MS". Notably no
sound scientific argument has ever been presented against the possible effects
of diet. For this analysis, I have looked at diet in the light of the nine
constraints detailed earlier. I have found that diet fits all nine constraints
and thus I currently believe the main environmental factor which is the prime
cause of MS indeed is diet. In regard to the nine constraints:
1. Diet is obviously found throughout the world and it is specific
enough to an individual with given dietary habits to result in MS affecting
only half or less of genetically susceptible individuals.
2. Diet also provides a reasonable explanation of the
immigrant/twin paradox. Adults who immigrate have a strong tendency to maintain
the diet of their homeland whereas their children are far more likely to
consume more of the food of the country they live in (especially once they have
left home). This results in a change of dietary habits and a consequent change
of MS risk in the children but not the adults. Thus the immigration data are
best interpreted in the light of immigrant children and immigrant parents
experiencing different environmental factors in their new country. This is not
surprising because it is well known that immigrant children integrate much more
than do immigrant adults.
Identical twins tend to have very similar diets when they live
together at home but their dietary habits potentially diverge after they leave
home and live apart. Furthermore identical twins can possibly have separate
food sensitivities especially when they are older due to long term intestinal
damage and increased permeability. Thus dietary and digestive system changes
(and MS risk divergence) would occur in twins mainly after age 18. Thus diet
and only diet explains this paradox.
3. The overall diets of the high prevalence areas have certain
features in common including high dairy, cereal grain and saturated fat
consumptions. These are all much higher than in the low prevalence areas. The
great differences in diet between the high prevalence areas and the low
prevalence areas can readily account for the occurrence of two very different
risk areas in the world. It would appear that the foods consumed in high
prevalence areas (e.g. dairy, cereal grains, high saturated fat) are more
effective in causing MS as has been noted in various statistical studies
(Shatin, 1964; Alter et al., 1974; Agranoff and Goldberg, 1974; Malosse et al.,
1992; Lauer, 1994). Shatin (1964) found a good correspondence of MS prevalence
with wheat consumption. Malosse et al. (1992) state "We have studied the
relationship between MS prevalence and dairy product consumption in 27
countries and 29 populations all over the world. A good correlation (p=0.836)
was found; this correlation was highly significant (p<0.001)". This
echoed Agranoff and Goldberg (1974) who almost 20 years earlier had stated
"a geographic predisposing factor in multiple sclerosis ... is directly
related to milk consumption". Alter et al. (1974) found a significant correlation
(0.7) between consumption of animal fats and MS prevalence. Furthermore on the
basis of a recent multivariate analysis, Lauer (1994) concludes "The
second MS- related bundle comprised characteristics ... with dietary variables
(i.e. a diet low in fish and high in dairy products)".
4. Diet is readily compatible with the north/south gradient
because diet varies directly with climate and thus latitude. The diets of
cooler, more temperate regions include much more saturated fat, dairy and
cereal grains which, as discussed above, are the most problematic foods.
5. Significant differences in diet can occur within a given
country and these differences are sufficient to account for different
prevalence rates. For example, the maritime Newfoundlanders consume much more
fish and less dairy and cereal grains than do Canadians on the prairies and, as
noted earlier, they have a far lower prevalence than do the land- locked,
prairie dwellers.
6. Most importantly diet explains the paradox of the adversely
affected Hawaiians of Japanese ancestry and the beneficially affected Hawaiians
of Caucasian descent which Poser (1994) characterized as "puzzling".
The diet of Japanese-Hawaiians includes many more elements of the high risk
diets of Europe and North America (e.g. saturated fats, dairy products, cereal
grains) than does the diet of native Japanese. Thus one would expect a
significantly higher prevalence for Japanese in Hawaii. On the other hand the
diet of Caucasians in Hawaii includes more elements of the low risk diets (e.g.
fish, fresh vegetables and fruits) then does the diet of Caucasians of mainland
North America. This of course would result in a lower prevalence for Caucasians
in Hawaii. Thus it would appear that diet provides the solution for this
puzzling paradox which is inexplicable by other postulated causes.
7. A critical question in this analysis is "Can diet explain
the increased prevalence of MS in the Faroes following British troop
occupation?" As has been discussed it is highly unlikely that the British
brought with them a MS virus but it is clear that they did bring the
environmental factor with them. The obvious interpretation is that they brought
their own food supplies which would have of course included food high in
saturated fat and the foods which most commonly cause hypersensitivity
reactions (dairy, eggs, cereal grains, nuts, legumes). The islanders living
near the bases (and working on them) would have had easy access to these
"non-traditional" foods and added them to their diet. Thus such dietary
changes in susceptible islanders can readily explain the sudden increase in MS.
These imported foods likely became part of the standard diet of many of the
islanders (especially the youth) and this accounts for the ongoing occurrence
of MS in the Faroes. Thus diet does indeed provide a solid and reasonable
explanation of one of the most specific and well controlled pieces of
epidemiological evidence regarding the environmental factor.
8. Diet as the main factor is entirely compatible with the
non-transmissible characteristic of MS as noted by Ebers (1996) who, on this
basis, clearly stated "In sum these data strongly indicate that the
environmental factor is affecting the population risk. Accordingly, factors
which influence large populations such as diet... deserve careful
reconsideration".
9. The diet of the high risk areas (western societies) has changed
significantly over the last 100 years with substantial increase of saturated
fat, a decrease in polyunsaturated fat and an increase in dairy and cereal
grains (Swank and Dugan, 1987). This trend of a higher consumption of these
foods has been significantly accelerated over the past fifty years with the
rise and constant expansion of the "fast food" (e.g. hamburgers,
pizza, donuts) industry. Thus the continued increase of consumption of these
foods readily accounts for the steadily increasing prevalence of MS over the
last 100 years.
PATHOGENESIS OF MS
In the last section the epidemiological evidence for dietary factors
as the main cause of MS was presented. Of course, if diet is the main cause, it
must be demonstrable that specific dietary factors are capable of resulting in
the various known disease processes of MS. In this and the next sections the
basic disease processes (pathogenesis) of MS are reviewed and the theoretical
basis for dietary factors resulting in these processes are presented.
The basic pathogenesis of MS involves the entry of immune cells
(e.g. T-cells, B-cells, macrophages) into the CNS through the walls of the
capillaries and venules (Traugott, 1990; Poser, 1993). Immune reactions occur,
a lesion is formed and myelin is eventually destroyed. Myelin consists of fatty
tissue which wraps around nerve axons. It essentially acts as nerve insulation
and is critical for proper nerve transmissions. Loss of myelin results in
degradation of nerve transmissions and a resultant multitude of disabilities
which gradually worsen over time as more myelin is destroyed.
It is very important to note that in healthy individuals immune
cells cannot pass through the CNS capillaries and venules into the CNS tissue.
This does not happen because the walls of the capillaries in the CNS are
different from those in the rest of the body in that they have very closely packed
cells which do not allow the passage of immune cells. This special feature of
the CNS vascular system is referred to as the blood-brain barrier (BBB)
(Traugott, 1990).
It would seem that an intact blood-brain barrier prevents CNS
infiltration of immune components and thus stops the possibility of MS
occurring. As noted by Compston (1991), one of Britain's leading MS
researchers, "blood-brain barrier penetration can be regarded as the
primary disease process". This is especially true because many people carry
immune cells which are reactive with brain tissue but only a few develop MS. As
explained by Soll (1968) many years ago, "isolation (of the CNS) begins to
take place during fetal life, very likely before the so-called immunologic
"recognition of self" takes place. Thus, at least parts of our brain
may be capable of evoking an immune reaction... provided the immune mechanisms
were allowed direct access to the CNS". Thus almost 30 years ago it was
recognized that a critical disease process in MS is the breach of the BBB and
the exposure of the CNS to autoreactive immune cells. This concept is now
widely accepted and Theofilopoulos (1995b) notes in a recent, comprehensive
review of autoimmune disease "Induction of autoimmune disease, following
contact with antigens of such so-called "immunological privileged"
sites, has been well documented".
This concept has been supported by observations of MS lesions on
MRI scans. On the MRI scans it was observed that the CNS lesions could be
enhanced by using gadolinium-DTPA (Miller et al., 1988; Kermode et al., 1990).
Passage of this substance through the BBB clearly indicated that the MS lesions
in the CNS occur where the BBB has been damaged so that various substances,
including gadolinium, could readily pass through the damaged walls of the
capillaries. Furthermore, Traugott (1990) notes "that MS lesions are
preferentially localized around postcapillary venules" which have a
"relatively low barrier function". This and other evidence led Poser
(1987, 1992, 1993), in a series of watershed papers, to declare in no uncertain
terms "In order for MS to become a disease affecting the CNS, it is
necessary for the blood-brain barrier's impermeability to be altered"
(Poser, 1993, p. 53). Recently, this emphasis on the damage to the BBB as a key
disease process in MS has been confirmed by Lai et al. (1996). Based on a study
of weekly MRI scans in patients, these researchers state that "this
finding suggests that breakdown of the blood-brain barrier is an invariable and
perhaps obligatory event in the development of new lesions".
A second part of MS pathogenesis, which is more controversial, is
the cause and timing of the activation of the autoreactive T-helper cells (a
type of immune cell strongly implicated in MS pathogenesis [Traugott, 1990])
which react to the CNS proteins. Two possibilities have been advanced. One
hypothesis is that the T-cells are activated in the blood outside of the CNS
and these cells then cross the BBB to attack the myelin or other CNS proteins.
The other hypothesis, which has been alluded to earlier, is that the
autoreactive T-cells become activated against CNS proteins after they have
passed through a breach in the BBB and encounter the previously sequestered CNS
proteins.
To me it is most likely that many of the pathogenic, autoreactive
T-cells are activated outside of the CNS. My reasoning for this conclusion is
that MS is just one of many autoimmune diseases and many of the others have
only the presence of a normal capillary wall between the blood and the tissue.
These diseases require activation of the T-cells outside the tissue and, thus,
I believe such a requirement also is the most reasonable assumption for MS.
The cause of the activation of T-cells against CNS proteins
outside the CNS is somewhat problematic. The most widely accepted hypothesis
(Theofilopoulos, 1995b) is that peptides (fragments of proteins) from foreign
antigens which are presented by macrophages (another type of immune cell) to
T-cells may resemble parts of CNS self proteins from a molecular structure
point of view. This is referred to as molecular mimicry as was mentioned
earlier. Experimental data have clearly shown that such a mechanism by both
food and viruses can result in the activation of T-cells against various self
proteins (Singh et al., 1989; Wucherpfennig et al., 1995; Ostenstat et al.,
1995). Thus molecular mimicry would indeed appear to be a critical factor in
the pathogenesis of MS.
In summary, the evidence is strong that a key part of MS
pathogenesis is the activation of autoreactive T- cells both outside and within
the CNS and that persons with MS carry such CNS autoreactive T-cells. These
activated T-cells set in motion a series of immune reactions which results in
myelin being destroyed by various immune elements (e.g. macrophages) (Traugott,
1990). The interested reader is referred to Steinman (1993) for an excellent
review of autoimmune disease in general and multiple sclerosis in specific.
Other articles in the same issue of Scientific American provide a good overview
of immunology.
TYPES OF MS
One related area regarding MS pathogenesis is that of the outward
manifestation of the disease. Most cases of MS start with a relapsing-remitting
(RR) character which refers to short periods when new symptoms appear or old
ones increase (attack or exacerbation) and long intervals when symptoms improve
somewhat or stabilize (remissions). On average it would appear a typical case
involves about one attack a year (Sibley, 1992). Notably it has been found
through MRI studies that lesion forming activity occurs even during remissions
(Lai et al., 1996). Thus in many cases it would appear as if disease activity
is essentially continuous with a waxing and waning character.
In many instances RRMS evolves into secondary progressive (or
chronic progressive) MS where there are no clear relapses and remissions, only
gradual deterioration.
In some cases, MS does not present in a relapsing- remitting
manner but rather gradual deterioration begins at onset. This type of MS is
known as primary progressive MS.
If untreated, RRMS can have a highly variable course in terms of
disabilities although an average rate of decline of one EDDS (a scale for
assessing disability state) level every six years has been documented (Swank
and Dugan, 1987; Sibley, 1992).
Any proposed cause of MS should be able to explain the various
types of MS and the observed average decline rate.
DIETARY FACTORS, MS
PATHOGENESIS AND MS TYPES
As explained in the last section, MS is mainly the result of both
the activation of T-cells against CNS protein and damage to the blood-brain
barrier which leads to infiltration of immune cells into the CNS tissue and
subsequent demyelinization. There are two main components of diet which appear
to be responsible for the activation of T-cells and BBB damage.
The first and perhaps most critical component is food antigens.
Gell and Coombs (1975) described four classes of hypersensitivity which is
defined as "an increased state of reactivity that involves a detrimental
immune response" (Elgert, 1996). Each of these types of hypersensitivity
causes tissue damage through various types of immune reactions (Elgert, 1996).
Type I, III and IV hypersensitivity reactions are relevant to this discussion
of reactions involving food (Sampson, 1991).
Type I is the classic immediate, hypersensitivity immune reactions
which involve the increased production of IgE antibodies upon introduction of
an offending food. This is what is termed a food allergy and the reader is
referred to Lichtenstein (1993) for a comprehensive review of the immune
response of allergens. Note that only this specific reaction is termed allergy
and all other reactions are referred to as hypersensitivities. In brief, an
allergen in the blood, through a complex series of immune responses, stimulates
mast cells and basophils (specific types of immune cells) to secrete various
chemicals and hormones such as histamine, leukotrienes and tumor necrosis
factor. It is well established that the chemicals secreted by the activated basophils
and mast cells can cause a significant increase in the permeability of
capillaries (Lichtenstein, 1993). As stated by Rozniecki et al. (1995),
"mast cells ... can participate in the regulation of blood-brain
permeability". Thus, food allergens are potentially capable of causing
significant, localized, increased permeabilities in the BBB. Activated mast
cells may also play a significant role in demyelinization (Johnson et al.,
1988; Kruger et al., 1990). Kruger and Nyland (1995) summarize these concepts:
"multiple sclerosis arises due to the effect of the various mediators
(histamine and protease) released from the perivascular mast cells after
stimulation by some diet factor". Also of significant importance is that
IgG4 antibodies can also activate mast cells and basophils (Shakib et al.,
1986; Elgert, 1996). The role of IgG4 in pathogenic immune reactions has been
shown by Gerrard el al. (1976) and Rafei et al. (1989). Rafei et al. (1989)
found that only 29% of those with food allergies (as demonstrated by food
challenges) had positive IgE skin tests whereas 91% tested positive for IgG4
and IgE. Furthermore one patient who demonstrated a delayed response to peanuts
had undetectable IgE but markedly elevated antipeanut IgG4. As recently shown
by Bengtsson et al. (1996), non-IgE immune reactions occur in adults due to the
ingestion of common foods such as eggs, milk and wheat. IgG4 may well be
involved in such reactions.
Type III hypersensitivity involves the production of immune
complexes which are formed by the combining of antigens and antibodies. This
type of hypersensitivity is likely responsible for many non-IgE reactions. It
has been established that these circulating immune complexes can have a
pathogenic effect mainly by deposition in blood vessel walls (Cochrane and
Koffler, 1973). This causes inflammation of the vessel walls and greatly
increased permeability. Immune complexes can also result in the activation of
another part of the immune system, complement (plasma proteins), which results
in further damage (Elgert, 1996). Thus the increased production of antibodies
(mainly IgA, IgG, IgE and IgM), due to the introduction of various food
proteins into the circulatory system, can readily result in immune complex
formation, deposition in the vascular system of the CNS, activation of
complement and a resultant damage to the BBB.
Type IV hypersensitivity refers to cell-mediated reactions and
results in the activation of T-cells which then induce an array of damaging
immune reactions. These reactions, like Type III reactions, are delayed and
often occur days after the offending foods are ingested. The mechanisms by
which food antigens induce Type IV reactions are currently poorly understood
although such occurrences (e.g. celiac disease in which cereal grain proteins
cause cell- mediated reactions) are undoubted. As mentioned earlier, one
possible mechanism for foods to induce an activation of T-cells against parts
of the CNS is through molecular mimicry. Food proteins which escape into the
circulatory system are processed by macrophages which then present peptides
(protein fragments) derived from the food protein to T-cells. The molecular
sequencing in these peptides may be close enough to the sequencing of
self-antigens in the CNS (molecular mimicry) to induce T-cell activation
against parts of the CNS. For example it was recently shown that cereal
proteins share amino acid homologies with human joint tissue (procollagen) and
that T-cells from the joints of arthritic patients were activated by these cereal
proteins. Thus molecular mimicry by cereal proteins can result in arthritis
(Ostenstad et al., 1995). It is readily conceivable that various proteins found
in dairy and grains as well as other foods (e.g. legumes, yeast, eggs) have
similar amino acid sequencing as proteins in the CNS.
In summary it is clear that, from a theoretical point of view,
hypersensitivity reactions to foods can result in significant damage to and
increased permeability of the BBB and can also result in T-cell activation against
the CNS. As discussed earlier, such damage to the BBB and activation of T-cells
initiates a cascade of immune reactions to happen in the CNS which results in
chronic inflammation, demyelination and a diagnosis of MS. The interested
reader is referred to the website www.webdirect.net/zeno for a comprehensive
discussion of the relationship of food hypersensitivities and disease.
The second component of diet which likely affects MS progression
is the types and amounts of fats consumed. The three basic types of fat are
saturated, monosaturated and polyunsaturated. The reader is referred to Erasmus
(1993) for a comprehensive, yet highly readable, explanation of fats and oils.
Swank and Dugan (1987) have presented considerable evidence which demonstrates a
relationship between MS and the consumption of saturated fat. This relationship
was also noted by Alter et al. (1974). Swank and Dugan (1987) have suggested
that a high consumption of saturated fat can result in the formation of micro-
emboli. These micro-emboli of fat particles and/or platelets then cause damage
to the BBB which aids the subsequent passage of activated immune cells into the
CNS. Swank and Dugan (1990) provide convincing evidence from a 35 year
longitudinal study of individuals on a low saturated fat diet that such a diet
beneficially affects the progression of MS.
Other workers have hypothesized that a deficiency in
polyunsaturated fats is also a contributing factor in MS (Thompson 1975; Smith
and Thompson, 1977). Clinical trials using supplementation of either omega 6
fatty acids (e.g. sunflower and safflower oil) or omega 3 fatty acids (e.g.
fish oil and flax oil) have shown a moderate benefit of these oils on MS
(Millar, 1975; Dworkin et al., 1984; Bates et al., 1989). It would appear that
these polyunsaturated fats reduce inflammation and are important in CNS cell
growth.
It is quite possible that the actions of the chemicals secreted by
the mast cells and basophils (Type I hypersensitivity), the actions of the
immune complexes (Type III hypersensitivity), and the constrictions caused by
saturated fat-related micro- emboli all work in concert to increase the
permeability of the BBB and to allow the passage of various activated (Type IV
hypersensitivity) and inactivated immune components. The introduction of these
immune cells into the CNS would then lead to various immune reactions against
previously sequestered CNS proteins and the eventual destruction of myelin.
Thus we now have theoretical evidence to go along with the solid epidemiological
evidence that a diet which contains substantial hypersensitive food, a large
amount of saturated fat, and a deficiency of polyunsaturated fat can lead to
the development of MS in a genetically susceptible person.
Dietary factors as the main cause of MS also provides a reasonable
explanation for the different types of MS. For any individual the ingestion of
specific kinds and amounts of sensitive and fatty foods, which potentially
affect the BBB and activate T- cells, will vary significantly with time but can
have a daily effect. This fact, in concert with random infections by common
viruses and bacteria which also affect the BBB and activate T-cells, results in
an ongoing disease process but a randomness in the severity of disease activity
and a consequent relapsing-remitting character for MS.
As the BBB continues to degrade through time, by the daily
irritation by dietary factors and by gradual aging processes, a point is often
reached when ongoing disease activity maintains a relatively high level and
RRMS transforms into secondary progressive MS.
Primary progressive MS is likely a reflection of an individual's
extreme hypersensitivity to various substances combined with high exposure and
a relatively easy path for the antigens to reach the circulatory system. In
such a case almost continuous BBB failure and T-cell activation might be
expected with no periods of relief.
Thus it would appear as if dietary factors do provide a reasonable
explanation for the great variation in presentation and progression of MS.
PERSONS WITH MS AND
HYPERSENSITIVITIES
If indeed food hypersensitivities are a main factor in the cause
of MS it would be expected that persons with MS as a group, would have many
more hypersensitivities than the general public. Soll and Grenoble (1984) noted
that "individuals with multiple sclerosis frequently display a profile of
numerous allergies" (i.e. hypersensitivities). My own experience, through
both personal and internet contacts with persons with MS, has confirmed Dr. Soll's
statement. Food hypersensitivities seem to be very common and this is currently
being demonstrated by ELISA blood tests which test for IgE and IgG4 immune
reactions to 190 foods. Currently 15 of 18 persons with MS who have had such a
test have had numerous, significant food hypersensitivities with dairy, cereal
grains, eggs, yeast and legumes being the most common reactive foods. Given
that it is estimated that between 1 in 50 to 1 in 100 people have significant
food hypersensitivities (Sampson, 1991), if MS and food hypersensitivities were
not related, the chance of a person with MS also having food hypersensitivities
would also be between 1 in 50 and 1 in 100. Current data suggest at least 50%,
if not 75%, of persons with MS have notable food hypersensitivities indicating
that MS and food hypersensitivities are definitely related.
ANECDOTAL DATA
A final area of potential useful data is anecdotal evidence
regarding recoveries from MS or significant positive changes in the course of
MS. Such data are quite rightly regarded as "soft" and by themselves
provide little, if any, good evidence for interpreting the cause of MS.
However, taken from another point of view, these independent accounts of
positive changes in MS progression can provide another test of any proposed
cause. For example, if dietary factors are the main cause of MS, then it might
be expected that diet revision, involving the avoidance of hypersensitive and
high saturated fat food, was a critical factor in many of the documented
anecdotal accounts.
To test this I searched for all the accounts of "MS
recovery" that I could find in the literature, on the Internet, and
through conversations with persons with MS. On the basis of the results of this
investigation it would indeed appear that diet revision is a very critical
treatment for achieving positive results in the halting or significantly
altering the progression of MS. Perhaps the most impressive account of recovery
is that of Roger MacDougall (1980) which is described in "My Fight Against
Multiple Sclerosis". Mr. MacDougall went from being near blind and
confined to a wheelchair to normal health and activity level (for over 35
years) by faithfully adhering to a low fat, food sensitivity-free diet. Other
published "success" stories which used diet revision as the main
therapy include those of Rachelle Breslow, Alan Greer, Judy Graham, Bob
Lawrence, John Pageler and Bryan Forbes. Recently a number of accounts of
recovery have been gathered on a website (www.2cowherd.net/q) by an individual
who himself has recovered from chronic progressive MS (wheelchair confined) to
a normal, healthy lifestyle through diet revision.
Of special interest is a scientific paper (Meyer et al., 1954)
published over forty years ago when "allergy" was seriously
considered as a possible cause of MS. The authors describe 17 case histories of
persons with MS whose symptoms were greatly alleviated by avoidance of
identified food and inhalant "allergies" (non IgE-mediated).
Importantly the authors note that in cases where offending substances were
reintroduced that MS symptoms returned.
In another well known study of diet revision, Swank and Dugan
(1987) reported that 66 patients who reduced their daily saturated fat intake
to less than 20 grams experienced, on average, only very minor deterioration
over 35 years. This result contrasted with 31 patients who did not follow such
a low fat diet and suffered major deterioration during the same 35 year study.
It should be noted that such a low fat dietary regime also resulted in a greatly
reduced consumption of the foods which most commonly cause hypersensitivity
reactions (dairy, grains, eggs). These impressive results are perhaps the best
documented evidence of the beneficial effects of diet revision on the course of
MS.
And what of my son? I had my son tested for food sensitivities on
the basis of the concepts presented herein. He came back with numerous
significant hypersensitivities with dairy products, legumes and eggs being very
problematic. After he began avoiding his offending foods and went on a very low
fat diet, a number of "minor" ailments which had plagued him for
years completely disappeared. These included night sweats, headaches, petechia
(bruising), rhinitis, slight hand tremor and light sensitivity. These ailments
are related to inflammatory reactions and are very common in persons with MS
(Swank and Dugan, 1987). All of his MS symptoms also disappeared and a
subsequent neurological examination revealed no neurological deficits. There is
no doubt that such drastic diet revision has been difficult but my son takes
the philosophical approach of DIET or WHEELCHAIR. This certainly provides the
necessary incentive to faithfully stick to his strict, but absolutely
essential, dietary regime. He has remained in excellent health for the past 15
months.
Notably a number of persons with MS who read the first
"edition" of this essay, which was put on the Internet in early 1996,
have reported significant improvement through diet revision therapy. One
example is Deidre's story which was written by her mother and is transcribed
below.
DEIDRE'S STORY
by Barbara MacLellan
"Deidre contracted MS at age 11 and the hospital put her on
steroids which had a limited benefit. At age 25 she began to deteriorate quite
rapidly: first her vision became distorted and she developed nystagmus. Her
whole body would go into spasm and rigidity; her head and neck then went into
spasm and shook all the time. Her left hand and arm began to shake just as if
she had palsy. Then her right hand began to shake so that she was unable to
feed herself, write or brush her teeth. Deidre was also a wall walker and
needed a wheelchair if she went any distance. Cognitively Deidre was very
confused and unable to continue with her university studies. She was terribly
fatigued. The diagnosis was chronic progressive MS.
In February a plea for help was made on the Internet Newsgroup
alt.support mult-sclerosis. Ashton Embry sent us his essay on MS and suggested
that Deidre immediately stop all dairy, gluten and egg products. We decided to
follow his advice and went a step farther by eliminating gluten, dairy,
chicken, potatoes, sugar, caffeine and aspartame. She mainly ate lots of
vegetables, rice products, lamb, fish and fruit. We had both RAST and ELISA
tests done which confirmed the presence of many significant allergies. Deidre
also began taking various supplements including bilberry, kelp, vitamin B and
C, cod liver oil, efamol and selenium.
Her head shakes stopped first and soon she no longer felt
"stupid and confused". Over the past nine months Deidre has improved
to the point where her arms and hands shake minimally and she is able to cut
her own food. Her body no longer goes into spasm, she is able to write again
and she can walk longer distances without help. Deidre shows gradual
improvement every week and we feel confident that in another year, Deidre will
be nearly symptom-free".
Although the above anecdotal data cannot be regarded as strong evidence
that dietary factors are the main cause of MS, I believe such data are
important for strongly supporting the case for dietary factors which has been
built on referenced epidemiological and theoretical scientific data.
MS AND SPECIFIC FOOD TYPES
It appears that specific types of food are most commonly
responsible for causing various hypersensitivity reactions which lead to MS.
Such foods are dairy, cereal grains, eggs, yeast and legumes. The evidence
supporting this comes from the previously-quoted statistical studies of food
consumption and MS prevalence (e.g. Malosse et al., 1992) and the abundant
anecdotal data (e.g. MacDougall, 1980). As noted by Eaton and Konner (1985)
these food types, as well as substantial saturated fats have been added relatively
recently to the human diet in terms of our two million year evolutionary
history. Our distant ancestors did not consume such foods and did not suffer
from most of the current lifestyle diseases, including MS, which are now common
in Western societies. It would seem that humans are genetically less tolerant
of these "recently" introduced foods which cause a great variety of
health problems (e.g. heart, stroke, cancer, autoimmune) for genetically
susceptible individuals in societies which consume large quantities of them
(Eaton and Konner, 1985).
To me the best explanation for the appearance and steady increase
of MS in Western societies is the continued increase over the last 150 years in
the consumption of the "late, genetically-hard-to-handle" foods such
as dairy, cereal grains, yeast, eggs, legumes and saturated fats. Thus,
although these "late", potentially problematic foods have been
consumed for thousands of years, it is only recently that large quantities have
been ingested so as to exceed tolerance levels for many genetically susceptible
individuals. Later a suggested treatment for MS is put forward and it is based
on the final conclusion of Eaton and Konner (1985) - The diet of our ancestors
is perhaps the best defense against the diseases of civilization.
DIETARY FACTORS AS THE MAIN
CAUSE OF MS
When considering this entire debate it is essential to realize
that diet is basically outside the world of conventional medicine and is rarely
even considered. Thus the subject is commonly either ignored or quickly brushed
off. Furthermore there is not one dime of research money being spent to test
the hypothesis of diet control for MS despite the obvious links between the
two. I would urge anyone with MS to maintain an open mind on this subject and to
consider the foregoing information objectively as possible. From my geological
background I never forget that the theory of continental drift, which is now a
fundamental concept of our science, was suppressed for 50 years (1912-1962) by
the geological establishment. It was simply too threatening to too many careers
of those in power. A diet cause for MS appears to represent a similar threat to
conventional medicine.
SUGGESTED TREATMENT
An effective treatment for MS clearly depends on knowing the cause
of the disease. The treatment which is suggested below assumes that diet is the
main cause of MS onset and progression because it best fits the extensive
epidemiological data base and is theoretically plausible. The treatment has two
components: (1) halting the activation of T-cells against the CNS and reducing
the ongoing damage to the BBB and (2) strengthening the BBB.
Halting T-cell Activation and
Reducing Damage to the BBB
1. The first step in halting T-cell activation and reducing the
continuous irritation of the BBB is the scientific identification of all food
hypersensitivities. There are various methods used to test for food
hypersensitivities (Bateson- Koch, 1994) and each has advantages and
disadvantages The three most reliable methods, which are scientifically based,
are described and evaluated below.
For IgE-mediated, immediate hypersensitivity, the cheapest and
most easily accessible method is skin testing. The main drawback to this method
is that it only looks at one component of hypersensitivity (IgE) and thus, at
best, it provides only very limited data for identifying one's offending foods.
If only such a test is used many major food hypersensitivities may well be
overlooked.
A second method for identifying immune-reactive foods is a blood
test using either a RAST (Radioallergosorbent) or ELISA (enzyme-linked
immunosorbent assay) methodology. Both of these methodologies measure the
amounts of various antibodies produced when a blood sample is challenged with a
given food protein. The ELISA methodology is somewhat more sensitive than the
RAST (Elgert, 1996) and is cheaper to do. Usually both IgE and IgG4 (a subclass
of IgG, the most common antibody type) are measured. In some tests all four
subclasses of IgG are measured. The advantages of this type of test is that it
is non- invasive ("in vitro"), easy to administer, relatively cheap
and can cover most common foods. Also, by measuring IgG4, foods which cause
delayed hypersensitivity (e.g. Type III reactions), are also uncovered. The
disadvantage of such blood tests is that they tend to be only about 80%
accurate and false negatives can occur. Also, because these tests only measure
antibody production, they do not provide direct data on foods causing the
activation of T-cells against the CNS (Type IV reactions). Thus the data should
be regarded as a guide to your food sensitivities with the realization that
others may remain to be identified.
A third method is the use of an elemental diet followed by
individual food challenges. Foods which cause a reaction and result in a
symptom (e.g. headache, stomach ache, numbness, etc.) are readily identified as
being hypersensitive. This methodology, because it involves the body's
reactions ("in vivo") to foods, is perhaps the most reliable method
for identifying foods which cause hypersensitivity reactions. Also foods which
result in all three types of hypersensitivity reactions can be identified. The
drawbacks are that it is very time consuming and potentially expensive. Also
there is some question if MS symptoms consistently become apparent on food
challenges.
Other blood tests which may help uncover foods which cause
damaging immune reactions are the cytotoxic test and a test which measures the
level of immune complexes in the blood. The relationship of the results of
these tests to food hypersensitivities is somewhat debatable but such data are
undoubtedly of some value.
There are a number of unconventional tests available such as
muscle tests and pulse tests. It is difficult to evaluate the reliability of
these tests because there is no theoretical basis for the relationship between
food hypersensitivities and the measured effects and they have never been
scientifically validated. I would suggest such tests not be used in place of
the above scientific tests until more data on their reliability and scientific
basis are obtained.
From my experience I strongly recommend that all dairy, cereal
grains, yeast, eggs and legumes be completely avoided. These are the foods with
the highest potential to cause the activation of T- cells against the CNS. I
would also suggest the use of an ELISA blood-allergy test (see Appendix). It
will detect most food hypersensitivities (Type I, III) and it provides a
quantitative result. As discussed, use of this test in my son's therapy was
very valuable and successful and many others have also found it to be very
informative. The food challenge method can be used subsequently if problems
remain after all ELISA-identified, offending foods are removed from one's diet.
Also one should always be aware of how a given food affects them and eliminate
foods which consistently result in discomfort and minor symptoms (fatigue,
tingling, etc.).
2. As has been discussed, MS is in part due to a leaky BBB caused
by food-induced immune reactions and high intake of saturated fats. One of the
reasons that food-induced immune reactions occur in the circulatory system is
the occurrence of another "leaky" area in the body, a "leaky
gut". A leaky gut refers to increased permeability of the intestinal tract
and results in food proteins being able to pass between intestinal cells into
the circulatory system. This of course sets off the destructive immune
reactions which eventually result in various diseases including MS (Butkus and
Mahan, 1986). Laboratories offer intestinal permeability tests (see appendix)
although I would suggest you save time and money and assume that you have a
leaky gut and take steps to heal it. Increased permeability has various causes
including NSAID (non-steroidal anti-inflammatory drugs) useage, infection,
candida overgrowth, parasites, ingestion of allergic foods, alcoholism, and
trauma. It is important to eliminate the source of the problem (e.g. candida
overgrowth) and to take various supplements to heal and protect the gut. These
include acidophilus, enzymes, fish oil, borage oil and glutamine.
3. Finally, to protect against the formation of damaging
micro-emboli, it is essential to decrease your intake of saturated fats to 15
grams or less a day. In this regard stop eating any margarine and any red meat.
Swank and Dugan (1987) provide much information on saturated fats in foods and
foods to avoid. As noted earlier these authors also present impressive data
from a thirty-five year, longitudinal study which demonstrates the
effectiveness of an ultra-low fat diet (Swank and Dugan, 1990). This study,
which is unique in MS research, was misrepresented and wrongly interpreted by
Sibley (1992).
I would also suggest that you have routine cholesterol level tests
to make sure your low fat diet is effective. If cholesterol levels remain high
you might consider drug therapy to lower the level.
Strengthening the BBB
There is very little literature on possible ways to strengthen the
BBB. Recently an essay on this subject was posted on a web site
(http://spider.lloyd.com/~tstout/articles) by T. Stout. Much of the information
in this section is taken from this excellent contribution.
Experiments with animals have shown that there are three related
chemicals, anthocyanosides, proanthocyanidins and procyanidolic oligomers,
which strengthen the BBB (Robert et al., 1977; Detre et al., 1986). These
chemicals are found in blueberries, cherries, black berries, grapes and the
bark and needles of certain pine trees. They are currently available as
encapsulated supplements called bilberry, grape seed extract and pycnogenol.
These supplements and/or substantial quantities of the above fruits should be
ingested daily to help strengthen the BBB.
The anthocyanosides and proanthocyanidins act as very powerful
anti-oxidants, block enzyme actions and bind with the BBB and it is these
properties which likely result in their beneficial effect on the BBB (see Stout
essay for details). Other supplements which are anti-oxidants (much less
powerful) include vitamin A (cod liver oil), vitamin C (with bioflavonoids) and
vitamin E. These, along with vitamin B complex and vitamin D, should be taken
daily. Calcium and magnesium supplements are also essential and have been shown
to beneficially affect MS progression (Goldberg et al., 1986).
As described earlier, micro-emboli, formed due to high saturated
fat intake, also damage the BBB. As a complementary treatment to the reduced
intake of saturated fats, consumption of polyunsaturated fats should be
increased. Such fats aid in the desegregation of platelets and are important
for cell growth and reducing inflammation. These fats include unrefined
safflower, sunflower and flax oil as well as encapsulated evening primrose oil
and borage oil. It was recently scientifically shown that gamma-linolenic acid,
the key ingredient of evening primrose oil and borage oil, greatly reduced
arthritis attacks (Zurier et al., 1996). Fish also contain valuable
polyunsaturated fats (omega 3 EFA) and should be eaten at least two or three
times a week. Fish oil (e.g. salmon oil) is also available in capsules. Notably
fish oil has been found to be very beneficial in controlling another autoimmune
disorder, Crohn's disease (Belluzzi et al., 1996). The interested reader is
referred to the comprehensive book by Erasmus (1993) which provides detailed
information on the harmful effects of some fats and the beneficial effects of
others.
SUPPLEMENTS
The following list of supplements is suggested for daily
ingestion. The indicated amounts are well below any toxicity levels but should
not be exceeded except on a physician's advice. Graham (1989) provides detailed
rationales for their therapeutic value for MS:
1. up to 300 mg grape seed extract (use pycnogenol or bilberry if
you are sensitive to grapes)
2. 2 grams cod liver oil (includes 5,000 IU vitamin A and 400 IU
vitamin D)
3. 4 grams salmon oil
4. 100 mg of B-50 complex
5. 100 mcg of B-12 (have your B-12 level routinely checked)
6. up to 3 g of vitamin C
7. up to 800 IU of vitamin E
8. up to 1500 mg of calcium depending on dairy consumption (I
strongly suggest no dairy consumption ever)
9. up to 500 mg of magnesium (a good Ca/Mg ratio is 2:1)
10. 25 mg of zinc
11. 50 mcg of selenium
12. up to 5 g of evening primrose oil or borage oil
13. up to 10 g of flax oil (make sure you are not hypersensitive
to flax!)
14. 4 capsules of acidophilus
15. 6 capsules of enzymes (see Bateson-Koch, 1994 for use of
enzymes for relieving food hypersensitivities)
Other supplements which have been recommended as helpful for MS
are co-enzyme Q10, amino acids, lecithin and octacosanol. The acidophilus,
enzymes and various oils are especially important for healing the gut. Graham
(1989) provides details on the use and value of most of these products.
OTHER ENVIRONMENTAL FACTORS AND
POTENTIAL TREATMENTS
I believe it would be naive to think that every single case of MS
had the same cause and that most cases have only a single cause. MS is
basically "an effect", a chronic inflammation and demyelination of
the CNS, and it seems to me a number of environmental factors can in
combination, result in such a condition. For example, it is known that a
bacterial infection can cause chronic inflammation and demyelination but,
because the cause is known, it is called Lyme Disease rather than MS.
Furthermore, in rare cases, measles vaccination has also resulted in chronic
demyelination and once again, because the cause is known, it is not referred to
as MS but rather as chronic rubella encephalitis. Thus MS is basically a catch
all term for chronic demyelination of unknown cause.
As I have discussed in the first part of this essay, dietary
factors are most probably the main (but not the only) cause of most (but not
all) cases of MS. Given this, it is essential to find out through testing if
indeed your MS is caused mainly by food hypersensitivities and high saturated
fat intake. If you avoid dairy, cereal grains, eggs, yeast, legumes and other
hypersensitive food and follow a low fat diet with supplements and the
progression of MS is not abated, then it is likely your MS is mainly caused by
another environmental factor. The factors discussed below are other likely
contributors to MS and, although in most cases they are subsidiary to
hypersensitive foods, they may be major factors in some cases.
Inhalants
Another possible cause of immune reactions which damage the BBB
and possibly activate T-cells are hypersensitivities (type I, III, IV) to
inhalants. IgE, immediate sensitivity reactions to inhalants seem relatively
rare in persons with MS (Oro et al., 1996) but IgG reactions may be more common
and problematic. Once again a blood-allergy ELISA or RAST test which measures
IgE and IgG4 production on antigen challenge for a variety of inhalants is a
reasonable way of determining if this is a major contributing factor to your
MS. If the test is positive for a number of inhalants then once again it is
essential to avoid or greatly lower the exposure to these substances. This
maybe more difficult than for foods but allergists should be able to advise on
various methods of avoidance and reduction. Extreme measures such as moving to
another part of the country may be necessary in rare cases.
Viruses and Bacteria
As discussed earlier common viral and bacterial infections
undoubtedly can affect the BBB and activate T-cells against the CNS. It is very
doubtful if common viral and bacterial infections are the main cause of MS
onset and progression as revealed by the epidemiological data but, in a few
cases, such occurrences may play a major role in progression. In regard to a
bacterial cause of MS the reader is referred to the website,
"ourworld.compuserve.com/homepages/GShannon". Strong antibiotics are
useful in cases where bacteria play a significant role in MS. In general,
strategies to avoid infections should be adopted and any common bacterial
infection should be treated with standard antibiotics as soon as possible.
Minerals such as zinc and selenium, which strengthen the immune
system, may well have value in warding off viral infections (Macknin et al.,
1996). It has also been suggested that herbs such as goldenseal and echinacea
have value in strengthening the immune system (Balch and Balch, 1996). One
problem with these herbs is that they may cause hypersensitivities (goldenseal
is closely related to ragweed) and questions still remain concerning the wisdom
in taking these herbs over a long time period. I would suggest caution in their
use for MS treatment with echinacea perhaps being the safest herb to use to
ward off viruses.
Heavy Metals
Heavy metals can be very toxic to the CNS and thus, in some cases,
may play a significant role in MS onset and progression. One of the most
obvious sources of heavy metal toxicity is mercury in dental fillings.
Currently there is considerable debate on this point and it is difficult to
separate the data from the hype. Replacement of mercury amalgams is very
expensive and may itself cause problems. However there is enough theoretical and
anecdotal data available to indicate that mercury fillings may contribute to MS
progression. If diet revision does not result in an effective halt of MS
progression then it may well be worth the trouble and expense to have the
fillings replaced.
An interesting and insightful study of the effect of toxins on the
CNS concerns the response of 26 women with failed, silicone breast implants
(Shoab and Patten, 1996). "All patients had evidence of disseminated CNS
lesions" and 80% had oligoclonal bands (IgG antibodies) in their spinal
fluid. All the women had "systemic, inflammatory, autoimmune disease with
CNS involvement" which was "triggered by the foreign material
(silicone) in their body". This example clearly indicates that foreign, "antigenic"
material can cause BBB failure and demyelinating immune reactions.
It is worth having a blood test and perhaps even a hair analysis
for levels of heavy metals (see appendix). Chelation therapy can be valuable
for detoxifying when anomalously high levels of heavy metals are detected.
Vaccinations
Poser (1986, 1993) has stated that vaccinations may be an
important factor in MS onset and progression. Given the fact that vaccinations
cause immune reactions it is clear that they may well affect the BBB and cause
CNS inflammation (not necessarily an exacerbation). Poser (1986) provides
references for a number of incidences where vaccinations resulted in MS. The
most reasonable explanation of such occurrences is that the vaccination
provided the final stress on an already embattled CNS. Overall I would suggest
that vaccinations (including the flu shot) be avoided unless they are
absolutely necessary.
Beta-interferon Drugs
Currently three different, but very closely related, drugs which
consist of beta-interferon, a protein (cytokine) secreted by immune cells, are
available for MS therapy (Betaseron, Avonex, Rebif). Clinical trials have
demonstrated that these drugs reduce the number of exacerbations and lesion
forming activity and thus are beneficial for treating MS. A number of immediate
side effects (flu-like symptoms, site reactions) are often associated with
these drugs but in most cases are not intolerable or dangerous. Depression can
be a troublesome side effect and notably 3% of the study group on betaseron
attempted or committed suicide whereas no one in the placebo group attempted or
committed suicide. One major concern in the use of these drugs is that up to
40% of those taking them for up to 3 years develop neutralizing antibodies to
the injected beta-interferon (Thompson and Noseworthy, 1996). The immediate
result of this is that the drug no longer will have any beneficial effect. Of
more concern is the possibility that the produced antibodies will cross-react
with and neutralize the individual's natural beta-interferon. If this happens
the individual's immune system will be severely compromised with likely
catastrophic results. There have been no confirmed reports of such disastrous
cross reactions having occurred. Thus the decision to take these drugs is a bit
of a gamble and I suggest that the pros and cons be thoroughly considered
before deciding to accept such drug therapy.
Copaxone
The latest drug available for treating relapsing- remitting MS is
copaxone which is a synthetic chemical (amino acid copolymer) that resembles
myelin basic protein. It was in development for about 30 years. It is not
certain how the drug works to reduce the number of exacerbations and lesion
activity but the most likely explanation is that it acts as a "decoy"
for the T-cells and antibodies which are activated against myelin. Thus,
instead of attacking the myelin, many immune cells react against the copaxone
(Wolinsky, 1995). The drug seems to be most effective in individuals in the
early stages of MS (minimum disability). A clear understanding of the short and
long term side effects of copaxone has not been achieved. Initial data indicate
the side effects and risks are less than those for the beta interferon drugs.
Myloral and Bovine-Brain
Supplements
Recently the concept of oral tolerance has been suggested as the
basis for MS treatment (Weiner et al., 1993). The main concept is, that by
eating CNS proteins of bovine derivation, an individual desensitizes the immune
system to CNS proteins and causes the development of suppressor immune cells
which inhibit immune action against CNS proteins.
Presently, a Phase III trial, which is testing this treatment, is
going on and the results are expected by mid-1997. The "drug" which
is currently being tested is refined bovine CNS proteins (including myelin
basic protein) and is called Myloral. In reality Myloral is nothing more than a
food supplement which has been patented. To me this therapy, like other
suggested supplements such as grape seed extract, holds promise because it
likely has few side effects and helps to offset the immune reactions associated
with the ingestion of offending foods. The most serious potential side effect
is a hypersensitivity reaction (i.e. oral tolerance is not achieved) to the
Myloral. Obviously immune reactions against ingested myelin proteins which pass
into the circulatory system will likely result in substantial damage to the
CNS. Clearly it will not solve the problem on its own but is a useful addition
to the suggested dietary revisions and other supplements.
It is worth noting that two non-patented, bovine brain products
are currently available, Sphingolin and Ora-brain. Given the above theoretical
basis it might be worth taking one of these products although optimum dosage is
not known. As a caution I suggest you make sure you are not hypersensitive to
this substance. Also there might be a remote possibility of disease
transmission (Creutzfeld-Jakob?) by them.
Overall the oral myelin therapy may turn out to be a very
beneficial therapy in fighting MS for many people and would be complimentary to
diet revision.
OTHER DRUGS
The one therapy method, for which MS societies, MS clinics and
many neurologists provide reasonably up to date information, is drug therapy
(Carter, 1995; Bansil et al., 1995; Van Oosten et al., 1995). A variety of
immunosuppressive drugs is being used to fight MS although results are mixed.
Cladribine and possibly Methotrexate appear to hold some promise for CPMS. For
those who prefer drugs to diet revision and supplements I suggest you discuss
the options and the various side effects with a neurologist.
ALTERNATIVE TREATMENTS
Numerous "alternative" therapies have been suggested to
relieve MS symptoms and to alter the progression. These are all listed and discussed
in Graham (1989) and Thomas (1995). Much anecdotal data are available to
indicate that various alternative therapies have value and are worth
investigating. Of course common sense approaches to health such as adequate
rest, exercise and a reduction of stress are undoubtedly very beneficial.
CURRENT PROBLEMS IN MS RESEARCH
Perhaps after you have read all the preceding information you are
wondering if any definitive research has been done on MS and diet.
Unfortunately no such research is currently being done and very, very little
has been done over the past 25 years. The complete lack of research in this
field is not in the best interests of persons with MS given the obvious and
plentiful theoretical, empirical and anecdotal evidence which has been
available for many years linking MS and diet. Furthermore, this dearth of
research is inexcusable given the great interest the MS community has in the
possible benefits of diet in MS treatment. When this topic is voiced, as it
frequently is, the same line is quoted by medical personnel "There is no
proof diet affects the course of MS". It comes as no surprise that there
is no proof one way or the other because the necessary research has not been
done or even promoted. Due to this neglect the MS community has been left in
limbo with the agonizing dilemma of "to diet or not to diet - that is the
question". Thus the concerns and questions of the persons with MS
regarding diet are going unheeded and this must be rectified.
I would suggest if you really want to know beyond a reasonable
doubt if diet is a significant cause of MS and significantly affects its
progression, then you must lobby the elected officials and directors of your
national MS society. It is essential to realize that the research which is currently
being supported by your MS Society, with money raised on your behalf, will have
very little, if any, impact on your health. This research is almost exclusively
long term, fundamental research (molecular immunology, genetics, etc.) which
will result in no practical applications for decades, if ever. Such academic
research is fine up to a point but the almost complete lack of research of
practical value (e.g. diet research) is not a reasonable balance (50-50 would
be reasonable). For example, here in Canada 90% of research funds are for
molecular and genetic research.
In conclusion, it would seem that the MS community is not being
well served from a research point of view. The main reason for this appears to
be that the officials of the societies are not aware of the large and varied
data base supporting the relationship between diet and MS. It seems only
reasonable that the societies should be promoting and supporting research which
could quite possibly benefit the members in the next five to ten years. Diet
research is of course one area which desperately needs a serious research
effort and I am sure there are others. I urge you to become proactive and write
your Society soon. Let them know you want hard data as to whether or not diet
influences MS and whether or not other alternative therapies are of value.
CONCLUSION
The diverse data sets for MS are all compatible with the
hypothesis that diet is the main environmental factor in the cause of the
disease. Only diet is compatible with the extensive and varied epidemiological
data base. It appears that the activation of T-cells against the CNS by
molecular mimicry initiated by food proteins and the constant irritation and
weakening of the blood-brain barrier by immune reactions caused by food
hypersensitivities and by micro-emboli related to saturated fats eventually
result in the onset and progression of MS. On this basis the best treatment for
MS is to remove the foods which activate the T-cells and which damage the BBB
and to add supplements which strengthen the CNS, the immune system, the BBB and
the gut. One should avoid all dairy, cereal grains, eggs, yeast and legumes,
identify all food hypersensitivities by an ELISA test and remove these
offending foods from one's diet, reduce saturated fat intake to less than 15 g
a day, increase polyunsaturated fat (unrefined oils) intake and take a variety
of supplements including vitamins, minerals and anthocyanosides. Substantial
evidence indicates that a faithful adherence to this dietary regime will greatly
reduce, and may well eliminate, MS exacerbations. Unfortunately, no research is
being done on the relationship between MS and diet despite the very obvious
links between the two. The MS community must become proactive and lobby
National MS Societies to promote and support research which will decide beyond
a reasonable doubt if diet affects the progression of MS. The community must
adopt a comrade-in-arms approach in fighting against MS and insist on
substantial research initiatives which will possibly benefit them in the near
term.
ACKNOWLEDGEMENTS
I would like to acknowledge the great help and support I received
from my wife Joan and my sons, Matt, Dean and Duncan, during the compilation of
this research. Irwin, Cathy, Joel and Michael kindly critically read the
manuscript and offered many valuable suggestions for improvement. Billie Chiang
expertly processed the manuscript. Many persons with MS have shared their
stories and their test results and this has provided me with much more insight
into a very frightening and sometimes devastating disease. I would especially
like to thank Barbara McLellan in this regard. Dave Q, Aapo Halko and Jean
Sumption have kindly placed this essay on their terrific websites and I am
grateful for their generosity.
This essay is dedicated to the memory of Roger MacDougall who
defeated MS through logic, intuition and dedication to his dietary program.
APPENDIX
Books
1. An absolute must-read is Multiple Sclerosis - a self-help guide
to its management by Judy Graham 2nd edition 1989. Published by Healing Arts
Press. One Park Street, Rochester, Vermont 05767. A 3rd edition (1993) is
available only in England, Contact MSRC 4a Chapel Hill, Stansted Essex, UK CM24
8AG. This book contains excellent discussions of various therapies used to
combat MS.
2. The Multiple Sclerosis Diet Book by R.L. Swank and B.B. Dugan,
1987. Published by Doubleday & Co. Garden City, New York. This book
promotes the ultra-low fat diet and has much useful general information. The
data demonstrate the lack of decline of numerous patients who were on the
ultra-low fat diet for 35 years.
3. MS Something Can Be Done and You Can Do It by R.W. Soll and
P.B. Grenoble, 1984. Contemporary Books, Chicago. A good book for the role of
food allergens and MS.
4. My Fight Against Multiple Sclerosis by R. MacDougall, 1980. A
pamphlet available from Regenics Inc., Rt. 10, 2660 Touby Road, Mansfield Ohio
44903, Telephone (419) 756-2994 (Cost $2). An excellent account of the permanent
remission (40 years) achieved by using an allergy-free, ultra low fat diet.
5. New Hope Real Help for those who have Multiple Sclerosis by
John Pageler, 1987. A booklet available from the author 6200, 102 Terrace N.,
Pinellas Park, FL 33782 (cost $9). Another inspiring personal account of
avoiding MS progression through diet revision.
6. Fats that Heal, Fats that Kill by Udo Erasmus, 1993. Alive
Books, 7436 Fraser Park Drive, Burnaby, British Columbia, Canada V5J 5B9. A
comprehensive account of the relationship between saturated fats and lifestyle
diseases such as multiple sclerosis.
7. Allergies-Disease in Disguise by C. Bateson-Koch, 1994, Alive
Books, Burnaby, B.C., Canada. An excellent review of allergy with suggestions
for reversing the condition.
Web Sites
There are numerous valuable web sites which contain an abundance
of information on MS. Many are linked and thus, with only a few to start with,
one can end up visiting many sites. Below are a few excellent sites which are
worth the visit. They will also lead you to many other connected sites.
Notably, by far the best sites have been set up by persons with MS.
http://www.helsinki.fi/~ahalko/ms.html
The last site is especially useful because it contains a great deal
on information on the relationship between food hypersensitivities and disease
as well as much general information on other causes of hypersensitivity.
Also of great value is the Internet newsgroup
alt.support.mult-sclerosis
TESTS
1. Blood Allergy Test by ELISA Absolutely essential for
establishing your food sensitivities. Available from
Meridan Valley Clinical Laboratory
515 W. Harrison St.
Kent, Washington 98032
Tel: (206) 859-1135
Fax: (206) 859-8700
Two food panels covering 190 foods available (approximate cost
$125US). If you have trouble finding a doctor who will do the test for you,
phone or fax the laboratory and they will likely be able to give you the name
of a physician in your area who will arrange the test.
2. Intestinal Permeability Increased permeability can result in
macromolecules, toxins and antigens crossing the intestinal barrier into lymph
and circulatory systems. These particles trigger an immune response. It is very
useful for MS patients to determine if they have a "leaky gut" and if
so, take the proper steps to reverse the condition. Available from
Great Smokies Diagnostic Laboratory
18A Regent Park Blvd.
Asheville, North Carolina 28806
3. Candida Analysis Candida overgrowth can result in greatly
increased intestinal permeability and food hypersensitivities and is very
common in MS patients. This condition should be reversed if present. Available
from
Antibody Assay Laboratories
1715E Wilshire #715
Santa Ana, California 92705
Tel: (714) 972-9979
4. Whole Blood Elements Heavy metals can, although rarely, play a
role in MS. Mercury from dental fillings may cause severe problems. Iron
deficiency has also been implicated in MS. Available from
Doctor's Data Laboratories
170 W. Roosevelt Rd.
West Chicago, Illinois
Toll free: (800-323-2784)
Fax: (708) 231-9190
Hair Multielement Analysis also available.
Doctors in Calgary
Very few doctors believe in anything except prescription drugs for
MS. In Calgary the doctor most open to alternative treatments for MS and the
need for the above tests is:
Dr. Bruce Hoffman
202, 4411-16th Ave. SW
Calgary, Alberta
Tel: (403) 286-7311
Fax: (403) 286-4767
Author
Ashton F. Embry
3303-33rd St. NW
Calgary, Alberta
Canada T2L 2A7
Voice: 403-292-7125 (office), 403-282-0028 (home)
Fax: 403-292-4961
Email: [email protected]
(office)
[email protected] (home)
Please feel free to copy and distribute all or parts of this
essay. An electronic version is available upon email request.
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