Two
devastating pathological syndromes
affecting nerves are Multiple Sclerosis
and Myasthenia Gravis. To adequately
understand the significance of these
diseases, one must have a working
knowledge of fatigue, normal and
abnormal. The phenomena of fatigue
according to Starling’s Principles of
Human Physiology has been recognized for
years to depend on two factors: l)The
consumption of the substances available
for the supply of potential energy to
the contractile material; 2)The
accumulation of products of the
contractile process. We must consider a
third: The inability to use available
energy-producing substances because of
distribution roadblocks.
Two general
locations for normal fatigue are: 1) At
the synapsis, the delicate junction
between neuron and neuron recognized as
highly susceptible to fatigue; 2) The
junction between motor nerves and the
fibers of skeletal muscle, made possible
by motor end plates. Synaptic fatigue
and endplate fatigue occur in such
minute structures that quick recovery
seems always possible. We must
recognize, however, that although the
feeling of fatigue may apparently be
quickly dissipated, actual restoration
of the fatigued structure will require
much time.
When a plant
is fatigued it wilts; unless relieved of
the fatigue, it dies. Proper atmospheric
conditions, proper soil, or these
equivalents conferred by man will
restore, to some degree, the faltering
plant. Even prayer has been advanced as
an active agent to not only relieve the
failing plant of its fatigue, but also
to encourage its growth. Plants do
indeed have a soul - the soul of growth.
This predicates a potential capable of
responding to kindness of various types.
In this light, then, people with “green
thumbs” are nothing more than accepted
plant missionaries. When an animal is
fatigued, it usually follows an innate
faculty supplied by Nature and rest.
When sick, like the dog, it will eat
grass to relieve the gastric complaint.
The dog’s master can go further and
supply various drugs or vaccines to
either cure the malady or to prevent
several types of illness from ever
coming into existence. Animals have not
only a soul for growth like the plant,
but also a soul of sensation. Proper
rest, proper drugs and proper food,
along with understanding, will secure
for the dog mental and physical
relaxation, thus assuring the animal a
more serene and longer life as compared
to a dog running loose on the streets or
in the wild, and required by
circumstances to scavenge for itself.
Man has been endowed by his Creator with
a soul for growth, like the plant; a
soul for recording sensations, like the
animal and what is truly a heavenly
gift, a soul for reasoning intellect.
Shakespeare, through Hamlet, had this to
say of man: “What a piece of work is
man! How noble in reason! How infinite
in faculty! In form, in moving, how
expressed and admirable! In action, how
like an angel! In apprehension, how like
a god! But Hamlet concluded with this
question: “What is this quintessence of
Dust?”
It is a
common experience to obtain marked
relief from physiological fatigue by
taking a short nap, often called “Edison
cat nap”. An ordinary night’s rest is
none too long for recovery from fatigue
created by a day’s labor. The almost
universal habit of abstaining from
ordinary duties one day out of seven has
real significance. It is the
acknowledged necessity of allowing at
intervals longer period for restoration
than the usual nightly ones in order
that accumulative fatigue will not be
experienced. Work is labor and so is
play. There is a real and significant
difference between being pleasantly
tired and being fatigued. The
sharecropper working in the field, where
fresh air abounds can easily expend far
more energy than one who works in a
poorly ventilated factory, yet the farm
worker will register relative fatigue
compared to the factory worker who often
will be physiologically exhausted. This
suggests that oxygen plays an important
role in the production of fatigue.
In the
laboratory, one can demonstrate that
repeated stimulation of striated muscle
diminished the force of the contraction
and that indefinite repetition of such
stimulation will so exhaust the muscle
that eventually it will fail to
response. The fatigue which is here
observed can be due either to the
exhaustion of the glycogen and the
hexose phosphates or to the accumulation
of lactic acid within the muscle.
Contraction is essentially anaerobic
process. Lactic acid production, the
fundamental chemical reaction producing
energy for muscle contraction, does not
require oxygen. Such energy-yielding
reactions of partial decomposition, not
requiring oxygen, are called
fermentations. Muscle then, obtains
energy incidentally of its immediate
oxygen supply by the rapid fermentation
of glycogen to lactic acid, in the same
way a brewer’s yeast derives one energy
by the fermentation of sugars to
alcohol. This anaerobic explosion of
energy is akin to jet propulsion, and
similarly, its potential is limited.
Ultimately, muscle requires oxygen for
the maintenance of normal irritability,
for oxidative energy production, and for
the restoration of its anaerobic
energy-yielding system. Muscle action
and muscle fatigue is indeed a very
complex chemical system. Such units as
phosphocreatine, adenosine triphosphate
and calcium and magnesium ions deserve
limited explanation. Eagleston and
others, independently, discovered that
most of the creatinine in muscle is in
labile combination with phosphoric acid.
The free creatine which occurs in muscle
fatigue in proportional to the amount of
phosphocreatine which is decomposed.
Creatine is derived in the body from the
amino acids Arginine and Glycine, plus a
labile methyl group. According to
Cameron and Gilmour creatine, in acid
solution, readily loses water to give a
ring compound, an internal anhydride,
creatinine. Creatinine is a constant
constituent of urine, and its amount is
sometimes increased in the later stages
of nephritis and always in Myasthenia
Gravis. The simplest conception of
creatine-creatinine metabolism is that
creatinine is formed from creatine
during periods of muscular activity when
creatinine is transiently free in muscle
and then passes by way of the blood,
without change, into the urine. Creatine
phosphate breaks down in the presence of
adenosine diphosphate (ADP) to form
adenosine triphosphate (ATP). Creatine
phosphate acts as the immediate energy
source for the synthesis of adenosine
triphosphate for relatively short
periods during bursts of contractile
activity. The usable life of creatine
phosphate is limited. Once it is used
up by muscle action, the muscle must
then rely on the adenosine triphosphate
(ATP) which is synthesized during the
chemical activity of the Krebs cycle in
glycolysis. Adenosine triphosphate is
the essential high-energy package, and
it is responsible for delivery of
necessary power for the activation of
all cells; it is the basic energy unit
for life. During muscle relaxation
phase, some of the adenosine
triphosphate reacts with creatine to
form creatine phosphate at the expense
of adenosine triphosphate which is
reduced to adenosine diphosphate (ADP):
a low-energy package. This change of
reactions continues until such a
situation exists when muscle cells can
no longer synthesize ATP due to lack of
oxygen and essential substrates. When
this happens, a state of muscle rigor
mortis exists. Frequently, Myasthenia
Gravis patients experience minimal rigor
mortis; sometimes no adenosine
triphosphate is available and so actual
death.
We must
briefly discuss still other phases of
muscle activity. The filaments in
skeletal muscle are composed primarily
of the proteins actin and myosin. Small
amounts of other proteins play important
roles in the contractile cycle. Part of
the energy for movement comes from the
splitting of adenosine triphosphate by
the myosin molecule. Actin increases the
ability of myosin to split adenosine
triphosphate. Magnesium ions and
calcium ions are also necessary in
muscle action. Besides actin,
tropomyosin and troponin are responsible
for the effects of calcium on the
contractile apparatus. One must also
consider the part played by
acetylcholine and its esterase in muscle
activity. Too much or too little of
these substances prevents or slows down
muscle action even when all other
factors are within normal limits. The
neuromuscular junction potential can be
modified by drugs and disease. One such
drug is curare. Curare merely occupies a
reactive site so that acetylcholine is
prevented from interaction with motor
end-plates. Myasthenia Gravis is a
disease whereby too much pyruvic acid (pyruvates),
due to faulty metabolism, affects the
interaction of acetylcholine at the site
of the motor end-plates at the neuro-muscular
junction. In Multiple Sclerosis, the
sluggish and sometimes bizarre muscle
activity is due to absence or inability
to utilize essential factors because of
mechanical and chemical roadblocks.
Like nerve
action potential, muscle action
potential is an all-or-none event, the
overall effects of motor unit
recruitment depends upon the anatomical
relationship between the contracting
units. Specifically whether the fibers
are in series or parallel. When linked
in parallel by connective tissue, the
force generated by each fiber is
additive, producing a total force
proportional to the number of fibers
contracting. When the fibers are in
series, the total force is equal to that
generated by a single fiber no matter
how many fibers fire simultaneously.
These relationships exert quite a
different effect on the degree and
velocity of shortening. No matter how
many fibers in parallel contract
together, the amount of shortening and
velocity are the same as when a single
fiber contracts but both the degree and
the velocity of shortening are
proportional to the number of
contracting fibers in series. Long
muscles shorten more and faster than
short muscles. Thick muscles exert more
tension than thin muscles. These
differences, however, disappear when the
values are expressed per unit length and
cross-section area. The total range of
length changes a muscle can undergo
while attached to the bone is much less
than the changes that would cause the
active tension to fall to zero. Muscle
exerts a force on the bones to which
they are attached through tendons. As
muscle shortens, it exerts only a
pulling force called flexion. Opposing
muscles straighten the unit flexed which
is known as extension. This review on
muscle action and fatigue is,
apologetically, very elementary, but
sufficient to establish a basic
understanding of what is happening in
the pathological conditions entertained
in this treatise.
These
physiological processes battling
fatigue, as enumerated, are such that
the sudden expenditure of a large part
of the potential energy of the muscle,
by the conversion of glycogen to lactic
acid, does not mean a permanent loss of
glycogen capital. This is so because
one-fifth of the lactic acid produced is
subsequently completely combusted.
Paradoxically, this re-yields energy
which is sufficient to convert
four-fifths of the lactic acid produced
back to glycogen. The grade of muscle
effort, which an individual can endure
before reaching his fatigue point, is
governed by his capacity for absorbing
oxygen and discharging carbon dioxide
during respiration. Each of us is
absorbing some 200cc to 300cc of oxygen
per minute. If we should suddenly start
to run for a bus, or climb several
flights of stairs, the amount of oxygen
required might rise to 2,000cc to
3,000cc and even 4,000cc. One liter of
oxygen will remove seven grams of lactic
acid. The individual who can absorb four
liters of oxygen per minute can endure
the production of twenty-eight grams of
lactic acid per minute by his muscular
effort. This tells us that our
ventilating system must be in grade A
condition. Anything such as smoking, or
even chronic sinusitis will have a
detrimental effect on neurological
diseases, and supportive treatment along
these lines must also be entertained if
success is the desired end point.
There are
other types of fatigue besetting man.
Mental fatigue can best be considered in
the light of active and passive. Passive
mental fatigue represents that type of
medical syndrome which includes such
symptoms and signs as “brain lag”,
sensations of pressure in the head, poor
memory, loss of power of concentration,
irritability of temper, increased
reflexes, insomnia, anorexia and a
general variety of aches and pains - the
classical syndrome of neurasthenia.
Active mental fatigue is elicited by
continuous work and is proportional to
the duration and difficulty of the task
performed. The effects are manifested by
lessening in feeling, in tone, in output
and in organic change. The organic
change is small compared to that from
equivalent periods of heavy muscular
work. Most of this change can be
attributed to the sensory-motor rather
than to the neural element of the mental
work. Mental performance is never
perfectly continuous, but is alternated
with pauses, which become longer and
more frequent in proportion to the
length and difficulty of the task
performed. The effects are accumulative
in that they are transferable from one
task to another in proportion to the
tasks similarity. Total sleep during a
day off is not necessary, since the
primary area of this phase of fatigue is
the synapses which beg only diversion of
interest and activity - something
foreign to one’s usual occupation. In
this manner, the fatigued synapses can
rest while others are busy.
Chemical
fatigue represents one of the major
groups of internal medicine. Passive
chemical fatigue represents that group
which makes itself known through body
lassitude following the administration
of a chemical compound. This group of
compounds is represented by the
soporific drugs, the analgesics, the
many tranquilizers, and those which
lower blood pressure. One must guard
against seemingly harmless chemicals.
Sodium bicarbonate, for example, is
capable of rendering hemoglobin less
capable of normal oxygen surrender to
tissues. Sodium bicarbonate can take up
as much as 70% of the available oxygen.
The immediate result of this anoxia is
weakness, even collapse; the remote
effect is tissue breakdown. Sodium
bicarbonate can mimic the action of
carbon monoxide. This gas, as you know,
combines with reduced hemoglobin,
displacing oxygen from oxyhemoglobulin
to form the specific compound
carboxyhemoglobin. Proper doses of
ascorbic acid will prevent or relieve
this syndrome. It is good to remember
that monoxide poisoning can exist from
many sources other than auto exhausts.
Smoke poisoning from fires is nothing
other than monoxide poisoning, and
carboxyhemoglobin blood levels up to
seven percent have been reported in
cigarette smokers. This can be serious,
especially in a patient with a
neurological pathology. Patients with
Myasthenia Gravis and Multiple Sclerosis
will not make progress if they use
tobacco. There are other reasons against
the use of tobacco. The hypnotic effect
of carbon monoxide may act in a
synergistic manner with other factors
operative in ischemic heart disease,
outstripping the limited coronary
reserve and augmenting the production of
stress-induced myocardial ischemia. (I
need not remind you that adequate
ascorbic acid intake will also “handle”
this situation.)
Active
chemical fatigue represents that type of
exhaustion which results from the
breakdown or inability to handle the
normal physiological processes in the
body. A classical example of this is
Myasthenia Gravis. Before the advent of
Prostigmin, Mestinon and Mytelase, all
those who have had this disease have
died unless favored with spontaneous
remission and one special type of
treatment which will be outlined later.
The physostigmine class of drugs inhibit
the action of cholinesterase. They also
have a direct effect on muscle fibers,
on neurons and on ganglion cells of the
central nervous system, much like jumper
cables on an automobile, or like a
cardiac pacemaker. Their action is
limited. Although the etiology differs
markedly, Multiple Sclerosis is also the
end result of an active chemical
problem.
From any
textbook of physiology, one might read
concerning the metabolic pathways. The
sequence of enzyme-mediated reactions
leading to formation of a particular
product is known as a metabolic pathway.
When dealing with glucose it is termed
glycolysis. The primary function of
carbohydrates in the body is to provide
a source of chemical energy. The
metabolic pathway for glucose
degradation to carbon dioxide and water
is divided into two parts: l) Involves
the breakdown of glucose to pyruvic acid
or lactic acid; 2) Conversion of pyruvic
acid to carbon dioxide and water in the
presence of oxygen. Whether the end
product of glycolysis is pyruvic acid or
lactic acid depends upon the supply of
oxygen in the cell. When the oxygen
supply is adequate, pyruvic acid is
formed; conversely an inadequate oxygen
supply will lead to lactic acid
formation. These are generally referred
to as aerobic and anaerobic glycolysis.
Adequate oxygen can be made available
not only through a high rate of gas
exchange in the lungs, assuming that the
pulmonary function tests are within
normal limits, but also by taking 10 to
30 grams ascorbic acid by mouth every 24
hours. Oxygen from vitamin C becomes
available through the loss and eventual
breakup of water in the reaction of
ascorbic acid to dehydroascorbic acid.
We reported this chemistry in several
papers dealing with the use of massive
doses of vitamin C in Monoxide
poisoning. Enzymes are also necessary in
making the glucose reactions possible.
Many pathological conditions in man can
be traced to faulty enzyme production.
This is usually due to genetic fault.
Food,
regardless the kind, must be reduced to
glucose if it is to be used to produce
energy. We have already implied that
only glucose can undergo glycolysis,
which produces as one type end point,
pyruvic acid. Pyruvic acid is a critical
agent in Multiple Sclerosis, because it
is the starting component of the Krebs
Cycle. Each step in glycolysis, that is,
the change in chemical structure
occurring along the pathway to pyruvic
acid from one molecule to the next is
relatively small, but the total sequence
of reactions alters the structure of
glucose dramatically. Biochemists record
that in the first glucose reaction, one
of nineteen, the phosphate from
adenosine-5-triphosphate (ATP) is
transferred to glucose to form
glucose-6-phosphate. In the third
reaction a second molecule of
adenosine5-triphosphate (ATP) is used in
the transfer of phosphate to
fructose-phosphate. Two molecules of
ATP, the key power source for life,
being utilized in getting to fructose 1,
6-diphosphate, but eventually four
molecules of ATP are formed resulting in
a net gain for the cell of two
Adenosine-5-triphosphate molecules.
During glycolysis reaction number six,
additional ATP molecules are synthesized
from or by way of the coenzyme
nicotinamide adenine dinucleotide plus 2
hydrogen atoms (NADH2) by the process of
oxidative phosphorylation. This,
however, cannot occur without oxygen
since in the reaction NADH2 is reduced
to NAD by transfer of the hydrogen atoms
and electrons to the cytochrome system.
Fortunately, adenosine-5-triphosphate
(ATP) can be synthesized by direct
substrate phosphorylation occurring
during anaerobic glycolysis.
Adenosine-5-triphosphate (ATP) provides
the ionized phosphate groups that trap
the intermediates within the cell and
forms the intermediate structures
required for the later stages of
glycolysis. It is important to recognize
that all the intermediates between
glucose and pyruvic acid contain an
ionized phosphate group and that ionized
molecules are generally unable to cross
the lipid barrier of a cell membrane.
Once glucose has been phosphorylated,
the intermediates of glycolysis are
trapped within a given cell. Glucose
enters the cell through a
carrier-mediated facilitated-diffusion
system. The amount of energy transferred
to ATP is roughly five percent of the
total potential of glucose. Thus, 95
percent of the ATP synthesized from the
energy released from glucose depends
upon oxygen and the oxidative
phosphorylation occurring in the
mitochondria. This gives us notice
concerning the importance of good
ventilation practices to maintain a high
degree of vital capacity. It also argues
for high daily intake of vitamin C.
Most of the
reactions of the tricarboxylic acid
cycle (Krebs Cycle) are reversible, but
the reaction in which pyruvic acid is
converted to acetyl co-enzyme A and
carbon dioxide is irreversible. It is
true that all chemical reactions are
theoretically reversible, but some are
limited to the plant kingdom. For
example: Carbon dioxide and water can
react to form glucose and oxygen,
reversing the reaction which led to the
breakdown of glucose, but to make it
work in this reverse direction, the same
amount of energy (685kcal) released
during glucose glycolysis must be
returned to the molecules of carbon
dioxide and water. This actually
happens, as you know, in plant cells
through a process called photosynthesis,
where the energy is obtained from
sunlight. Pyruvic acid, which comes
from phosphoenolpyruvate, the last step
in glycolysis, and which cannot be
reversed once acted upon by coenzyme A
to form acetyl coenzyme A, can be
produced by direct decarboxylation of
oxalacetic acid. Pyruvic acid from this
source can be phosphorylated in the
presence of ATP to form phosphopyruvate,
and this can then serve as a direct
precursor of the hexoses and glycogen by
the reversal of the glycolytic system.
Pyruvic acid (plus CO2), according to
Ochoa, can be “shuttled” into the Krebs
cycle through malic acid when this
compound is reversibly oxidized and
decarboxylated using triphosphopyridine
nucleotide (TPN) as hydrogen acceptor,
and catalyzed by malic enzyme. We
mention these chemical routes for
pyruvic acid since it plays a very
important part in Myasthenia Gravis. The
reversibility of the decarboxylation
reactions in the Krebs cycle enhances
the importance of the mechanism of CO2
fixation by animal tissues. CO2 fixation
implies the utilization of carbon
dioxide for metabolic purposes. As noted
in any text of physiological chemistry,
the assimilation of CO2 by green plants
during photosynthesis leads to the
formation of phosphoglyceric and
phosphopyruvic acids, and that malic
acid is a subsequent product of the
reaction. One can speculate that the
fundamental processes of CO2
assimilation known for plants can also
be assigned for man.
There is
evidence sufficient to believe that
coenzyme A, which is the physiologically
active form of pantothenic acid in
animals, is in limited supply in
Myasthenia Gravis. This special enzyme
is chemically situated at the gateway to
the Tricarboxylic Acid Cycle where it
“intercepts” pyruvic acid at the end
point of glycolysis The absence or
reduced supply of this coenzyme is
actually due to the absence or reduced
supply of cocarboxylase. When it is
present, it not only splits the carboxyl
group (COOH) away from pyruvic acid to
form CO2 and “free” H; with the “H”
being positively ionized, but it also
bonds or joins the remaining two carbon
fragments of pyruvic acid, known as
active acetate, to form acetyl coenzyme
A. This leaves the low-energy package
niacin-adenosine-dinucleotide (NAD) free
to pick up two molecules of hydrogen.
(At one time it was thought that the
low-energy package was diphosphopyridine
nucleotide (DPN), but through the
employment of radioactive isotopes and
the electron microscope, this was proved
to be in error.) One molecule from the
carboxyl group of pyruvic acid, and the
second molecule from the sulfur group of
coenzyme A, makes a high-energy package
with the “call letters” NADH2. One
method in getting coenzyme A from
pyruvic acid, which has been established
for heart tissue by Koroes et al, is the
reaction between pyruvic acid, coenzyme
A, and diphosphopyridine nucleotide (DPN
or coenzyme I), in the presence of
diphosphothiamine which is
cocarboxylase. There are other important
low-energy packages operative in this
system and necessary for good health.
Flavinadenosine-dinuclectide (FAD) picks
up two molecules of hydrogen to form the
high-energy package FADH2 and adenosine
diphosphate (ADP). Adenosine diphosphate
picks up available P04 radicals to form
adenosine-5-triphosphate (ATP).
In dealing
with muscle and nerve pathology, the
metabolism of lipids and protein must
also be considered, although in a lesser
degree. There is a close relationship
between neutral fats and glucose
metabolism. The neutral fats, consisting
of three fatty acids attached to the
three-carbon molecule glycerol,
constitutes the majority of the lipid in
the body. The breakdown and synthesis of
neutral fats is closely associated with
the metabolism of glucose because of the
formation of intermediates common to
both pathways. The breakdown of fatty
acids requires coenzyme A and hydrogen
carriers such as niacin-adenosine-dinucleotide
(NAD). Ascorbic acid can operate as a
hydrogen transport in cellular
oxidation, thus facilitating these
reactions. The starting point for fatty
acid synthesis is acetyl coenzyme A. In
the diseases in which we are concerned,
myelin is very important. Myelin is a
fat-like substance forming the principle
component of the myelin sheath of nerve
fibers. It is composed of cholesterol,
certain cerobrosides, phospholipids and
fatty acids.
Protein
metabolism is far more complicated than
lipid or carbohydrate metabolism.
Proteins are formed from twenty
different amino acids, all of which have
different chemical structures and
require different pathways for their
synthesis and degradation Synthesis of a
protein molecule from amino acids
involves more than the formation of
chemical bonds between amino acids. The
amino acids must be placed in a precise
sequential order. Unlike fats and
sugars, amino acids contain nitrogen in
addition to carbon, hydrogen and oxygen.
It is more than of academic interest to
know that thiamin hydrochloride is a
pyrimidine compound: thus containing
nitrogen, like amino acids. Because of
this amine factor, Funk originally
spelled vitamin with an “e” - vitamine.
“Vit” comes from the Greek “vita”,
meaning life, and E amine for the
nitrogen factor. Since only thiamin
hydrochloride of all vitamins had this
factor, the “e” was dropped, and the
name vitamin retained for symbolic
reasons. Although all amino acids are
important, some more than others, and
still others necessary for the
continuance of life, the one we are
interested in is the amino acid glycine.
Glycine is noted for its specific
dynamic action. Bodansky states that not
only does the body use any preformed
glycine that may be present either in
the diet or in the tissues, but it is
forced, at times, to synthesize this
amino acid in large amounts. The
conversion of glycine into sugar in the
animal body has been well documented.
Rapport and Kats have shown that when
glycine is added to perfused muscle, the
oxygen absorption is 40 percent higher
than otherwise, indicating that the
presence of the amino acid glycine
stimulates the combustion of other
tissue constituents. Glycine with the
amidine group from Arginine through a
process of transamidination and
transmethylation yields creatine.
COMPARISON
BETWEEN MULTIPLE SCLEROSIS and
MYASTHENIA GRAVIS
Myasthenia
Gravis and Multiple Sclerosis differ
only in that the former will not require
as intensive treatment as will Multiple
Sclerosis. The answer for this
difference is obvious. One is a
peripheral nerve pathology, the other
being central nerve pathology. In the
diagnosis, one will find the eyelids in
Myasthenia Gravis drooping. In Multiple
Sclerosis there will be nystagmus -
constant involuntary, more or less
cyclical movement of the eyeballs.
Movement may be in any direction, but
usually lateral as the patient follows
the examiner’s finger. (It is definitely
more pronounced than that found in
Meniere’s disease.) There may be
heaviness of the legs in Myasthenia
Gravis, but it will always be present in
at least one leg in Multiple Sclerosis.
Myasthenia Gravis patients will have
difficulty in chewing and swallowing,
the jaws might sag, and some will
present a sad, masked-like expression,
but never like Parkinson’s disease.
Scanning speech will be in evidence in
advanced cases in Multiple Sclerosis,
and words will come slow and syllabic.
General weakness increases as the day
goes on in Myasthenia Gravis; some
increase in fatigue only with activity
in Multiple Sclerosis. Remissions and
exacerbations are common in both
diseases in the early stages, but more
so in Myasthenia Gravis. In Multiple
Sclerosis, the patient will experience
numbness of the hands and legs as the
disease progresses, or a tremor in the
hand will develop, making signing of
one’s name a problem. The tremor is
intentional. Well along in the disease
of Multiple Sclerosis, the gait will be
awkward and stiff. Ataxia is due mainly
to the inability to coordinate and
control movements. The knee-jerks will
be exaggerated, with positive Babinski
and ankle clonus. The Babinski can be
normal and no clonus, but there are
other signs equally as important.
Oppenheim’s tibia test; Gordon’s calf
muscle test; Chaddock’s external
malleolus test, and the Hoffman reflex -
a finger reflex. Anyone of these, along
with temporal whiteness of the optic
nerve can be considered early or minimal
Multiple Sclerosis. Abdominal reflexes
are variable. Pain, bilateral, of the
sartorius muscles with any positive
reflex is always very suspicious of
Multiple Sclerosis. In Myasthenia
Gravis, the old neostigmine test is
conclusive. More detailed symptoms and
signs on these two pathological
conditions can be found in such common
reference as Merck’s Manual. The
important factor is early diagnosis. Do
not hesitate to commence treatment in
either disease even though the
impression might be guarded. Response to
treatment is sufficient evidence that
your judgment is sound.
There are
three forms of Multiple Sclerosis: 1)
Pseudo-Multiple Sclerosis or Cerebral,
which is the syndrome characterized by
mental symptoms, emotional lability,
convulsive seizures, hemiplegia and
aphasia. This type is caused by an
Adenovirus which gains entry into the
brain through damage to the choroid
plexus much like the encephalitis that
follows pneumonias. Actually, the
resulting pathology is an encephalitis.
Many who have experienced this syndrome
have died; many who have lived might
just as well have died, for the return
trip is costly, long, and requires a
great amount of tender, loving care. 2)
cerebellar-brain-stem-spinal: This is
true Multiple Sclerosis and is
manifested by nystagmus, scanning
speech, intention tremor, ataxia,
transient parenthesis, weakness in one
or more extremity, and visual
disturbances. 3) Spinal or minimal
Multiple Sclerosis: These cases are
never given a diagnosis. These patients
come with other complaints, but singular
upper motor neuron pathology will be
evident. This might be, as we have seen
them, positive Hoffman, positive Gordon,
positive Oppenheim, and occasionally, a
patient with a footdrop limb.
IMPORTANCE
of THIAMIN HYDROCHLORIDE in NEUROLOGICAL
DISEASES
The
importance of thiamine in treating
Myasthenia Gravis and Multiple Sclerosis
cannot be over-emphasized. Two molecules
of thiamin hydrochloride in combination
with two molecules of phosphoric acid is
cocarboxylase. For the reaction of
acetyl coenzyme A plus oxaloacetic acid
to continue through to citric acid with
the release of coenzyme A, cocarboxylase
must be present. If this reaction does
not take place, due to one of many
factors, there will be no coenzyme A
present to react with another molecule
of pyruvic acid to set in motion the
elements necessary for the continuance
of the metabolic cycle. In thiamin
deficiency, both pyruvates and lactate
accumulate in the blood. Pyruvates also
accumulate at the neuromuscular junction
causing cloudy swelling of the distal
portion of the nerves. Cocarboxylase,
also known as diphosphothiamine, is
necessary in the synthesis of
acetylcholine and in the control of its
hydrolysis. The activity of choline
esterase of serum is also strongly
inhibited by cocarboxylase.
The chief
chemical factor in both diseases is
thiamine hydrochloride. Other fractions
of the B complex are also essential but
in lesser amounts. Myasthenia Gravis is
due to genetic fault, most likely
involving an intermediate lethal gene or
group of genes. Multiple Sclerosis is
more complex. The initial pathology is
sickness caused by the Coxsackie virus.
This virus mimics poliomyelitis, and for
many years accounted for thousands of
so-called polio cases. This virus, like
the polio viruses, can cause paralysis
but never permanently. The nerve damage
is the result of microscopic hemorrhages
in the central nervous system. With the
contraction of the scar at the site of
bleeding, the vessels carrying nutrients
to the nerve cells are virtually clamped
off. This leaves nerve tissue, in many
instances, alive but not capable of
work. As time goes on, this wasting of
nerve tissue results in loss of its
myelin protection. This is similar to
electrical wires that have lost their
insulation when exposed to the wear of
daily use, or exposure to the elements.
Myelin is a lamellated structure
composed of neurilemma cell membranes.
Neurilemma cells have marked affinity
for axis cylinders, apply themselves
closely and seemingly engulf them. At
the same time, their cytoplasm flows
around the axis cylinder. The myelin
sheath is actually part of the
neurilemma plasma membrane with its
lipid and protein layers. Myelin in the
central nervous system is likewise
lamellated. It is laid down by neuroglia
cells. The sheath of the nerve fiber is
known to have a relationship to speed of
conduction - the speed of propagation
being in direct proportion to the fiber
diameter. Impulses are thought to travel
along the surface of a nerve fiber and
its speed over the large myelinated
fibers is approximately 337 miles per
hour, 150 meters per second. We can
reconstruct the nerve pathways and re-myelinate
the damaged nerve channels. There is
nothing new about this physiology. Each
one of us has demonstrated or
experienced positive Babinski reflexes.
A child is born without completed
laminated sheath. This is the reason for
the spastic movements of the child. The
nerve channels are minute in comparison
tc the adult person, thus we can expect
a longer interval of tine necessary for
repair. If the baby can complete the
myelination of its nerve channels with
only mother’s milk, surely we can
duplicate this performance - - and we
can. There will, however, be situations
where the pathology has existed for so
long a time that recovery seems
impossible. This is true because it
requires approximately two years of
treatment, with massive doses of
vitamins and a high protein diet, to
repair one year of the disease.
Physicians are too afraid to make an
early diagnosis, and some patients now
under my care experienced as much as ten
years in that process. In Myasthenia
Gravis, the chief concern is with the
build-up of pyruvic acid at the
neuromuscular junction. We also find
decreased amounts of acetylcholine along
with limited amounts of cocarboxylase.
As we noted in the discussion of
glycolysis, cocarboxylase plays a very
important role in various reactions
involving principally the
decarboxylation of pyruvic acid and
other keto acids. In the brain,
cocarboxylase participates in the
anaerobic dismutation of pyruvate to
lactate and acetate, and their
subsequent oxidation to carbon dioxide
and water. Cocarboxylase is also
involved in the synthesis of
acetylcholine which is definitely in
short supply in Myasthenia Gravis. The
activity of choline esterase is strongly
inhibited by this same double thiamin
unit. The conversion of thiamin
hydrochloride to cocarboxylase takes
place in the liver, the kidneys, and to
a small degree, in brain and muscle. One
can have nephritis, yet the small amount
manufactured in the kidneys continues to
be produced. The liver is the main
source for this conversion. An
individual with liver pathology would
have a decreased capacity for
phosphorylation of thiamin. The storage
capacity of the body for thiamin is
limited. It does accumulate rapidly in
the liver in its original form and also
as the pyrophosphoric ester. Thiamin
deficiency inhibits lactic acid
metabolism at the stage of pyruvic acid.
When we refer to thiamin deficiency, we
actually mean a lack of cocarboxylase.
Pyruvic acidemia is an index of this
type of thiamin deficiency. We might
mention here that niacin deficiency can
induce hepatic insufficiency. The amount
of nicotinic acid required to elevate
blood coenzyme, the active physiological
form of nicotinic acid, increases
dramatically in liver stress.
Cocarboxylase (thiamin pyrophosphate)
operates as a coenzyme in the oxidative
decarboxylation of ketoglutarate to
succinate and of pyruvate to
acetoacetate. Succinic acid in turn is
acted upon by the enzyme succinic
dehydrogenase, yielding fumaric acid by
oxidative dehydrogenation. Fumaric acid
readily undergoes hydration in the
presence of the enzyme fumarase to form
malic acid, which on oxidation in the
presence of the enzyme malic
dehydrogenase, yields oxalacetic acid.
At this point of cell metabolism, the
entrance of another molecule of pyruvic
acid follows the Krebs cycle to be
repeated. We are never concerned with
the amount of pyruvic acid formed by the
various routes, provided we can maintain
normal cell metabolism.
EARLY USE of
THIAMIN HYDROCHLORIDE in NEUROLOGICAL
DISEASES
In the late
thirties, Stern from Columbia University
was employing thiamin hydrochloride
intraspinally with astonishing results
in Multiple Sclerosis. He reported
taking patients to the operating room on
a stretcher, and following 30 mg.
thiamin given intraspinally, they would
walk back to their room. The response
was relatively transient, but it led
Stern to believe that Multiple Sclerosis
was nothing more than vitamin B1
avitaminosis, the “modus operandi” being
damage to the filter bed of the choroid
plexus. Stern also found that the
effective dose of vitamin B1, when given
into the lumbar subarachnoid space, was
too close to the lethal dose as was
demonstrated in dogs. Stern’s hypothesis
was backed by the knowledge that
degeneration of the myelin sheaths of
peripheral nerves as well as of the
ganglion cells of the brain arid spinal
cord can be produced in experimental
polyneuritis. Similar findings are
observed in starvation, even when the
supply of thiamin appears to be
adequate. One school of thought regards
the neurological syndrome of
polyneuritis as a functional defect
concerned with the neurons. From thirty
years of observation, I am certain that
in Myasthenia Gravis and Multiple
Sclerosis, it is not a functional
defect, nor is it due to impaired
diffusion which would deny to the total
metabolism sufficient quantities of the
vitamin to satisfy the requirements of
the neuromuscular systems The problem is
supply and demand. In this light, Dr.
Leon Rosenberg of Yale University
Medical School, in working with B
vitamins, distinguishes between
vitamin-deficiency diseases and
vitamin-dependent diseases. He states
that the successful treatment of
vitamin-dependent diseases requires
dosages up to 1000 times the calculated
minimal daily requirement. 1.3 mg. has
been established for thiamin
hydrochloride which would indicate that
in the pathological conditions being
considered, the daily requirement would
be at lease 1300 me. Moore in 1940
published a monograph on the use of high
intravenous doses of nicotinic acid for
the cure of Multiple Sclerosis. Moore
employed a drug combination called “Nicobee”.
This preparation contained 100 mg.
nicotinic acid and 60 mg. of thiamin in
each 10 cc solution.
Many of the
components of the B complex must also be
administered in varying amounts, along
with thiamin hydrochloride, since they
too exert a dynamic influence in general
metabolism. Many believe that the B
vitamins are actually metabolic
reagents. Hoagland has referred to them
as “protective catalysts”.
1) Thiamin
hydrochloride: 300mg. to 500 mg., 30
minutes before meals and bed hour, and
during the night if awake. (The higher
amounts in long-standing cases.) This
requirement is high, since much is lost
through action of gastric juices and
loss due to perspiration. 400-mg. daily
by needle, given intramuscularly. During
summer months this can be given every 12
hours to good advantage. Two to three
times each week, and where office access
is convenient, 20 mg. per kg. body
weight, or at least 1000-mg. is
administered intravenously. This is
given with 100 mg. to 200 mg. Niacine
(nicotinic acid) which is available 100
mg. in 10 cc ampules (The concentrated
Niacin available in 30 cc vials, must be
diluted if employed intravenously.) The
intravenous dose is given with the
patient in a recumbent position. A 20 cc
to 30 cc syringe, carrying a one-inch
22-gauge needle should be employed. The
injection is given slowly (5 to 7
minutes) holding the syringe with one
hand. The usually-employed three fingers
of the other hand must be on the
patient’s pulse. An increased pulse rate
indicates too fast a flow of the
medicine. This indicates the rate of
phosphorylization. Thiamin hydrochloride
is, indeed, a toxic substance, and
anaphylactic reactions have been
reported, but I have never seen a case
in treating thousands of patients (not
necessarily Myasthenia Gravis or
Multiple Sclerosis), in 30 years of
clinical observation. I have observed
one case of extreme sensitivity in which
itching was present within one minute
after an intramuscular injection of 100
ing. This was immediately controlled
with 5 cc Benadryl (diphenhydramine) IM
It must be remembered that once thiamin
hydrochloride is phosphorylated it is no
longer a critical allergic substance,
but is cocarboxylase, a necessary but
absolutely harmless agent. (My problem
has been the PRESERVATIVES now required
by FDA regulations, and they should be
removed.) Higher doses of thiamin can be
used, but then the dilution factor must
be greater.
2) Niacin
nicotinic acid: We recommend 100mg. to 3
grams, thirty minutes before meals and
at bed hour, and also during the night
if awake whichever dose will produce a
strong body flush. Niacin dilates the
blood vessels, even those that have been
compressed by scar tissue, allowing a
greater amount of nutrient material to
reach the cell laboratory or factory
comprising muscles and nerves. This
constant, repeated dilatation of the
blood vessels acts in the same manner as
the dilating urethral catheter to
correct constriction. One is chemical,
the other is mechanical. Hot fluids
taken at the same time as the niacin
will enhance the flush. Pyridoxine. has
been a suggested stimulant The lack of
constant flushing in Multiple Sclerosis
is disappointing but not hopeless. It
will require a longer time to achieve
results. Many times patients will flush
with intramuscular niacin when they fail
to flush by the oral route. An
occasional patient will experience the
sensation of a chill following nicotinic
acid flush. This is transient and of no
consequence. Food, even jelly beans or a
glass of milk, will reverse or minimize
the experience. Some patients will flush
sometimes and not at other times, even
during a single day. If no flush
develops within 45 minutes, the dose
should be repeatedly delayed reaction of
several hours can occur, and should this
be superimpose upon a previous
medication, the result could be severe.
Do not scratch when itching from niacin.
Just press the area with your fingers,
or better still, with a cube of ice.
Antihistamines will stop the itching and
limit the flush, should this he
necessary. Niacin should be given very
slowly by the intravenous route in the
geriatric patient, with or without
cardiac pathology, since it can produce
dilatation great enough to effect
right-side heart failure. Myasthenia
Cravis patients sometimes attain
geriatric status. Vasomotor collapse of
peripheral vessels, although rare, can
occur. Eight mg Decadron given I.M. will
reverse this condition.
3)
Pyridoxine (Vitamin B6): Lack of this
vitamin has been shown to induce
microcytic hypochromic anemia and
neurologic lesions in dogs and pigs. The
term includes not only pyridoxine but
also pyridoxal and pyridoxamine, all
three compounds being found in nature.
These derivatives have biological
activity equal to that of pyridoxine, as
demonstrated in rats. Pyridoxine plays a
part in the metabolism of unsaturated
fatty acids. It is also important in the
metabolism of amino acids. Pyridoxal
phosphate functions as a coenzyme, and
in transamination reactions. 100mg. to
200 mg. is given before meals and bed
hour. At least 100 mg. daily is given
intramuscularly.
4) Cobalamin
(Vitamin B12 ): It is thought that
vitamin B12 acts as a catalyst in the
formation of the purine and pyrimidine
deoxyribosides which are present in
deoxyribonucleic acid. Technically, B12
is cyanocobalamin. Vitamin B12 with
pterylglutamie reduces the requirement
for choline essential in the treatment
of neurological diseases. l000mcg. is
given three times each week by needle
(repository type). The incident of
dermatitis from continued use of vitamin
B12by needle is roughly 15 percent. I
have never seen this develop in a
patient with Myasthenia Gravis or
Multiple Sclerosis. B12 is recognized as
a factor in the synthesis of Myelin
5) Ascorbic
Acid (Vitamin C): The use of high daily
doses of vitamin C will prevent a
superimposed illness and will lend
itself in metabolism. Ten to twenty
grams should be taken daily by mouth in
divided doses.
6)
Riboflavin (Vitamin B2): A deficiency of
vitamin B2 in young animals results in
inhibition of growth terminated by
death. The yellow enzyme can, as
demonstrated by Warburg and Christian,
participate in a series of enzyme
reactions involved in the metabolism of
carbohydrates. It is capable of
transporting hydrogen from reduced
coenzyme II, a niacin coenzyme which
attacks hexosemonophosphate,
regenerating the riboflavin
phosphate-protein complex. Riboflavin
also takes part in enzymic reactions as
a dinucleotide prosthetic group,
consisting of riboflavin, two phosphoric
acids, ribose and adenine. Riboflavin is
very important in the regulatory
function of the hormones involved in
carbohydrate metabolism It is classified
as a low-energy package. 40mg. to 80 mg.
given daily by needle IM 25 mg. before
meals and bed hour.
7) Vitamin E
as d-alpha Tocopherol acetate or d-alpha
Tocopherol acid succinate. The latter is
more practical since it is a pure form.
Complex biochemical changes in the.
muscle tissue in chrome vitamin E
deficiency are followed by histological
lesions characteristic of muscular
dystrophy. Deficiency has also been
shown to produce dernyelinization and
distortion of the axon pattern in the
spinal cord, giving rise to hypalgesia
and progressive paresis. Fatal massive
liver necrosis occurs in animals
maintained on diets low in vitamin E and
sulfur-containing amino acids. 800
international units before meals and bed
hour must be adhered to in this
treatment.
8) Crude
liver: This substance contains factors
still unknown but essential in
metabolism. Patients with pernicious
anemia often show neurological
involvement, and are tremendously
benefited by liver injections which, of
course, contain vitamin B12 .
Degenerative changes brought on by other
factors, therefore, can also be
benefited by daily injections of crude
liver.
9)
Adenosine-5-Monophosphoric acid: One of
the purine bases occurring in muscle is
adenine It, along with other purines,
exists in various forms. Adenosine
polyphosphate is of primary interest in
this discussion. The basic structure is
adenosine, adenine-9-riboside This is
esterified with phosphoric acid at the
5-position of the ribofuranose to form
adenosine-5-phosphoric acid, also known
as adenosinemonophosphate (AMP).
Inosinic acid is a commonly-occurring
breakdown product of AMP, formed by
deamination in muscle extract. Myosin
displays enzymic activity similar to
adenylic deaminase. By attaching further
phosphoric acid residues in
pyrophosphate linkage
adenosinediphosphate (ADP) and
adenosinetriphosphate (ATP) are
obtained. ATP, as previously noted, is
the energy package essential for life.
By adding this to our treatment, we
enhance all chemistry dealing with cell
metabolism.
10) Choline:
Choline is a structural component of fat
and nerve tissue, thus has a strong
relationship to the phospholipids and to
its acetyl ester. Acetylcholine plays an
important role in the humoral
transmission of parasympathetic and
other nerve impulses to effector organs.
It also plays a part in transmethylation.
Choline serves as a methylating agent in
the physiological process -
guanidoacetic acid to creatine. We give
700mg. to 1400mg. after each meal and at
bed hour.
11)
Lecithin: Lecithin is the glyceryl
ester of a pair of fatty acids and a
substituted phosphoric acid group
attached to a choline radical. “Choline”
is one of the products of lecithin,
representing about 15 percent of the
molecule. Lecithin placed in water and
observed under the microscope, will
diffuse out, forming long, curving
strands (myelin forms). The hydrophilic
nature of the lecithin molecule plays an
important part in the structure and
properties of cell membranes. It is the
lipid used in nerve tissue. We give 1200
mg. Soybean Lecithin after each meal.
12)
Magnesium: 100 mg. after each meal to
supply additional ions for muscle
activity. It is an enzyme activator.
13) Calcium
Gluconate (10-grain tablets): We give
two tablets after each meal and at bed
hour to supplement dietary intake for
muscle activity. At times this is given
intravenously, one gram twice weekly.
14) Calcium
pantothenate: The physiologically
active form of panthothenic acid is
coenzyme A. Its acetyl derivative
(acetyl CoA) is synonymous with active
acetate. Metabolic transformations are
very complex and involve numerous
enzymes and coenzymes. Coenzyme A
participates in the acetylation of
amines. The panthothenic acid coenzyme
plays a vital role in carbohydrate
metabolism and acetyl transfer also
occurs in the metabolism of fatty acids.
We give 200 mg. after each meal and at
bed hour.
15)
Aminoacetic acid (glycine): Glycine
enters into a variety of metabolic
functions. It is directly concerned in
the synthesis of glutathione, the
tripeptide which plays an important part
in intracellular oxidation and
reduction. Rapport and Katz have shown
that when glycine is added to perfused
muscle, the oxygen absorption is 40
percent higher than otherwise,
indicating that the presence of this
amino acid stimulates the combustion of
other tissue constituents. To the body
in general, glycine is no doubt most
important because of its wide
adaptability in the detoxicating process
of the body. More than one hundred
substances, when fed, are joined in the
body with glycine. In the deamination of
glycine, three products will be formed:
ammonia, carbon dioxide and water. The
ammonia from this reaction is then
quantitatively converted to urea. One
heaping tablespoon of the powder in a
glass of milk four times each day. Much
of the oral medication can be taken with
this drink.
16) Make
certain that the hemoglobin is at least
13 grams.
17) High
protein diet with two to three eggs for
breakfast.
18) One
Theragram-M cap. daily for trace
minerals.
19) Dantrium
has value for relieving intentional
tremor and Symmetrel for relieving
stiffness in Multiple Sclerosis. Dose
must be individualized.
20) Zinc
gluconate: 10 mg. three times each day
has some value in Myasthenia Gravis.
Take several hours after vitamin B2
This
treatment works so dramatically in
Myasthenia Gravis, that should a given
patient’s physician refuse to administer
this schedule, I have this
recommendation: One gram thiamin
hydrochloride one hour before meals and
at bed hour, and during the night if
awake. Niacin taken at the same time,
and in amounts sufficient to produce a
good body flush. Two hundred mg. calcium
pantothenate and one hundred milligrams
pyridoxine before meals and at bed hour.
Ten grams ascorbic acid, taken in
divided doses. Amino acetic acid: one
heaping tablespoon in a glass of milk,
four times each day. Naturally, the full
schedule will afford more dramatic
response.
For a long
time, it has seemed to me that virus
bodies might have the potential tc alter
their protein coat, and therefore their
dimension, and become another virus for
another disease. In our long practice,
we would see, as I an certain many of
you have, chicken pox just before
Thanksgiving, mumps by Christmas, red
measles in the Spring, and polio or a
virus mimicking polio in the Sumner,
German measles, virus colds, and virus
pneumonitis just about any time.
As for
etiology of Multiple Sclerosis, a good
history will tell the story. I have one
patient who was diagnosed Polio in 1950.
He experienced total paralysis, but made
a complete recovery. Five years ago, he
began to demonstrate the signs and
symptoms of Multiple Sclerosis, he was
given a “strong” course of ACTH with
relief of symptoms. Three months later,
this had to be repeated, but the results
were not as good. Some three months
later, a third series of injections of
ACTH was worthless. (This has been the
pattern with the use of ACTH, and
represents nothing more than whipping a
tired horse. In my book, it borders on
malpractice.) His myelin sheath has just
about been destroyed. He has so many
areas of “no insulation” that his
movements are like that of a newborn
baby. - Had he received our treatment at
the onset of his illness, he would be in
good health today without any physical
handicap. This individual never had
Poliomyelitis. The virus that brought
him down was the COXSACKIE virus, and
this explains his initial recovery.
Another case seen was a 31 year-old
female. This young lady was diagnosed
Poliomyelitis when she was 19 years of
age. Three years ago, she began
developing signs and symptoms of
Multiple Sclerosis, and that is her
present diagnosis. Her neurologist, who
made the diagnosis of Polio, now tells
her that there is no doubt in his mind
that what she has now, actually started
when she was 19. He is absolutely
correct, because she had a COXSACKIE
virus infection. In 80 percent of the
cases that have come under my
supervision, an illness compatible with
a Summer virus has been entertained.
Unless an illness is associated with
paralysis, it is understandable when a
patient or the family have difficulty in
establishing a workable timetable.
OTHER
HYPOTHESES on ETIOLOGY of MULTIPLE
SCLEROSIS
Dr. Henry
Kempe, from the University of Colorado
School of Medicine, as reported by
Medical World News believes that
Multiple Sclerosis is caused by vaccinia
virus. He found a correlation between
severity of the clinical disease and
antibody titer. He also observed that
only in demyelinating disease were
antibodies to vaccinia virus in the
cerebral spinal fluid. This brings to
mind the work of Horsefall and his
co-workers at the Rockefeller Institute.
They were able to culture an organism,
which they designated Streptococcus MG,
from a large percentage of their
patients with primary atypical
pneumonia. This proved later to have no
value, and the viral nature of the
disease was recognized.
The sleeping
virus theory of Dr. Milton Alter and
others, as reported in Medical Tribune,
along with the environmental aspect for
Multiple Sclerosis is another “ripe
apple” for public consumption and public
press exaggeration. Most of this theory
rests with the circumstantial evidence
that filterable transmissible agents
having slow virus properties are present
in other diseases.
Another
theory, that of Dr. Dmil K. Schandi, a
Nova University biochemist, in Fort
Lauderdale, Florida, and published in
“The Charlotte Observer”, relates it to
an environmental agent: specifically
carbon monoxide and the lack of the
vitamin pyridoxine (vitamin B6).
Pyridoxine is concerned with the
enzymatic decarboxylation of amino acids
and the incidence of Multiple Sclerosis
is too low in terms of the availability
of carbon monoxide.
Still
another theory has been advanced by
Doris Dahl and Amico Eignami8 of
Stanford University, Palo Alto,
California. They report the discovery of
a substance that “may” prevent the
self-renewing of myelin Scar tissue is
indeed the problem, but it is the end
result of microscopic hemorrhages
following virus invasion.
In
Myasthenia Gravis the accepted reasoning
is initiated by Thymomas in 20 percent
of patients over forty, and hyperplasia
of the thymus in others. Antibodies to
muscle have been reported in roughly 33
percent. Excessive pyruvates at the
neuro-muscular junction has been
recognized but not appreciated.
CASE
HISTORIES
CASE
HISTORY: MULTIPLE SCLEROSIS Male, white,
was in a wheel chair at a Veterans’
hospital for two years. Patient seen
while home on 30-day vacation. Treatment
given every day with marked improvement.
Upon returning to Veterans’ hospital,
the physician in charge recognized the
improvement and advised the young man to
return home and continue the treatment.
After three years, he was given a clean
bill of health by three neurologists in
three different places and was given a
responsible position. This was in 1950.
The individual remains in excellent
health, but continues with modified
therapy.
CASE
HISTORY: MYASTHENIA GRAVIS Male, white,
receiving treatment from nearby medical
centre for one year. He was receiving
guanidine (amount unknown) and 90 mg.
prostigmine bromide each day. He was
first seen in a Myasthenia Gravis
crisis. The emergency treatment
consisted of two ampules of prostigmine
methylsulfate of a strength of 1:2000,
and 5cc of coramine. Within a period of
eight or ten minutes, the patient
experienced a generalized convulsive
seizure which lasted some five minutes
and required 4 men to hold him on the
bed. Prostigmine, by needle, was
continued for three weeks, and then
15mg. tablets every six hours, Thiamin
hydrochloride was given three times each
day, intramuscularly, as well as other
fractions of the B complex. In one
year’s time, he had been “weaned off’
prostigmine Although given only two
weeks to live by the physicians at the
medical centre the day prior to our
first visit, this individual lived a
normal life for 18 years his death was
due to a cerebral accident.
CASE
HISTORY: Female, white, with diagnosis,
(August 1967), Poly Neuritis. Began
with pain and burning of legs associated
with jerking. Ran high fever 10 days.
Paralysis started on left side along
with weakness of hands, soon followed
with complete paralysis lower
extremities. Seen first time 7/5/69.
Paralysis and weakness as described.
Started on medication by mouth and
intramuscular injections. Several months
later, began intravenous schedule. In
approximately 16 months, was able to
move right leg. Upper extremities
returned to normal. On 6/10/72, began to
move left foot. Patient now able to walk
approximately fifty yards with knee
braces and walker. Does all the cooking
for family of four, as well as sewing
clothes for herself and two daughters.
(I can personally vouch for her ability
as a cook.) April 1973, she was able to
go without a back brace that was
previously necessary for her to use to
even get out of bed. One marvels at her
ability to pedal a stationary bicycle
“contraption” made for her by her
husband so that she might exercise her
legs. Our diagnosis in this case is
Transverse Myelitis (200 grams ascorbic
acid given IV in divided doses would
have saved this patient from paralysis.)
She has also received 300mg. ribonucleic
acid four times each week.
CASE
HISTORY: Female, white, who developed
weakness in extremities around June 25,
1961. Sensory examination revealed
hypalgesia over medial aspect of right
foot and calf. Motor examination
revealed a partial foot drop on the
right, with rather marked weakness and
inversion, eversion, and dorsiflexion of
right foot. Reflexes upper extremities 3
- 4 plus. Abdominal reflexes absent.
Knee jerks were 3 - 4 plus with patellar
clonus. Right ankle jerk was 4 plus and
the left, 3 plus. Bilateral, sustained,
ankle clonus. Babinski’s “brisk”.
Later
examined and hospitalized at a nearby
medical centre where Medrol was tried.
She was sent home with a diagnosis of
Multiple Sclerosis, superimposed by a
viral meningoencephalic. Blurring of
vision was established as due to a left
six-nerve paralysis She came home to
ride a wheel chair provided she lived.
Seen in our office one month later, we
concurred with the impression of
Multiple Sclerosis. Our treatment
schedule became operative. It has been a
long journey since June 1961, but the
results have been phenomenal. This
individual has been returned to full
activities, and as a gesture of
gratitude, comes to my office to serve
in the capacity of an office assistant
several days each week. She does,
however, still maintain her treatment
schedule. Whether this is necessary or
not, I follow the advice of another
patient who has been continuing modified
treatment for 22 years; “Why stop when
you feel so good?”
CASE
HISTORY: Male, white, 28 years. Seen
first time 2/26/72. History of numbness
in lower extremities with loss of muscle
control from waist down. This started
approximately 2 years before this visit.
Difficulty with bladder control at
times. Seen by several neurologists at a
nearby medical centre who failed to make
a diagnosis other than to say he had a
Central Nervous System Pathology.
Babinski’s, Cordon and Oppenheim signs
were all positive, and ankle jerks were
4-plus. Ankle clonus was bilateral and
sustained on right. be demonstrated a
right foot drop. We entertained a
diagnosis of Multiple Sclerosis.
Treatment was not started since he had
an appointment to be examined at a
nearby Veterans hospital clinic. We
advised him not to accept ACTH therapy.
The following week we did start
treatment. After 5 weeks, we did not see
the patient again for three weeks, at
which time he confessed that he thought
that he was well and had stopped
treatment. The weakness and other
symptoms were again returning. He has
been back to gainful employment for the
past 12 months. Incidentally, he has
been a “crack” pistol shooter, and he
still can hold a steady hand on the gun.
CASE
HISTORY: Female, white, 57 years. Seen
first time 5/19/72. Chief complaint was
fatigue. This started approximately
seven years before coming to our office.
The onset of illness was gradual.
Generalized weakness as the day went on,
but was always feeling refreshed in the
morning. Drooping of the eyelids became
a problem so that she automatically
would tilt her head backward so that the
ptosed eyelids would be partially
corrected. Fatigue of the muscles of
mastication on chewing became so
embarrassing that for the past several
months, she avoided all social events,
even dinner with friends. Swallowing
also became a serious problem forcing
her to a bland and sometimes liquid
diet. Even a few minutes talking, while
taking the history, would so fatigue her
that she found it necessary to recline
on the examining table so as to regain
her strength. She visited many clinics
and medical centres in the United States
and Europe, but always was given the
same-diagnosis - her review of
conditions labeled her as PSYCHOSOMATIC.
To us it was obvious that she suffered
from advanced Myasthenia Gravis.
1000mg. Thiamin Hydrochloride and 300mg.
pyridoxine given by needle had her
demonstrating jaw and face-movements to
her husband in less than 10 minutes. She
remarked that she had not been able to
do that in three years. She was given
our schedule for treatment, but had
great difficulty getting her local
physician or any physician to give her
the needed injections. In desperation,
she returned to one of the medical
centres and confronted them with the
diagnosis, which they did not believe.
She, however, demanded that they employ
their test for this disease, which they
did. From the patient’s description,
given at a later visit, I surmised that
Tensilon was used. Her response was the
greatest ever seen at that University.
She is also receiving RNA 300mg. tablets
three times each week, which we believe
have stimulated or furthered her
progress. She no longer hesitates to eat
in public, and her stamina is
approaching normal. During a visit to
our office in April of this year (1973),
she laughed and joked about her
experiences in getting the diagnosis
confirmed so that she could receive the
vitamin injections under supervision.
She also favored us with a platter of
delicious cakes that she had baked prior
to coming to the office.
Although we
could write a book on cases treated and
cured (or established a permanent
remission), time is a prohibiting
factor.
The
treatment of Multiple Sclerosis has been
empiric since it was first described by
Sir Robert Carswell in 1838. Brickner,
in 1336, gave a review on treatment
which included preparations of Antimony
and Arsenic, fever induced by various
methods such as diathermy, malaria
typhoid vaccine, and fever brought on
with the use of drugs. Surgical
procedures such as cervical
sympathectomy and root section were also
employed. Serums, hypnotism and
intraspinal injections of lecithin had
their day. Moore administered nicotinic
acid and thiamin following the
dissertation by Zimmerman and Burack on
diseases of the nervous system resulting
from a deficiency of the vitamin D
Complex, and the paper by Spies and
others on the use of nicotinic acid in
the treatment of Pellagra associated
with mental pathology. Spies and Aring
in 1938 published a paper on the effects
of Vitamin B1 on peripheral neuritis as
associated with Pellegra. Moore also had
the benefit of the work of Stern, who
published an article on the intraspinal
use of Vitamin B1 for the relief of
intractable pain, and for inflammatory
and degenerative diseases of the Central
Nervous System. We learned early in our
approach to this disease that small and
infrequent doses of thiamin
hydrochloride would not accomplish our
purpose, and we also realized that more
than one unit of the B Complex would be
required, even though the physiological
chemistry relative to this phase of
metabolism had not been completely
established. Although Moore used
nicotinic acid for vasodilation
purposes, we rationalized that the
degenerative process taking place in
nerves, and thus also in muscle, was of
a greater magnitude. Inasmuch as the
only sickness remembered by the patient,
family or relatives took place during
the summer months we immediately
suspected a virus to be the offending
agent. This idea gained momentum with
the greater incidence of Multiple
Sclerosis following the epidemic of
encephalitis lethargia of 1920 to 1926,
and the epidemic of encephalitis B in
St. Louis and Toledo in1934. However,
the incidence of Polio was also up.
Mixed, abortive or unrecognized cases of
Poliomyelitis became a tantalizing
factor. After the isolation of the
Coxsackie virus with its mimicking of
Polio, and the knowledge that the
paralysis with this type virus infection
was never permanent, the real
devastating factor, in time and place,
at least to me, became apparent. Flexner
and Lewis were able to demonstrate that
in Polio, vascular and lymphatic lesions
constituted the primary causes of the
lesions of the nervous system. Multiple
hemorrhagic accidents take place in
Multiple Sclerosis with ensuing scar
tissue . As these microscopic scars
contract, they impinge on the vessels
carrying nutrients to the Central
Nervous System cells. In muscle, the
“devastation” is brought about through
lack of function, there being no
“electrical charge” present to keep
muscle active. For this reason, the
Sister Kenney treatment for Polio had
merit, since it helps to maintain muscle
and muscle-nerve integrity. Our
employment of nicotinic acid is to
effect adequate dilatation of existing
vascular structures, producing over a
time, chemically, what the Urologist
accomplished with his catheters in
mechanical fashion. Once these channels
are sufficiently operative, the
metabolic factors that we supply will go
about revamping the myelin sheaths. Due
to lack of full energy components, cells
can temporarily lose the ability of
normal physiological activity. We can
restore the normal function of cells
which depends upon their ability to
extract and use the chemical potential
energy locked within the structure of
organic molecules. We accomplish this by
placing massive amounts of the essential
material at the disposal of cells. We
categorically make this statement: Any
victim of Multiple Sclerosis who will
dramatically flush with the use of
nicotinic acid, and who has not yet
progressed to the stage of myelin
degeneration, as witnessed by sustained
ankle clonus elicited in the orthodox
manner, can be CURED with the adequate
employment of Thiamin Hydrochloride and
other factors of the Vitamin B Complex
in conjunction with essential proteins,
lipids, carbohydrates and injectable
crude liver. If sustained ankle clonus
is not bilateral, then it is not a
deterrent. I have had patients who did
demonstrate bilateral sustained ankle
clonus, and who were in wheel chairs,
and who returned to normal activities
after 5 to 8 years of treatment. These
patients, fortunately, had not received
ACTH. One patient was given a single
course of Medrol 4 mg. Q.I.D. This had
little effect on her pathology, and
apparently no “blocking action” on our
treatment. The general use of ACTH in
Multiple Sclerosis will extend the
recovery period by a time directly
proportional to the amount of the drug
employed. It is hoped that this paper
will bring an end to this senseless
practice of medicine, since ACTH never
works the third time.
The theories
recognized as playing a part in
Myasthenia Gravis still rest in the main
with Thymus enlargement or tumor,
Endocrine dysfunction, metabolic fault,
and the build-up of pyruvic acid in the
vicinity of the motor end-plates. In
reality, it is a genetic fault involving
a lethal intermediate gene or group of
genes. There is definitely an
over-supply of pyruvates, and an
under-supply of acetylcholine. The cue
in this drama is cocarboxylase. Coenzyme
A is also in limited supply. Two
molecules of thiamin hydrochloride, and
two molecules of phosphoric acid yields
cocarboxylase. One way in obtaining
acetyl coenzyme A, a by-product of
coenzyme and pyruvic Acid, is in the
reaction between pyruvic acid, coenzyme
A and diphosphopyridine nucleotide in
the presence of diphosphothiamine
(cocarboxylase). Cocarboxylase is also
involved in the synthesis of
acetylcholine and in the control of its
hydrolysis. The activity of choline
esterase of serum is strongly inhibited
by this same agent. Thiamine occupies a
key position in at least the terminal
stages of carbohydrate metabolism.
Cocarboxylase plays an active role in
the decarboxylation of pyruvic and other
keto acids. In the brain, cocarboxylase
participates in the anaerobic
dismutation of pyruvates to lactate and
acetate, and their subsequent oxidation
to carbon dioxide and water. In liver
and other tissue cells, cocarboxylase is
involved in the conversion of pyruvates
to oxalacetate which combines
oxidatively and irreversibly with
another molecule of pyruvate to enter
the tricarboxylic acid cycle. In thiamin
deficiency, a form of peripheral
neuritis markedly demonstrated in some
cases of chronic alcoholism exists,
affecting both sensory and motor nerves.
The
treatment of Myasthenia Gravis is that
of any pathology dealing with the
interruption of the normal physiology of
nerve cells. In years past, when we
were treating Poliomyelitis successfully
with massive doses of ascorbic acid, we
would always follow with an indefinite
time-table giving the 3 vitamins for
nerve repair. We see the same results
when treating damage to the spinal cord,
whether this is due to mechanical
trauma, or to the inflammation caused by
a virus - any virus. As pointed out by
Lipschitz et al., the replenishing of
vitamin restores the ability of the
nervous system to handle properly
pyruvic acid and dextrose. This action
of thiamin makes its function in
Myasthenia Gravis seem elementary. A
German scientist once speculated that
cocarboxylase was actually the “food”
required for nerve life. In treating
Myasthenia Gravis with the schedule
outlined, the intensity to which it is
applied in Multiple Sclerosis will never
be necessary. We are not confronted with
the loss of myelin sheaths in extra
vital areas. The chemistry, however, is
more complex than in Multiple Sclerosis,
since it involves muscle cells to a
greater degree. Enzymes and their
balance is a necessary approach. When we
realize that over 900 different enzymes
have been identified, it makes more
knowledge knowledgeable the need for
extensive vitamin therapy. This suggests
that normal liver function is necessary
for good results. A simple liver
function test can be used to good
advantage. One that I “worked out” many
years ago to demonstrate “liver stress”
is performed as follows. Have patient
bring 90 cc from first voiding upon
arising. Fill ordinary test tube to
within one cm of top. Allow to set for
24 hours and read. One will find in most
specimens a gelatinous fluid resting at
the bottom of the test tube. The amount
present, which can measure 2.5 cm,
indicates the degree of liver stress
present. Choline by needle or by mouth
will remove this finding from the urine.
Some urine specimens will show a heavy,
white sediment obstructing proper
reading of liver stress. Glacial Acetic
Acid alone, and/or heat will temporarily
remove these phosphates. Should the
deposit of phosphates be exceedingly
heavy, then it is advisable to secure a
bed-hour specimen, or one 2 hours after
breakfast. The night specimen should be
placed in a cool area until delivery.
Occasionally, the urine specimen will
grossly look like skim milk. This is
clue to earthy phosphates and can be
cleared by adding Glacial Acetic Acid to
the tube. (After ascertaining liver
stress; one can then add 20 drops
Glacial Acetic Acid to the specimen if
none was previously added - and allow to
remain an additional 48 hours to check
for Uric Acid Crystals. A red shower
indicating an abnormal level for uric
acid.) This test must be run every week
when administering ribonucleic acid
(RNA).
APPENDIX
Since
presenting this paper, we have observed
that improvement in all categories is
enhanced when the intravenous injection
contains 800 mg. to 1000 mg. thiamin
hydrochloride, 200 mg., pyridoxine, 400
mg niacinamide, 100 mg. nicotinic acid.
The thiamin hydrochloride solution MUST
be clear. The amount of niacin employed
must be calculated from the “flush
factor” of a given patient. The
injection is made with a 20 cc or 30 cc
syringe, using a 23Ga. x ¾ inch or 22G x
1-inch needle. Intravenous medication
can be given daily; it should be
administered at least twice weekly. Due
to sensitivity possibilities, we always
have the patient take the intramuscular
injections for three weeks before
starting intravenous therapy.
1.
Stern, L.L.: The Intraspinal
Injection of Vitamin B1 for the
Relief of Intractable Pain, and for
Inflammatory and Degenerative
Diseases of the Central Nervous
System. Am,.J. Surg. 34:495,,1938.
2.
Rosenberg, L.L., Vitamin Deficiency
Diseases and the Vitamin Dependent
Diseases With Reference to arid D.
Nat’l. Health Ped’n. Bulletin Vol.
XVIII, No. 10, November 172.
3.
Moore, M.T.: Treatment of Multiple
Sclerosis Pith Nicotinic Acid and
Vitamin B1 Archives In .Med Vol. 65,
pp. 18, Jan. 1940.
4.
Bijou, S.W., Baer, M: Child
Development II Universal Stage of
Infancy. Appleton- Century- Crofts,
1965.
5.
Kempe, C.H.: Key to the Secret of
M.S. Medical World News, July
7,1972.
6.
Alter, M. et al: Dissertation on
Environmental and Sleeping Virus
Theory. Medical Tribune.
7.
Schandi, D.K.: Dissertation on
Environmental and Pyridoxine Cause
of M.S. The Charlotte Observer,
Charlotte, N.C. April 23, 1973.
8. Dahl,
Doris; Bignami, Amico: Report of
Substance Preventing Renewal Myelin.
Reidsville Review, April 23, 1973.
9.
Brickner, R.M.: A Critique of
Therapy in Multiple Sclerosis.
Bulletin Maur. Inst., New York, Vol.
6:665, April 1936.
10.
Zimmerman, H.H., Burack, F Lesions
of the Nervous System Resulting from
a Deficiency of the Vitamin B.
Complex Arch. Pathology, Vol.
13:207, February 1932.
11.
Spies, T.D;’ Cooper, C, Blankenhorn,
M.A. The Use of Nicotinic Acid in
the Treatment of Pellagra. J2\MI\,
Vol. 110:622, February; 1936.
12.
Spies, T.D.; Aring, C.D. The Effect
of Vitamin on the Peripheral
Neuritis of Pellegra. Vol. 110:1031,
April 1938.
13.
Klenner, F.P. Fatigue-Normal arid
Pathological with Special
Consideration of Myasthenia Gravis
and Multiple Sclerosis. Southern
Medicine and Surgery, Vol. III, No.
9; September 1949.
a.
Alpers, E.J.: Clinical Urology, 2nd
Ed., F.L. Davis Co., 1950
b.
Bodansky, M.: Intro. to
Physiological Chemistry, 2nd
Ed. John Wiley & Sons, Inc., 1930.
c.
Cameron, A.T., Gilmour, C.R.: The
Biochemistry of Medicine William
Wood & Co., 1933.
d.
Evans, A.L., Hartridge, L.:
Starling’s Principles of Human
Physiology 5th Ed., J.& A.
Churchill, London, 1930.
e.
Fieser, L.F.; Fieser, Mary: Organic
Chemistry. 3rd Ed, D.C. Heath
and Company, 1956.
f.
Harrow, B.: Casimir Funk, Pioneer In
Vitamins & Hormones. Dodd, Mead &
Co., New York, 1955.
g. Hawk,
P.B.; User, B.L.; Suramerson, W.H.:
Practical Physiological Chemistry.
13th Ed., McGraw-Hill Book Co.
Inc., 1954.
h.
Lichtman, S.S.: Diseases of the
Liver, Gallbladder and Bile Ducts,
Vol. 1, Lea & Febiger, Philadelphia,
1953.
i.
Lowenberg, S.A.: Medical and
Physical Diagnosis.7th Ed. F.A.
Davis Co., 1946
j.
Martin, H.N.; Martin, E.G.; The
Human Body. 11th Ed. Revised.
Henry Holt and Cc., 1932
k. Srb,
A.M.; Owen, H.J.; Edgar, R.S.:
General Genetics, 2nd Ed., W.E.
Freeman and Co., 1965.
l. The
Merck Manual, 12th Ed. Merck
Co. Inc., Rahway, N.J. 1972.
m. The
Vitamins: A Symposium, 1939, A.M.A.
n.
Vander, A.J.; Sherman, J.H.;
Luciano, D.S.: Human Physiology
McGraw-Hill Inc., 1970.
o.
Wells, H. C.: Chemical Pathology, 5th
Ed. revised. R.B. Saunders Co.,
1925.
BIOGRAPHY
FREDERICH R.
KLENNER B.S., M.S., M.D.
Reidsville,
North Carolina
A native of
Pennsylvania, Dr. Klenner attended St.
Vincent and St. Francis College, where
he received his B.S. and M.S. degrees in
Biology. He graduated “magna cum lauda”
and was awarded a teaching fellowship
there. He was also awarded the college
medal ‘for scholastic philosophy. There
followed another teaching fellowship in
Chemistry at Catholic University, where
he pursued studies for a doctorate in
Physiology.
Dr. Klenner
then “migrated” to North Carolina and
Duke University to continue his studies.
He arrived in time to use his knowledge
in Physiology and Chemistry to free the
nervous system of the frog for a
symposium, by immersing the animal in
10% nitric acid. Taken in tow by Dr.
Pearse, chairman of the department, he
was finally persuaded to enter the
school of medicine. He completed his
studies at Duke University and received
his medical degree in 1936.
Dr. Klenner
served three years in post-graduate
hospital training before embarking on a
private practice in medicine. Although
specializing in diseases of the chest,
he continued to do General Practice
because of the opportunities it afforded
for observations in medicine. His
patients were as enthusiastic as he in
playing “guinea pigs” to study the
action of ascorbic acid. The first
massive doses of ascorbic acid he gave
to himself. Each time something new
appeared on the horizon, he took the
same amount of ascorbic acid to study
its effects so as to come up with the
answers.
Dr.
Klenner’s list of honours and
professional affiliations is tremendous.
He is listed in a flock of various
“Who’s Who” registers. He has published
many scientific papers throughout his
scientific career.
Dr. Klenner was a:
Fellow: The American
College of Chest Physicians
Fellow & Diplomate: The
International College of Applied
Nutrition
Fellow: The American Association for
the Advancement of Science
Fellow: The American College of
Angiology
Fellow: The American Academy of
Family Practice
Fellow: The Royal Society of Health
(London)
Fellow: International College of
Angiology
Founder-Fellow: American Geriatrics
Society
Fellow (Honorary): The International
Academy of Orthomolecular and
Preventive Medicine
