From Archive Of Pediatrics (April, 1952)
The Poison Cause of Poliomyelitis
And Obstructions
To Its Investigation
Statement prepared for the Select Committee
to Investigate the Use of Chemicals in Food Products,
United States House of Representatives, Washington, D.C.
Ralph R. Scobey, M.D.
Syracuse, N.Y.
(with thanks to Jim West who made this document available on his website)
The disease that we now know as poliomyelitis was not designated as such until
about the middle of the 19th Century. Prior to that, it was designated by many
different names at various times and in different localities.1,2 The simple
designations, paralysis, palsy and apoplexy, were some of the earliest names
applied to what is now called poliomyelitis.
Paralysis, resulting from poisoning, has probably been known since the time
of Hippocrates (460-437 B.C.), Boerhaave,3 Germany, (1765) stated: "We
frequently find persons rendered paralytic by exposing themselves imprudently
to quicksilver, dispersed into vapors by the fire, as gilders, chemists, miners,
etc., and perhaps there are other poisons, which may produce the same disease,
even externally applied." In 1824, Cooke,4 England, stated: "Among
the exciting causes of the partial palsies we may reckon the poison of certain
mineral substances, particularly of quick silver, arsenic, and lead. The fumes
of these metals or the receptance of them in solution into the stomach, have
often causes paralysis."
Colton5 (1850) mentions the case of a patient who swallowed some arsenic accidentally
and was admitted to the hospital. The primary effects of the poison had been
successfully combated with proper remedies, but seven days afterward he became
paralyzed. It is significant to note that there was a latent period of several
days before the paralysis appeared since this delayed reaction is comparable
to the incubation period in infectious diseases.
Vulpian6 (1879) experimentally produced paralysis of the extensor muscles of
a dog by lead poisoning. The lesions, consisting in colloid degeneration and
cell atrophy of the anterior horn cells of the spinal cord were pronounced by
Vulpian as poliomyelitis. Adamkiewitz7 (1879) reported two parallel cases, one
of poliomyelitis and one of lead poisoning.
In 1881, Popow8 of St. Petersburg, published an essay upon the pathological
anatomy of arsenical paralysis as produced artificially in animals. The work
of Popow was carried out under the guidance of the distinguished neurologist
and microscopist, Professor Mierzeyeski. Popow concluded that arsenic, even
in a few hours after its ingestion, may cause acute central myelitis or acute
poliomyelitis.
During an epidemic of poliomyelitis in Australia in 1897, Altman9 pointed out
that phosphorus had been widely used by farmers for fertilizing that year. This
observation may be of significance since in recent years organic phosphorus
insecticides, such as parathion, have been suspected as possible causes of poliomyelitis.
Onuff10 (1900) reported a case of a painter with flaccid paralysis of both legs,
in whom the autopsy showed lesions characteristic of poliomyelitis.
Obsrastoff11 (1902) reported a case of acute poliomyelitis resulting from arsenic
poisoning. Phillippe and Gauthard12 (1903) reported a case of anterior poliomyelitis
from lead poisoning.
Gossage13 (1902), writing on infantile paralysis, says: "The nerve cells
or fiber may be acutely disabled by the action of some poison circulating in
the blood, and it is possible that such poison would only temporarily impair
their functions or so seriously affect them that recovery would be impossible."
Dr. David E. Edsall14 (1907), writing on the pathology of carbon monoxide poisoning
in Osler's System of Medicine, states: "Peripheral neuritis had repeatedly
been described and poliomyelitis and disseminated encephalitis have been seen."
Collins and Martland15 (1908) reported a case of poliomyelitis in a man, 38
years of age, which resulted from the use of cyanide as a silver polish. The
illness began with diarrhea, followed by headache and pain and stiffness in
the back of the neck. About eight days after the onset of the illness, he became
paralyzed. In discussing Collins and Martland's paper, Larkin stated that he
had seen one instance of this disease following potassium cyanide poisoning.
In the spring of 1930, there occurred in Ohio, Kentucky, Alabama, Mississippi
and other states an epidemic of paralysis.16,17 The patients gave a history
of drinking commercial extract of ginger. It is estimated that at the height
of the epidemic there were 500 cases in Cincinnati district alone. The cause
of the paralysis was subsequently shown to be triorthocresyl phosphate in a
spurious Jamaica ginger. Death resulted not infrequently from respiratory paralysis
similar to the bulbar paralysis deaths in poliomyelitis. On pathological examination,
the anterior horn cells of the spinal cord in these cases showed lesions similar
to those of poliomyelitis.
These incidents show that epidemics of poisoning occur and furthermore, that
epidemic diseases do not always indicate that they are caused by infectious
agents. Moreover, following the ingestion of the spurious Jamaica ginger, the
symptoms appeared two to ten days later. In some cases a longer time elapsed.
This latent period is comparable to the incubation period of infections diseases.
As a matter of fact, the incubation period of poliomyelitis is commonly stated
to be seven to 10 days on the average with considerable variation in either
direction. The so-called incubation period in poliomyelitis and the latent period
in these cases of poisoning, therefore, are strikingly similar in length.
Leenhardt et al.18 (1951) described acrodynia in the course of three cases of
acute poliomyelitis. Some authorities have considered acrodynia to be caused
by a poison. Elmore19 (1948) reported two cases of this disease following the
ingestion of mercury and Warkany and Hubbard20 (1951) found mercury in the urines
of 38 (92.7 per cent) of 40 acrodynia patients. Meyerhofer21 (1939) reported
that infantile acrodynia may immediately follow certain forms at atypical poliomyelitis,
especially encephalomyelitis. Mercury is used as an insecticide and a fungicide
and the above clinical observations indicate that it might be a factor in producing
some cases of poliomyelitis.
Gougerot22 (1935) reported that during arsenical therapy for syphilis, poliomyelitis
developed in two patients, and lethargic encephalitis followed by Parkinson's
disease in one.
In 1936, during a campaign to eliminate yaws in Western Samoa by the injection
of arsenicals, an epidemic of poliomyelitis appeared simultaneously.23 In one
community all of the patients developed paralysis in the same lower limbs and
buttocks in which they had received the injections and this pattern was repeated
in 37 other villages, whereas there was no paralysis in uninoculated districts.
The natives accused the injections as the cause of the epidemic of poliomyelitis.
Most of the cases of paralysis occurred one to tow weeks after the injection
of the arsenic.
The foregoing reports indicate that poisons can cause poliomyelitis. It would
appear that not any one poison in particular would be responsible for all cases
of poliomyelitis but the effect of any one of several could produce the same
ultimate result. When a disease is known to be caused by a poison, it is obvious
that a search for a germ or virus in relation to it would not be made. Conversely,
if a so-called virus is believed to be associated with the disease, then the
possibility of poisoning as the cause of the disease would not be considered.
It will be shown, moreover, that some so-called virus diseases and virus inclusions
can be caused by poisons.
Dr. Robert W. Lovett24 of the Massachusetts State Board of health (1908), describing
the epidemic of poliomyelitis in Massachusetts in 1907, and after reviewing
the medical literature on experimental poliomyelitis, states: "The injection
experiments prove that certain metallic poisons, bacteria and toxins have a
selective action on the motor cells of the anterior cornua when present in the
general circulation; that the paralysis of this type may be largely unilateral;
that the posterior limbs are always more affected than the anterior; and that
the lesions in the cord in such cases do not differ from those in anterior poliomyelitis."
It appears to be of great importance that various poisons, lead, arsenic, mercury,
cyanide, etc., found capable of causing paralysis are employed in relation to
articles of food that are used for human consumption.
There are two abnormal findings in cases of poliomyelitis that point strongly
to poisoning as the cause of this disease. One consists in the appearance of
increased amounts of porphyrin in the urine; the other is the presence of increased
amounts of guanidine in the blood. It is a well-known fact that porphyria can
follow poisoning by a number of chemicals. Guanidine has been found in increased
amounts in the blood in arsenic, chloroform, and carbon tetrachloride poisonings.
The fact that ascorbic acid has been effective in the treatment of poliomyelitis
appears justly to imply that this disease has a poison cause. Ascorbic acid
has been used as a reducing agent in the treatment of poisoning resulting from
a number of toxic agents, including coal tar antipyretics, nitro compounds,
aniline, cyanide, benzene, lead, arsenic, etc.32-40 Paralleling these modern
scientific investigations is the observation over a century ago that lime juice
and lemon juice were protective against the poisoning by fish which sometimes
resulted in paralysis,41,42. This early observation is perhaps the principle
reason why lemon juice is customarily served today when fish are eaten.
The fact that methylene blue,43 another reducing agent, is effective in the
treatment of poliomyelitis also points to the poison cause of this disease.
Methylene blue has been used as an antidote in the treatment of nitrite, cyanide,
carbon monoxide and other poisonings.
Another fact that strongly implies that human poliomyelitis is caused by a poison
is found in the recent report (1951) by Dr. Irwin S. Eskwith44 of Bridgeport,
Conn., that BAL (dimercaprol) was effective in bringing about complete recovery
in a moribund 4 1/2 year-old girl with bulbar poliomyelitis. BAL counteracts
the effects of poisons; it has been shown not to be effective in infectious
diseases.
RELATIONSHIP OF HARVEST TO POLIOMYELITIS
[...]
In 1907, Dr. H. C. Emerson54, Massachusetts State Inspector of Health, District
14, investigating an epidemic of poliomyelitis in that state, made a careful
inquiry regarding the diet. No infant who was fed exclusively on the breast
developed poliomyelitis. He found in six cases that fruit and berries had been
a large item of the diet. In the cases of two infants, bananas and berries had
been given in the diet in addition to breast milk. In three cases of poliomyelitis,
the illness was attributed to the eating of large amounts of blackberries and
blueberries. In one case the illness was credited to eating heartily of English
mulberries. In 39 instances it was stated that food supplied were bought from
fruit and vegetable peddlers in their localities.
[...]
Dingman55 (1916) reported a milk-borne epidemic of poliomyelitis and several
similar outbreaks have been reported since then that were traceable to milk.
[...]
Chapman58, raised the question of food poisoning to explain the epidemic of
poliomyelitis in England in 1947, when he stated: "Is it not possible that
the present prevalence of infantile paralysis may, in part at any rate, be due
to some article in our restricted and modified dietary?"
[...]
Toomey and August59 (1932) pointed out that some authors thought that poliomyelitis
is a disease of gastrointestinal origin which might follow the ingestion of
foodstuffs. In 193360, they noted that the epidemic peak of poliomyelitis corresponds
with the harvest peak of perishable fruits and vegetables. They called attention
to the fact that the disease occurs only in those countries which raise the
same type of agricultural products. Dr. C.W. Burhans60, one of the colleagues
of the authors, thought that green apples might be a factor in the etiology
of poliomyelitis. Toomey et al61. (1943) points out that there is frequently
a history of dietary indiscretions previous to an attack of poliomyelitis. They
suspected that a virus could be found on or in unwashed fruit or in well water
during epidemics of poliomyelitis. Every year for eight years, therefore, grapes,
apples, peaches, and pears were collected from the vineyards and trees in Northern
Ohio at the time of the ripening. In none of their studies was the so-called
virus of poliomyelitis demonstrated when the washings of the fruit or the well
water were injected into experimental animals. However, no chemical tests were
made to determine whether or not a chemical substance on or within the fruit
or in the well water, acting by oral ingestion top produce poliomyelitis, was
present.
Draper62 (1935) recorded a series of cases of poliomyelitis which he postulated
originated from a Greek fruiterer. All of the cases were in contact with the
Greek as business associates, relatives or customers, and there was nothing
in the evidence to point to infection being carried by the Greek himself other
than the fruit he supplied.
[...]
Barber64 (1939) reported four cases of poliomyelitis that developed simultaneously
on the same day from the eating of strawberries in a single house of a boarding
school. He says that the simultaneous onset of these cases resembled food poisoning.
The seasonal and climatic incidence of poliomyelitis, he points out, agree closely
with the seasonal increase in the consumption of fresh garden production. He
says that the epidemiological distribution of poliomyelitis resembles food poisoning.
Chenault65 (1941) noted that the history of poliomyelitis points to a "suggested
parallelism between a number of epidemics and the appearance of fresh fruits
and vegetables." [With regard to these numerous statements regarding fruit
and milk, note the high production of pesticides in the form of lead and arsenic
compounds during this pre-DDT period, graphed]
Goldstein et al66 (1946) reported an epidemic of polioencephalitis at a naval
training school among the cadets. The epidemic was explosive in character and
involved over 100 persons. Epidemiological evidence suggested that some food
served in the mess hall was the cause of the disease.
[...]
Gebhardt and McKay68 (1946) found during an epidemic of poliomyelitis in Utah
that of a total of 206 persons surveyed, 192 persons, or 93.2 per cent, had
one to two weeks prior to the onset of the disease eaten fresh fruits. The authors
found in Utah, New York and California, during 1943, that the cases of poliomyelitis
paralleled the harvest peaks. Most of the multiple cases in families were found
to have developed at the same time, suggesting means other than contact as the
mode of spread. Among the fruits more commonly eaten were apples, peaches and
pears; tomatoes headed the list of vegetables. The authors stated that the data
appeared to fit into the jigsaw puzzle of epidemic poliomyelitis.
[...]
Abbott71 (1948), of Auckland, New Zealand, stated: "The public has always
been fully convinced that they caught poliomyelitis from one another by direct
infection. The 'germ' idea is indeed deeply ingrained in both the profession
and the public. It will be many years before our prolific writers of medical
textbooks attain the degree of sophistication that would enable them to understand
how and why poliomyelitis would be more likely to be contacted from the flour-bag,
or some homely article of food, rather than from their neighbors."
[...]
Barondes72 (1949) points out that a study of the epidemiology of poliomyelitis
shows a definite correlation with the harvesting of fruit and vegetable crops
and to changes in climate, weather and humidity. The harvesting of such fruits
as cherries, grapes, berries, apricots, etc. and the edible vegetables, as lettuce,
radish, cucumbers, etc. usually from June to September, corresponds with the
period of poliomyelitis epidemics, Barondes points out.
Toomey et al74 (1949) made some important experimental observations that appear
to show a correlation of the poison and virus theories of poliomyelitis. They
considered it possible that a food (fruit) which enters the gastrointestinal
tract could in some way act as a precursor of catalytic enzyme on a normal constituent
of the tract and accelerate the production of poliomyelitis. Various materials,
together with fruit extracts, were tested.
When supernates of peach skin mash were injected intracerebrally into cotton
rats, followed at intervals with intracerebral injections of the so-called poliomyelitis
virus, accelerated production of paralysis occurred. Because of the presence
of cyanophore glucosides in peach skins, a synthetic preparation, succinotrile,
was injected intracerebrally into the experimental animals. This chemical accelerated
the production of the disease similar to that produced with the peach supernates.
Toomey et al. emphasize that the injections of fruit supernates were made in
a manner that does not occur under natural circumstances.
Sabin75 (1951), although insisting on the virus etiology of poliomyelitis, implicates
food and drink as important factors in the cause of this disease. He points
out that measures which are often advocated to combat poliomyelitis epidemics
are not warranted, such as (a) avoidance of crowds, large gatherings or sports
events, (b) exclusion of children under 16 years of age from movies, churches,
or schools, and (c) exclusion of poliomyelitis patients and suspects from general
hospital wards.
[...]
The implications [of the foregoing] should be obvious that investigations of
foods eaten by the poliomyelitis victim prior to his or her illness should be
carefully considered.
THE PRODUCTION OF SO-CALLED VIRUS DISEASES
AND "VIRUS" INCLUSIONS BY POISONS
The public, as well as many physicians, is under the impression that viruses
are living organisms comparable to a germ that enters the human, animal or plant
to cause the disease. The scientists, who are authorities on virus diseases,
are in disagreement as to the nature of a virus.
It is not generally realized that some so-called virus diseases may result from
the effects of poisons on the human body, thus, herpes zoster may follow exposure
to carbon monoxide or the administration of arsenic, bismuth, lipiodol, gold,
mercury, tuberculin, alcohol, etc. An epidemic of herpes zoster and peripheral
neuritis, similar to the "jake" paralysis epidemic in this country,
followed the ingestion of arsenic in beer in Manchester, England in 1900.76-78
The toxic agent was determined to be arsenic arising from dextrose made from
starch by the use of crude sulfuric acid containing this poisonous substance.
Herpes simplex, another so-called virus disease, has followed the ingestion
of alcohol, benzol, arsenobenzol, mercury, and the inhalation of either, among
other poisons. Van Rooyen79 noted its appearance after sulfapyridine therapy.
Herpes simplex has followed the injection of vaccines, milk and colloidal metals.
Inclusion bodies have been defined as products of virus activity or the elementary
virus bodies themselves. Inclusion bodies have been found in poisoned humans
and experimental animals.
Dalldorf and Williams80 (1945) found large acidophilic inclusion bodies in the
kidneys of rats poisoned by lead. Blackman81 (1936) found intranuclear inclusion
bodies in the tubular epithelium of the kidney and in the liver cells of 21
children dying from the effects of acute lead poisoning and lead encephalitis.
Cox and Olitsky82 (1934) found that the injection into animals of aluminum hydroxide
produced inclusion bodies similar to those seen in infectious encephalitis.
Van Rooyen and Rhodes83, in their textbook (1948), "Virus Diseases in Man,"
state: "Histological changes similar to those seen in infectious encephalitis
may be produced by carbon monoxide poisoning, brain injury, arteriosclerosis,
uremia, pregnancy toxemia and toxic agents like alcohol and lead."
Olitsky and Harford84 (1937) were able to produce inclusion bodies indistinguishable
from those observed in virus infections by the injections of aluminum compounds,
ferric hydroxide and carbon.
MISTAKES THAT HAVE BEEN MADE IN THE PAST
Several commissions, appointed during the first quarter of this century to investigate
the cause of pellagra, concluded from their studies that pellagra was an infectious,
contagious disease. Harris85 (1913) was able to inject Berkefeld filtered tissue
material from pellagra victims into monkeys to cause a corresponding disease
in these animals. He concluded from these experiments that a virus was present
in the injected material and that it was the cause of pellagra. If the work
of Harris had been followed exclusively, various strains of this "virus"
might have been discovered and a vaccine, effective in experimental animals,
might have been developed, as in the case of poliomyelitis. Today, as a result
of unlimited research, however, we know conclusively that pellagra is not caused
by a virus but rather that it is a vitamin deficiency disease. It is obvious
that if the investigations of pellagra had been restricted to the virus theory,
it would still be a mystery.
[...]
The symptoms of milk sickness in man resemble those of influenza or grippe,
gastritis, and so-called ptomaine poisoning. As a matter of fact, so-called
summer grippe or flu often occurs during epidemics of poliomyelitis. There were
10,000 cases in Cincinnati in 194789-90, which were thought to be related to
poliomyelitis and were considered, therefore, virus infections. However, Matson91
(1950), writing about poisonous plants, says that some physicians have expressed
the opinion that mysterious outbreaks of so-called summer flu in the late summer
are often due to milk contaminated with tremetol [a poison occurring in white
snakeroot and rayless goldenrod].
The observation that human and bovine outbreaks of tremetol poisoning occur
simultaneously corresponds with similar observations made during epidemics of
poliomyelitis. Medical reports have shown repeatedly that paralytic diseases
in horses, pigs, dogs, cats, ducks, chickens, etc. occur simultaneously in districts
where epidemics of poliomyelitis are prevalent,... [even though "polio"
affects only humans (except in laboratories), pesticide causality resolves these
conflicts of data.]
FACTORS PRECLUDING INVESTIGATION
OF THE POISON CAUSE OF POLIOMYELITIS
It is obvious that in the study of poliomyelitis every possible cause, including
the possibility of poisoning, should be investigated.
Since 1908 -- for 44 years -- poliomyelitis research has been predominantly
directed along only one line of investigation, i.e., the infectious theory.
This single line of study, precluding other possibilities, including the poison
cause of the disease, has resulted from two factors, (1) The Public Health Law93,
and (2) the insistence, based entirely on animal experiments, thatpoliomyelitis
is caused by a virus.
1. The Public Health Law. The inclusion of poliomyelitis in the Public Health
Law as a communicable, infectious disease dates back to the early part of the
20th Century. At that time many diseases, now known to be neither communicable
nor infectious, were considered to be caused by an infectious agent simply because
they occurred in epidemics. The general attitude of that period is expressed
by Sachs94 (1911) in his statement: "In general, the epidemic occurrence
of any disease is sufficient to prove its infectious or contagious character."
The vitamin deficiency diseases, beriberi and pellagra, are outstanding examples
of epidemic diseases that were formerly considered to be infectious and communicable
according to the logic employed by Sachs. In fact, we find pellagra incorporated
into the Public Health Law as a communicable disease in the State of Pennsylvania
in the following rule and regulation adopted January 5, 1910: "That all
physicians practicing within the limits of the state shall make immediate report
of each and every case of uncinariasis duodenalis (hookworm disease) and pellagra
and anterior poliomyelitis (infantile paralysis) occurring in their practice
in the same manner that other communicable diseases are now by law and by rule
and regulation of the State Department of Health reported to the health authorities."
A State Health Officer95 recently wrote to me as follows: "I think all
of us will agree with you that in the past, as is still probably true, public
health rules and regulations and sometimes even public health laws, were influenced
too much by what we did not know rather than by what we did know. This was probably
an acceptable line of reasoning in the past, but with increasing public health
education and greater understanding and cooperation from citizens, this justification
becomes less acceptable."
The fact that an extensive epidemic of poliomyelitis was prevailing in the states
of New York and Massachusetts in 1907, aroused the suspicion that the disease
was infectious and communicable; it was therefore incorporated into the Public
Health Law as such. However, conclusive evidence of contagiousness was not established
during that epidemic nor in subsequent ones. Moreover, during the greatest epidemic
of poliomyelitis in recorded history, as shown by the records of the U.S. Public
Health Service and the New York State Department of Health. Time Magazine, commenting
on these surveys, points out how, when and where people catch polio remained
a mystery. In addition to the failure to prove contagiousness of human poliomyelitis,
it has likewise been impossible to prove contagiousness of poliomyelitis in
experimental animals. This fact will be considered in detail later.
As a result of the inclusion of poliomyelitis in the Public Health Law as a
contagious, communicable or infectious disease, investigations regarding it
are almost exclusively in the hands of specialists in virology and public health.
The country doctor, general practitioner, and clinician have little or no opportunity
to participate in poliomyelitis research under these circumstances. Yet, Dr.
W. Ritchie Russell97 of the Department of Neurology, United Oxford Hospitals,
Oxford, England stated in 1950: "Clinical research into this disease is
so much neglected that there are exciting discoveries waiting for anyone with
time to give to this type of investigation."
Medical advances of the utmost importance have been made in the past by general
practitioners. An outstanding example is the work of Dr. Edward Jenner, a general
practitioner in Gloucestershire, England, whose observations and deductions
brought about vaccination against smallpox. All advances in medicine do not
result from laboratory experiments. Any doctor in any community, however, small,
and however limited his opportunities, may make a fundamental discovery, but
he must be given the opportunity to participate in the program and his observations
and deductions must be given adequate consideration.
2. Virus Research. The more or less general acceptance of the idea that poliomyelitis
is caused by a virus arose from experimental animal studies by Landsteiner98
(1908) in Austria, and Flexner and Lewis99 (1909) in the United States. These
experiments showed that a substance obtained from poliomyelitis victims could
produce a paralytic disease when administered to experimental animals. It has
been assumed, as a result of these experiments that an exogenous [originating
from without] virus is the cause of human poliomyelitis. Dr. Harold L. Amoss100
stated in 1928: "By reason of the parallelism of the human and experimental
disease it is believed that inferences drawn from experiments with monkeys may
be accepted with a certain degree of safety as applicable to the solution of
problems in connection with human cases." The portal of entry of the so-called
virus of poliomyelitis into the human body never has been established. The question
of the portal of entry is summed up in the published reports of the International
Poliomyelitis Congress that was held in New York City in 1948. The Modulator
stated: "We do not know too much about the portal of entry in human beings,"
and Dr. John R. Paul, of Yale University, stated: "I would say we do not
know the portal of entry in human beings."
It was mentioned in the foregoing that human poliomyelitis has not been shown
conclusively to be a contagious disease. Neither has the experimental animal
disease, produced by the so-called poliomyelitis virus, been shown to be communicable.
Rosenau102 (1921) stated: "Monkeys have so far never been known to contract
the disease "spontaneously" even though they are kept in intimate
association with infected monkeys." Twenty years later (1941), Dr. John
A. Toomey103, a poliomyelitis authority, stated: "No animal gets the disease
from another no matter how intimately exposed."
It is extremely difficult to understand how a human can contract poliomyelitis
from another individual through dissemination of a virus by contact, carriers,
excrement, unclean hands, unwashed fruits and vegetables, flies, etc. when a
healthy animal in the same cage with an "infected" animal, exposed
to all of these natural factors, remains unaffected. It appears obvious, therefore,
that communicability should have been established conclusively both in humans
and in experimental animals before poliomyelitis was incorporated into the Public
Health Law as a communicable disease.
Some investigators have as a matter of fact pointed out that human poliomyelitis
and the disease produced in experimental animals from human material, etc. are
not the same disease. Toomey104 (1935), for example, stated that intranasal
and intracerebral inoculation of poliomyelitis virus in the monkey does not
produce the same disease that is seen in man. Dr. Claus W. Jungeblut, a well-known
bacteriologist who has worked on the poliomyelitis problem for many years, recently
stated (1950): "Whatever the final answer may be, it seems a reasonable
statement at this time that the highly specialized, neurotropically fixed virus,
which has been maintained in the past by intracerebral passage in rhesus monkeys,
is more likely a laboratory artifact than the agent which causes the natural
disease in man." The logical conclusion appears to be, therefore, that
the laboratory experiments with the so-called virus of poliomyelitis are merely
of academic interest and have no practical application to human poliomyelitis.
For almost half a century poliomyelitis investigations have been directed towards
a supposed exogenous virus that enters the human body to cause the disease.
The manner in which the Public Health Law is now stated imposes only this type
of investigation. No intensive studies have been made, on the other hand, to
determine whether or not the so-called virus of poliomyelitis is an autochthonous
chemical substance that does not enter the human body at all, but simply results
from an exogenous factor or factors, for example, a food poison. Analogous reactions
are well-known as illustrated by the production of experimental sarcomas by
indol, arsenic, tar, etc. and which have been transmitted by Berkefeld filtrates.
The discovery in recent years of the so-called Coxsackie virus has tended to
further confuse the entire poliomyelitis problem. Hoyne107 (1951), for example,
states that the announcement of this discovery "is accompanied by some
feeling of dismay... In view of the foregoing announcement it seems that trained
investigators have added one more problem to the nebulous conditions enveloping
poliomyelitis. One might also be tempted to make the statement that the more
we learn about poliomyelitis, the less we know." Hoyne's statement applies
obviously to the confusion that has arisen from exclusive virus studies in poliomyelitis.
A Lancet editorial108 (1951) also indicates the complexity of the problem brought
about by the discovery of the Coxsackie virus, as follows: "A crop of new
snags is coming along as every week brings new tidings of the Coxsackie viruses."
Many diseases have been considered to be caused by viruses but virus studies
constitute only a portion of the investigations intended to determine the cause
of the disease. Poliomyelitis investigations, on the other hand, have been confined
exclusively to virus studies. Because of this situation and the Public Health
Law, those who maintain other opinions, including those concerned poisons as
the cause of poliomyelitis, can neither obtain funds from any source for research
nor cooperation for investigating their ideas. Reappraisal and investigation
of all theories, infectious and non-infectious, are imperative.
To epitomize, the following quotation from a talk on poliomyelitis given by
Dr. Ritchie Russell97, Department of Neurology, United Oxford Hospitals, Oxford,
England (1950) summarizes what has been pointed out in the foregoing: "The
time is ripe for a survey of our knowledge of the disease, of the methods of
treatment we are accustomed to use and our efforts to advance knowledge of the
condition... Surely if the Americans with all their millions of dollars for
research on poliomyelitis can do so little, we need not try... I do not intend
here to praise good work that has been done, but more to emphasize the gaps
in our knowledge of the disease in the hope that others may be encouraged to
work on the subject which sorely needs some extra attention. There are at present
several different groups of specialists working on the disease, including virologists,
infectious disease physicians, orthopedic surgeons, physiotherapists and public
health officers. This may be a reasonably adequate state of affairs as far as
handling the individual case is concerned; but as a background for advancing
knowledge of the disease it is not satisfactory for the members of each of these
groups have many other interests, and have neither the time nor always the experience
of other aspects of the disease to enable them to fit their piece into the whole
picture in such a way as to advance research... Unfortunately, the disease gets
worse as public health improves, and measures which are designed simply to avoid
infection seem to be singularly ineffective in poliomyelitis."
The statement is reminiscent of one made in 1938 by Dr. Carl C. Dauer109, Chief
of the Bureau of Preventable Diseases, District of Columbia health Department,
viz: "It seems rather remarkable in spite of all the time and effort spent
in poliomyelitis studies during the past 20 years so little information in the
epidemiology of the disease has been produced."
The urgent need for cooperation between the clinician and laboratory worker,
as well as an unprejudiced attitude toward the poliomyelitis problem, is emphasized
by Jungeblut105 as follows: "The subject is of keen interest to clinicians
and laboratory workers alike and progress will be measured by the extent of
cooperation between the two. Until the final word has been said it is hoped
that, in the future, students of poliomyelitis will preserve an open mind and
maintain an open door in their efforts to unravel the mysteries of this baffling
disease." Jungeblut indicates the confusion that has been caused by the
virus theory when he states: "Actually, the history of this disease has
been marked by periods of violent disagreement among scientific workers and
by sharp dissension within the ranks of the medical profession."
SUMMARY
[Omitted]
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