Fluoride Information

Fluoride is a poison. Fluoride was poison yesterday. Fluoride is poison today. Fluoride will be poison tomorrow. When in doubt, get it out.


An American Affidavit

Monday, February 3, 2014

Kaj Roholm's 1937 Classic Summary of: Fluorine Intoxication


 316              Fluorine Intoxication Summary by Kaj Roholm


     The starting point of the author’s investigations lies in Flemming Moller and Gudjonsson’s description of the previously unknown fluorine intoxication among workers at a Copenhagen factory, where cryolite is purified and ground, giving off quantities of dust.  As fluorine intoxication has not hitherto been thoroughly enquired into, a systematic, critical-synthetic examination is made in Part I of the numerous and little known works concerning the role played by fluorine in biology.  Most importance is attached to the genesis of the various forms of intoxication, as well as to their clinical and patho-anatomical picture.  The occurrence of fluorine in inanimate and animate nature is discussed in detail.  After Explaining the technique employed in the author’s investigation (Part II), a full account is given in Part III of the result of the author’s studies on human cryolite intoxication from the point of view of the clinical picture, morbid anatomy and industrial hygiene.  A synoptic digest concludes this part.  Part IV contains a description of the author’s intoxication experiments on rats, pigs, calves and dogs, with a concluding summary of the results obtained for each species of animal.  In Part V, Discussion and Conclusions, the results of the literature studies and the author’s investigations are summarized by means of a brief, systematic examination of acute and chronic fluorine intoxication, the possibilities of intoxication, and the prophylactic problems.  A final chapter discusses the physiological role possibly played by fluorine.  The principal conclusions of the work are outlined below. 

                       Occurrence of Fluoride in Nature

     As a constant ingredient of eruptive rocks, fluorine is a widely diffused element in inanimate nature.  Fluorine in soil, fresh water and seawater comes from that source.  Volcanic products may contain fluorine.  Deposits of fluorine minerals and rocks occur in the form of fluorspar, cryolite, apatite, phosphorite.  Normally, plants and animals absorb small quantities of fluorine according to local factors.  It is probable that there are traces of fluorine in all organic tissue.  As there is an affinity between fluorine and calcium phosphate, fluorine

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is stored in bones and teeth.  As a rule bone ash of terrestrial mammals contains 0.1-1%, tooth ash 0.1-0.4% fluorine.  Bones and teeth of animals living in the sea contain about ten times as much fluorine.  In the teeth fluorine is principally deposited in the dentine, to a lower degree in the enamel.


                     Effect on Enzymatic Processes and Protoplasm

     Fluorine compounds affect a large number of enzymatic processes (e.g. tissue respiration, blood coagulation, lactic acid formation in muscle, the splitting of starch by yeast).  Generally the effect is inhibitory, but often a weak concentration of fluorine is stimulating, a stronger one inhibitory.  Active fluorine compounds destroy protoplasm and arrest bacterial growth.  Yeast cells can become habituated to fluorine compounds.  It is doubtful whether the quantity of fluorine absorbed under normal conditions is of any physiological significance.  Experimentally, fluorine in quantities below the toxic limit has a stimulating effect on growth processes.  It has never been demonstrated nor is it probable, that fluorine in physiological doses is necessary to or has a beneficial effect on the development of the teeth. 

                               Fluorine Compounds

     From a toxicological point of view the fluorine compounds may be divided into four groups:  (1) Gaseous, hydrogen fluoride (HF), silicon tetrafluoride (SiF4) and certain organic compounds; (2) solutions of hydrofluoric acid (HF) and hydrofluosilicic acid (H2SiF6); (3) relatively easily soluble fluorides and silicofluorides; (4) slowly soluble compounds, especially cryolite (Na3AlF6) and calcium fluoride (CaF2),  The first three groups play a part in acute intoxications, all of them in chronic intoxications. 

                              Acute Intoxication

Acute intoxication manifests itself by a mixture of local irritation or corroding phenomena and symptoms due to absorption.  Ingested perorally, fluorine compounds in man produce vomiting, often haemrrhagic, diffuse abdominal pains, diarrhoea, alternation between painful spasms and pareses, both localized and universal, weakness, thirst, salivation, perspiration, dyspnoea, weak pulse, possibly death.  One or more of the symptoms may be absent.  Mammals present a similar picture, also under parenteral administration of fluorine.  The calcium content of the blood is lowered.  On respiration of gaseous fluorine compounds there are irritation symptoms from the mucous membranes of

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the eye and air-passage, and more or less pronounced symptoms due to absorption. 
     In acute intoxication the post-mortem findings are haemorrhagic gastroenteritis with a tendency to necrosis, acute toxic nephritis, and varying inflammatory changes in the lungs.  Dosis minima letalis depends upon the rate of absorption.  For the mammals generally used in the laboratory, d.m.l. is 23-90 mg. fluorine per Kg. body weight with peroral administration.  Man is much more sensitive, 6-9 mg. fluorine per kg. having caused death.  As a rule the lethal dose is much higher, about 5-15 g. sodium fluoride.  The lethal intoxication mostly have a course of hours only. 

                              Chronic Intoxication 

     The symptoms depend upon the dose, the time factor, the animal species, the age of the individual, the composition of the diet, and other factors, some of them unknown.  The injurious effect of fluorine is especially localized to bones and teeth.  The intoxication has three different forms which are capable of various combinations: (1) Degenerative tooth changes; (2) diffuse osteosclerosis; (3) a generalized bone disease accompanied by general symptoms and resembling the classical osteomalacia.  The smallest dose that can produce the various forms is uncertain as yet, but seems to rise from (1)  to (3). 
     Dental changes have been observed in man and in many animals.  Teeth already calcified are not affected, or only slightly so, by fluorine ingestion.  Teeth of parts of teeth calcifying during the period of ingestion display degenerative changes which seem to be pathognomonic.  In the lightest degrees the enamel is dull, chalky-white, with yellow, brown or black pigmentation of the areas of the teeth that are exposed to the light.  The more severe degrees are characterized by a hypoplastic, low-resistant enamel and dentine.  The abnormally heavy wear may cause considerable functional disturbances.  The teeth may present abnormities as to size, shape and position.  Histologically degenerative changes are observed of the enamel epithelium and formation of a hypoplastic, defectively calcified enamel and dentine.  The smallest dose capable of producing just recognizable changes in the rat (under the hand glass) is about 1 mg. fluorine per Kg. body weight per day.  Man is much more sensitive, as about 0.07 mg. fluorine per kg. daily will cause macroscopic changes.  These doses are not accompanied by other known injurious effects on the organism.
     Osteosclerosis in man is known as a systemic disease attacking all bones and

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especially the cancellous bones.  The X-ray examination reveals increased bone formation from both periosteum and endosteum (narrowed medullary cavity, periosteal deposits).  Cancellous bones densify and may give a diffuse, structureless shadow.  The osseous ligaments calcify,  especially those of the vertebral column.  Clinical observations include irregular thickenings of the subcutaneous bone surfaces and reduction of motility in the vertebral column and the thorax.  Post-mortem examination shows the bones to be massive, up to three times as heavy as normal bone, and relatively brittle.  The surface is uneven, ligaments and joints capsules calcified, but not the cartilage.  Microscopical examination reveals abnormally structured osseous tissue and excessive calcium deposition; the calcium salts are partly precipitated in the form of irregular granules.  The general condition is not affected, and no definite changes in other organs are observed; the teeth, however, show signs of increased formation of cement and dentine.  In man the disease is probably caused by 0.20-0.35mg. fluorine daily per kg. body weight.  The changes appear, however, only after several years of regular fluorine ingestion.  In the rat a similar, if not identical, condition can be produced experimentally by administration of fluorine over a period of months.
     The osteomalacic condition is known to occur in a number of mammals, but not in man.  It is a link in a more or less pronounced cachexia, manifested in the form of anorexia, emaciation, anaemia, coarse and untidy coat, and sundry eye changes.  Simultaneously there usually are signs of manifest or latent tetany, especially a stiff and laborious gait, a tendency to a reduction of blood calcium and tremor.  The osseous system displays varying formation of exostoses, especially on mandible and extremity bones.  On necropsy the bones are found to light and soft, spongiosa and compacta atrophic, but their thickness owing to periosteal deposits is sometimes surprising.  Microscopically the disease is characterized by the formation of an abnormally structured osseous tissue and a reduced and irregular calcification of the osteoid tissue, with tendency toward a granular precipitation of the calcium salts.  The pathoanatomical changes are similar to rickets and classical osteomalacia, but cannot be identified with them.  The parenchymatous organs, including the bone marrow, display varying degrees of degeneration phenomena, and the kidney also a mostly interstitial, contracting nephritis.  The renal effect is not equally great in the various animals.  The dose varies, but most frequently is about 15-20mg. fluorine daily per kg. body weight (growing rats, pigs,dogs).  Herbivora seem to be more sensitive.  The condition develops and death may occur  in the course of weeks or months.  An increased calcium requirement (growth, pregnancy, lactation) expedites the development of the intoxication.


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                             Mode of Action of Fluorine

     Fluorine is absorbed from the gastro-intestinal tract; gaseous fluorine compounds may be absorbed through the lung.  In what form fluorine is absorbed, circulated, stored or excreted is not known.  The heaviest storage takes place in the bones and teeth, probably as a mixture of hydroxyl- and fluorapatite. There is no deposition as crystalline calcium fluoride.  Fluorine is deposited diffusely in the osseous system, but especially in the cancellous bones.  Most probably fluorine can be deposited in preformed enamel.  All forms of chronic intoxication have an increased fluorine content in bone and tooth ash (from about 2 to 30%).  As a rule, fluorine in small quantities does not permeate placenta; yet the various species react differently.  In woman and the rat fluorine is excreted in the milk.
     In relatively large doses fluorine causes a negative calcium balance, presumably by monopolizing the calcium of the organism; calcium fluoride is very slowly soluble.  The calcioprive effect of fluorine cannot explain all the symptoms of the intoxication.  The osteosclerosis is accompanied by increased mineral deposition, the tooth changes occur at such small doses that direct calcium deficiency is out of the question.  Fluorine must be assumed to have a special effect on tissue.  The effect on osseous and dental tissue appears universally by (1) the formation of an abnormally structured organic matrix, and (2) a calcification anomaly, whereby the mineral salts of the bone are precipitated irregularly and in discrete granules.  Comparatively small doses seem to produce increased growth and increased calcification, comparatively large doses produce mostly atrophic processes and reduced calcification.  The osseous effect of fluorine probably is the result of an influence on enzymatic processes connected with the precipitation of the mineral salts, stimulative or inhibitive according to circumstances.  It is possible, but not probable, that the effect on the calcium metabolism is exerted via the parathyroid glands.  Fluorine affects several metabolic processes, and presumably the symptoms of intoxication have a complicated pathogenesis.  There is a special relation between vitamin C and fluorine. 

                             Possibilities of Intoxication


     Local corrosion phenomena are common in industry. Acute intoxication is particularly often the result of an accident (mistaken identity); suicide and murder are not unknown.  In the period from 1873-1935 a total of 112 cases of human poisoning were published, 60 of them fatal.  Many cases of animal poisoning have been described.      


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     The cases of spontaneous, chronic intoxication all arise from the ingestion of fluorine through the gastro-intestinal tract. Gaseous fluorine compounds may bring about chronic intoxication by absorption through the lung.  The known chronic intoxications comprise (1) mottled teeth, a dental disease that is endemic in man in certain parts of Europe, America, Africa and Asia; (2) osteosclerosis* an occupation disease among cryolite workers in Copenhagen; (3) osteomalacia, endemic among herbivora in the vicinity of certain manufacturing plants in Europe; (4) darmous, a dental and mandible disease in herbivora in certain parts of North Africa; (5)gaddur, a dental and osseous disease among herbivora in Iceland after volcanic eruption. 
     Greater or smaller possibilities of intoxication are offered by: Drinking water containing more than 1 mg. fluorine per liter; plants cultivated in regions where the soil is especially rich in fluorine; extraction and use of fluoric products.  A number of the uses of fluorine compounds are of interest, though they have not caused intoxication so far as is known, i.e. spraying of edible plants with fluorine compounds as insecticides, manuring with fluoric superphosphate, the addition of fluorine compounds to food for preserving purposes, and the therapeutic employment of fluorine compounds.

                                         Prophylaxis 


     Restriction of the trade in fluorine compounds with the highest acute toxicity.  Prohibition against the addition of fluorine compounds to food as preservatives.  Maximum limits for the fluorine content in edible plants sprayed with insecticides containing fluorine.  Prohibition against the employment of females and young people on work with fluorine compounds developing dust or vapour.  Protection and control of workers exposed to the effects of fluorine.  Recognition of chronic fluorine intoxication as an occupation disease rating for compensation.  Demand that industrial establishments should neutralize waste products containing fluorine.  Cessation of the therapeutic use of fluorine compounds for children.  Test for fluorine in the routine analysis of drinking water, food, and cases of poisoning with vague aetiology. 

*) Recently, the osteosclerosis has been observed in persons attacked by darmous and a man employed in a fertilizer factory, where he had handled rock phosphate containing fluorine  

                                         The End 


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