Friday, October 12, 2012

RATH/PAULING U.S. PATENT # 5278189

RATH/PAULING U.S. PATENT # 5278189

Prevention and treatment of occlusive cardiovascular disease with ascorbate and substances that inhibit the binding of lipoprotein (A)


PATN Patent Bibliographic Information

WKU     Patent Number:                          05278189
SRC     Series Code:                            7
APN     Application Number:                     5575168
APT     Application Type:                       1
ART     Art Unit:                               125
APD     Application Filing Date:                19900724
TTL     Title of Invention:                     Prevention and treatment of occlusive cardiovascular 
                                                        disease with ascorbate and substances that                             
                                                        inhibit the binding of lipoprotein (A)
ISD     Issue Date:                             19940111
NCL     Number of Claims:                       15
ECL     Exemplary Claim Number:                 1
EXA     Assistant Examiner:                     Henley, III; Raymond J.
EXP     Primary Examiner:                       Waddell; Frederick E.
NDR     Number of Drawings Sheets:              5
NFG     Number of Figures:                      6

INVT Inventor Information

NAM     Inventor Name:                          Rath; Matthias W.
STR     Inventor Street:                        Eberhardstrasse 12
CTY     Inventor City:                          7141 Kirchberg/Murr
CNT     Inventor Country:                       DEX

INVT  Inventor Information
NAM     Inventor Name:                          Pauling; Linus C.
STR     Inventor Street:                        15 Salmon Creek
CTY     Inventor City:                          Big Sur
STA     Inventor State:                         CA
ZIP     Inventor Zip Code:                      93920

RLAP Related U.S. Application Data

COD     Parent Code:                            72
APN     Application Number:                     533129
APD     Application Filing Date:                19900604
PSC     Parent Status Code:                     03

CLAS Classification

OCL     Original U.S. Classification:                   514561
XCL     Cross Reference Classification:                 514356
XCL     Cross Reference Classification:                 514474
XCL     Cross Reference Classification:                 514824
EDF     International Classification Edition Field:     5
ICL     International Classification:                   A61K 31195
ICL     International Classification:                   A61K 3134
ICL     International Classification:                   A61K 3144
FSC     Field of Search Class:                          514
FSS     Field of Search Subclass:                       474;561;562;564;567;824
;356

UREF U.S. Patent Reference

PNO     Patent Number:                                  3956504
ISD     Issue Date:                                     19760500
NAM     Patentee Name:                                  Sawyer
OCL     Original U.S. Classification:                   514567

U.S. Patent References

UREF U.S. Patent Reference

PNO     Patent Number:                                  4424232
ISD     Issue Date:                                     19840100
NAM     Patentee Name:                                  Parkinson
OCL     Original U.S. Classification:                   514474

UREF U.S. Patent Reference

PNO     Patent Number:                                  4600582
ISD     Issue Date:                                     19860700
NAM     Patentee Name:                                  Stevens et al.
OCL     Original U.S. Classification:                   514561

UREF U.S. Patent Reference

PNO     Patent Number:                                  4954521
ISD     Issue Date:                                     19900900
NAM     Patentee Name:                                  Sawyer et al.
OCL     Original U.S. Classification:                   514474

FREF Foreign Reference

PNO     Patent Number:                          60-4611
ISD     Issue Date:                             19850000
CNT     Foreign Reference Country Code:         JPX

FREF Foreign Reference

PNO     Patent Number:                          60-78560
ISD     Issue Date:                             19850000
CNT     Foreign Reference Country Code:         JPX

FREF Foreign Reference

PNO     Patent Number:                          60-87221
ISD     Issue Date:                             19850000
CNT     Foreign Reference Country Code:         JPX

OREF Other Reference

Chemical Abstracts 77(13):86318 (1972).

Vitamin C in Health and Disease, Basu et al., AVI Publishing Co., Inc. (1982) pp. 95-101.

Martindale, The Extra Pharmacopoeia, 28th edition (1982) p. 56, "Lysine Hydrochloride".

The Nutrition Desk Reference, Garrison et al, Keats Publishing Inc. (1985) pp. 172-177.

Rath, M. & L. Pauling, "Solution of the puzzle of human cardiovascular disease: Its primary cause is ascorbate deficinecy leading to the deposition of lipoprotein(a) and fibrinogen/fibrin in the vascular wall," J. Orthomolecular Med. (In Press 1991).

Markwardt, F. & H. P. Klocking, "Chemical control of hyperfibrinolytic states by synthetic inhibitors of fibrinolytic enzymes," Biomed. Biochim. Acta 42:725-730 (1983).

Werb, Z. et al., "Endogenous activation of latent collagenase by rheumatoid synovial cells," New England J. Med. 296(18):1017-1023 (1977).

Knox, E. G., "Ischaemic-heart-disease mortality and dietary intake of calcium," Lancet, i, pp. 1465-1467, Jun. 30, 1973.

Berg, K. "A new serum type system in man--The LP system," Acta Path. 59:369-382 (1963).

McLean, J. et al., "cDNA sequence of human apolipoprotein(a) is homologous to plasminogen," Nature 300:132-137 (1987).

Salonen, E-M, et al., "Lipoprotein(a) binds to fibronectin and has serine proteinase activity capable of cleaving it," EMBO J. 8(13):4035-4040 (1989.

Harpel, P.C. et al., "Plasmin catalyzes binding of lipoprotein(a) to immobilized fibrinogen and fibrin," Proc. Natl. Acad. Sci. USA 86:3847-3851 (1989).

Gonzalez-Gronow, M. et al., "Further characterization of the cellular plasminogen biding site: Evidence that Plasminogen 2 and Lipoprotein a compete for the same site," Biochemistry 28:2374-2377 (1989).

Hajjar, K. A. et al., "Lipoprotein(a) modulation of endothelial cell surface fibrinolysis and its potential role in atherosclerosis," Nature 339:303-305 (1989).

Armstrong, V. W. et al., "The association between serum Lp(a) concentrations and angiographically assessed coronary atherosclerosis"; Atheroscloerosis 62:249-257 (1986).

Dahlen, G. H. et al., "Association of levels of lipoprotein Lp(a), plasma lipids, and other lipoproteins with coronary artery disease documented by angiography," Circulation 74(4): 758-765 (1986).

Miles, L. A. et al., "A potential basis for the thrombotic risks associated with Lipoprotein (a)," Nature 339:301-302 (1989).

Zenker, G. et al., "Lipoprotein(a) as a strong indicator for cerebrovascular disease," Stroke 17(5)942-945 (1986).

Zechner, R. et al., "Fluctuations of plasma Lipoprotein-A concentrations during pregnancy and post partum," Metabolism 35(4):333-336 (1986).

Hoff, H. et al., "Serum Lp(a) level as a predictor of vein graft stenosis after coronary artery bypass surgery in patients," Circulation 77(6):1238-1244 (1988).

Rath, M. et al., "Detection and quantification of Lipoprotein(a) in the arterial wall of 107 coronary bypass patients," Arteriosclerosis 9(5):579-592 (1989).

Cushing, G. L. et al., "Quantitation and localization of Apolipoproteins [a] and B in Coronary artery bypass vein grafts resected at re-operation," Arteriosclerosis 9(5):593-603 (1989).

Bruckert, E. et al., "Increased serum levels of Lipoprotein(a) in diabetes mellitus and their reduction with glycemic control," JAMA 263(1):35-36 (1990).

Blumberg, B., et al., "A human lipoprotein polymorphism," J. Clin. Invest. 41:1936-1944 (1962).

Eaton, D. L., et al., "Partial amoni acid sequence of apolipoprotein(a) shows that it is homologous to plasminogen," Proc. Natl. Acad. Sci. USA, 84:3224-3228 (1987).

Wright, L. C. et al., "Elevated apolipoprotein(a) levels in cancer patients," Int. J. Cancer 43:241-244 (1989).

Som, S. et al., "Ascorbic acid metabolism in diabetes mellitus," Metabolism 30:572-577 (1981).

Maeda, S. et al., "Transient changes in serum lipoprotein(a) as an acute phase protein," Atherosclerosis 78:145-150 (1989).

Kapeghian, J. C. et al., "The effects of glucose on ascorbic acid uptake in heart, endothelial cells: Possible pathogenesis of diabetic angiopathies," Life Sci. 34:577 (1984).

Tomlinson, J. E. et al., "Rhesus monkey apolipoprotein(a)," J. Biol. Chem. 264:5957-5965 (1989).

Ginter, E. et al., "The effect of chronic hypovitaminosis C on the metabolism of cholesterol and athergenesis in guinea pigs," J. Atherosclerosis Res. 10:341-352 (1969).

LREP Legal Information

FRM     Legal Firm:                             Limbach & Limbach

ABST Abstract

A method is provided for prevention and treatment of cardiovascular disease, such as atherosclerosis, by administering therapeutically effective dosages of a drug comprised of ascorbate, lipoprotein(a) binding inhibitors, and antioxidants.

PARN Parent Case Text

This application is a continuation-in-part of application Ser. No. 07/533,129, filed Jun. 4, 1990.

BSUM Brief Summary

TECHNICAL FIELD

The present invention relates generally to the prevention and treatment of cardiovascular disease and more particularly to methods and compounds that inhibit the binding of lipoprotein (a) to components of the arterial wall.

BACKGROUND OF THE INVENTION

Lipoprotein(a) ("Lp(a)") was first identified by Blumberg, B. S., et al. (1962) J. Clin. Invest. 41: 1936-1944 , and Berg, K. (1963) Acta Pathol. 59: 369-382. The structure of Lp(a) resembles that of low-density lipoprotein ("LDL") in that both share a lipid apoprotein composition, mainly apolipoprotein B-100 ("apo B"), the ligand by which LDL binds to the LDL receptors present on the interior surfaces of arterial walls. The unique feature of Lp(a) is an additional glycoprotein, designated apoprotein(a), apo(a), which is linked to apo B by disulfide groups. The cDNA sequence of apo(a) shows a striking homology to plasminogen, with multiple repeats of kringle 4, one kringle 5, and a protease domain. The isoforms of apo(a) vary in the range of 300 to 800 kDa and differ mainly in their genetically determined number of kringle 4 structures. McLean, J. W., et al. (1987) Nature 300: 132-137. Apo(a) has no plasmin-like protease activity. Eaton, D. L., et al., (1987) Proc. Natl Acad. Sci. USA, 84: 3224-3228. Serine protease activity, however, has been demonstrated. Salonen, E., et al. (1989) EMBO J. 8: 4035-4040. Like plasminogen, Lp(a) has been shown to bind to lysine-sepharose, immobilized fibrin and fibrinogen, and the plasminogen receptor on endothelial cells. Harpel, P.C., et al. (1989) Proc. Natl. Acad. Sci. USA 86:3847-3851; Gonzalez-Gronow, M., et al. (1989) Biochemistry 28: 2374-2377; Miles, L. et al. (1989) Nature 339: 301-302; Hajjar, K. A., et al. (1989) Nature 339: 303-305. Furthermore, Lp(a) has been demonstrated to bind to other components of the arterial wall like fibronectin and glycosaminoglycans. The nature of these bindings, however, is poorly understood.

Essentially all human blood contains lipoprotein(a); however, there can a thousand-fold range in its plasma concentration between individuals. High levels of Lp(a) are associated with a high incidence of cardiovascular disease. Armstrong, V. W., et al. (1986) Atherosclerosis 62: 249-257; Dahlen, G., et al. (1986) Circulation 74: 758-765; Miles, L. A., et al. (1989) Nature 339: 301-302; Zenker, G., et al. (1986). Stroke 17: 942-945 (The term occlusive cardiovascular disease will be used hereafter as including all pathological states leading to a narrowing and/or occlusion of blood vessels throughout the body, but particularly atherosclerosis, thrombosis and other related pathological states, especially as occurs in the arteries of the heart muscle and the brain.)

For some time, general medical practice has focused on the role of LDL, th e so called "bad cholesterol," in occlusive cardiovascular disease. A great many studies have been published ostensibly linking occlusive cardiovascular disease with elevated levels of LDL. As a result, most therapies for the treatment and prevention of arteriosclerosis rely on drugs and methods for the reduction of serum levels of LDL's. Such therapies have had mixed results. The efficacy of such approaches to the problem of occlusive cardiovascular disease continues to be major source of debate.

There exists therefore a need for a drug therapy for reducing the binding of Lp(a) to vessel walls, for reducing the overall level of Lp(a) in the circulatory system and for promoting the release of existing deposits of Lp(a) on vessel walls.

SUMMARY OF THE INVENTION

The foregoing needs in the treatment and prevention of cardiovascular disease are met by the methods and compositions of the present invention.

A method is provided for the treatment of occlusive cardiovascular disease , comprising the step of administering to a subject an effective amount of ascorbate and one or more binding inhibitors, as a mixture or as a compound comprising ascorbate covalently linked with binding inhibitors, which inhibit the binding of Lp(a) to blood vessel walls, such as arterial walls. This effect may also be obtained by administering an effective amount of one or more inhibitors, without ascorbate. The term binding inhibitor throughout the specification and claims is intended to include all substances that have an affinity for the lysine binding site present on the interior walls of blood vessels, particularly arteries, the site of Lp(a) binding. Most of these substances compete with plasmin for the lysine binding site and some of these compounds, in high doses, are in clinical use for the treatment of hyperfibrinolytic states.

A method is further provided for the prevention of atherosclerosis comprising the step of administering to a subject an effective amount of ascorbate and one or more binding inhibitors as previously discussed but further comprising one or more antioxidants. The term antioxidant throughout the specification and the claims is intended to exclude ascorbate which has as one of its chemical properties a potent antioxidant effect.

It is thus an object of the invention to provide a method for treatment of occlusive cardiovascular disease by administering to a subject an effective amount of ascorbate and one or more binding inhibitors, or an effective amount of one or a mixture of binding inhibitors.

It is another object of the invention to provide a method for preventing o f occlusive cardiovascular disease, by administering to a subject an amount of ascorbate effective to lower the amount of Lp(a) in the plasma of the subject.

Yet another object of the present invention is to provide a method for prevention of cardiovascular disease by administering to a subject an effective amount of ascorbate and one or more binding inhibitors, or an effective amount of one or more binding inhibitors.

A further object of the present invention is to provide a pharmaceutically acceptable agent for the treatment of occlusive cardiovascular disease.

Still another object of the present invention is to provide a pharmaceutically acceptable agent for the prevention of cardiovascular disease.

These and other objects will be more readily understood upon consideration of the following detailed descriptions of embodiments of the invention and the drawings.

DRWD Drawing Description

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an immunoblot of the plasma of guinea pigs form from the test described in Example 1.

FIG. 2A a photograph of the aorta of a guinea pig receiving an adequate amount of ascorbate from the test diet in Example 1.

FIG. 2B is a photograph of an aorta of a guinea pig receiving a hypoascorbic diet after three weeks from the test diet in Example 1.

FIG. 3 is an immunoblot of plasma and tissue of guinea pigs from the test shown in Example 2.

FIG. 4 shows the potential mechanism of binding inhibitors in the therapy for atherosclerosis.

FIG. 5 show the potential mechanism of ascorbate in the binding of Lp(a) t o the arterial wall.

DETD Detail Description

DETAILED DESCRIPTION OF THE INVENTION

Our invention is based in part on our discovery that animals which have lost the ability to produce ascorbate, such as higher primates and guinea pigs, uniformly produce Lp(a). Most animals which possess the ability to synthesize ascorbate generally do not produce Lp(a). Further, we have found that ascorbate deficiency in humans and guinea pigs tends to raise Lp(a) levels and causes atherosclerosis by the deposition of Lp(a) in the arterial wall, from which we conclude that ascorbate administration lowers plasma Lp(a) levels.

We have also discovered that substances that inhibit the binding of Lp(a) to components of the arterial wall, particularly to fibrinogen, fibrin and fibrin degradation products herein identified as binding inhibitors, such as lysine or .epsilon.-aminocaproic acid used alone or in combination with ascorbate, cause release of Lp(a) from the arterial wall. Thus, ascorbate and such binding inhibitors are not only useful for the prevention of occlusive cardiovascular disease, but also for the treatment of such disease. The present invention, then, provides methods and pharmaceutical agents for the both the treatment and prevention of occlusive cardiovascular disease in vivo.

GENERAL APPLICATIONS

The present invention provides a method and pharmaceutical agent for the treatment and prevention of occlusive cardiovascular disease generally, by administering to a subject an effective amount of ascorbate and one or more binding inhibitors. Throughout the specification and claims, the term binding inhibitor is intended to cover any substance which has as at least one of its chemical properties the ability to inhibit the binding of Lp(a) to blood vessel wall components, particularly to fibrin or fibrinogen. As used herein, the term "ascorbate" includes any pharmaceutically acceptable salt of ascorbate, including sodium ascorbate, as well as ascorbic acid itself. Binding inhibitors include, but are not limited to .epsilon.-aminocaproic acid, lysine, tranexamic acid (4-aminomethylcyclohexane carboxylic acid), p-aminomethylbenzoic acid, p-benzylamine sulfuric acid, o-N-acetyl-lysine-methyl ester, PROBUCOL (a compound comprised of 2 butyl hydroxy tocopherol groups linked together by a disulphide group), Aprotinin, trans-4-aminomethylcyclohexanecarboxylic acid (AMCA), and benzamidine derivatives such as amidinophenylpyruvic acid (APPA) and 1-naphthyl-(1)-3-(6-amidinonaphthyl-(2))-propanone-1 HCl (NANP). An effective amount of a binding inhibitor or a mixture of binding inhibitors may also be used, without ascorbate. Other substances used in the treatment of occlusive cardiovascular disease may be co-administered, including antioxidants, such as tocopherol, carotene and related substances; vitamins; provitamins; trace elements; lipid-lowering drugs, such as hydroxy-methyl-glutaryl coenzyme A reductase inhibitors, nicotinic acid, fibrates, bile acid sequestrants; and mixtures of any two or more of these substances.

Although ascorbate can be used alone or in varying combinations with one o r more representative constituents of the above classes of compounds, we prefer when treating a pre-existing cardiovascular condition to combine ascorbate with at least one each of the binding inhibitors, antioxidants and lipid lowering drugs elements in the dosages (per kilogram of body weight per day (Kg BW/d)) provided in Table 1. It should be noted that Table 1 provides differing concentration ranges of each constituent, depending upon whether the agent is to be administered orally or parenterally. The variance in dosages is reflective of variation in disease severity. It will be realized therefore that if the subject has been diagnosed for advanced stages of atherosclerosis,

dosages at the higher end of this range can be utilized. However, if only prevention of an atherosclerosis condition is the object, dosages at the lower end of this range can be utilized.

As an alternative, a pharmaceutical agent identical to the one just described, but omitting ascorbate, may be employed.

Where ascorbate and binding inhibitors are utilized in the same agent, the y may simply be mixed or may be chemically combined using synthesis methods well known in the art, such as compounds in which ascorbate and the inhibitor are covalently linked, or form ionically bound salts. For example, ascorbate may be bound covalently to lysine, other amino acids, or .epsilon.-aminocaproic acid by ester linkages. Ascorbyl .epsilon.-aminocaproate is such an example. In this form the ascorbate moiety may be particularly effective in preventing undesirable lipid peroxidation.

In the case of oral administration, a pharmaceutically acceptable and otherwise inert carrier may be employed. Thus, when administered orally, the active ingredients may be administered in tablet form. The tablet may contain a binder such as tragacanth, corn starch or gelatin; a disintegrating agent, such as alginic acid, and/or a lubricant such as magnesium stearate. If administration in liquid form is desired, sweetening and/or flavoring agents may be used. If administration is by parenteral injection, in isotonic saline, a phosphate buffered solution or the like, may be used as a pharmaceutically acceptable carrier.

The advisability of using binding inhibitors in treating occlusive cardiovascular disease will depend to some extent on the subject's general health, particularly with regard to hyperfibrinolytic conditions. Most binding inhibitors (except lysine) are used clinically to treat such conditions. As a result, monitoring of the subject's coagulation and fibrinolytic sysem is recommended before and during treatment for occlusive cardiovascular disease. Long-term administration of binding inhibitors will require formulations in which the dosages of binding inhibitors are in the lower ranges of the dosages given in Table 1.

Prevention, as contrasted with treatment, of cardiovascular disease may be accomplished by oral or parenteral administration of ascorbate alone. Table 1 gives a range of ascorbate concentrations sufficient to lower the serum Lp(a) concentration.

Preferably the prevention of the occlusive cardiovascular disease accordin g to the invention is accomplished by use of a physical mixture of ascorbate and one or more binding inhibitors, or by use of a compound comprising covalently linked ascorbate with one or more of the binding inhibitors, which inhibit binding of Lp(a) to the arterial wall. A binding inhibitor or mixture of binding inhibitors may also be administered without ascorbate to prevent Lp(a)-associated occlusive cardiovascular disease.

To optimize the therapeutic effect of the release of Lp(a) from the blood vessel walls, the ascorbate and the binding inhibitors described above may be separately administered. Further optimization of therapeutic effect can be gained by using a time release composition to achieve relatively constant serum concentrations of the agent through time.

TBL TABLE 1

     ______________________________________
     DOSAGES OF COMPONENTS IN THE DRUG
     COMPOSITIONS OF THE PRESENT INVENTION
                Oral        Parenteral
                Administration
                            Administration
     ______________________________________
     Ascorbate:   5 mg-2500 mg/kg
                                25 mg-2500 mg/kg
                  bw/d          bw/d
     Binding inhibitors:
     EACA         5 mg-500 mg/kg
                                same
                  bw/d
     Tranexamic Acid
                  1 mg-100 mg/kg
                                same
                  bw/d
     Para-aminomethyl
                  1 mg-30 mg/kg same
     benzoic acid bw/d
     Lysine       5-500 mg/kg bw/d
                                same
     Antioxidants:
     Tocopherol   0,1 IU-20 IU/kg
                                same
                  bw/d
     Carotene     100 IU-1000 IU/kg
                                same
                  bw/d
     Lipid
     Lowering Drugs:
     Nicotinic Acid
                  1 mg-300 mg/kg
                  bw/d
     HMG-CoA      0.1-10 mg/kg bw/d
     Fibrates     0.1-20 mg/kg bw/d
     Probucol     0.1-20 mg/kg bw/d
     Bile Acid Sequestrants
                  10-400 mg/kg bw/d
     ______________________________________

TBL TABLE 2

     ______________________________________
     CONCENTRATION OF COMPONENTS IN THE
     SOLUTION OF THE PRESENT INVENTION
     ______________________________________
     Ascorbate           50-5000  mg/l
     Binding inhibitors
     EACA                2-2000   mg/l
     Tranexamic Acid     1-300    mg/l
     Para-aminomethyl    1-200    mg/l
     benzoic acid
     Lysine              10-5000  mg/l
     Antioxidants
     Tocopherol          1-1000   mg/l
     Carotene            0.1-100  mg/l
     ______________________________________

EXPERIMENTAL

Having disclosed the preferred embodiment of the present invention, the following examples are provided by way of illustration only and are not intended to limit the invention in any way.

EXAMPLE 1

Because of its metabolic similarity to man, with resepct to the metabolism of ascorbate and Lp(a), the guinea pig was used in this example.

No study has been previously reported in the guinea pig to identify the lopoprotein involved as risk factors in plasma and as constituents of the atherosclerotic plaque.

Three female Gartly guinea pigs with an average weight of 800 g and an approximate age of 1 year wer stuided. One animal received an extreme hypoascorbic diet with 1 mg ascorbate/kg body weight/d. Another animal received 4 mg/kg BW/d. The third animal served as a control receiving 40 mg ascorbate/kg/BW/d)

Blood was drawn by heart puncture from the anesthetized animals and collected into EDTA containing tubes at the beginning, after 10 days, and after 3 weeks, when the animals were sacrificed. Plasma was stored at - -80.degree. C. until analyzed. Lp(a) was detected in the plasma of the guinea pigs by use of SDS-polyacrylamide gels according to Neville (J. Biol. Chem., 246, 6328-6334 (1971)) followed by Western blotting (Beisiegel, et al., J. Biol. Chem., 257, 13150-13156 (1982)). 40 .mu.l of plasma and 20 mg of arterial wall homogenate were applied in delipidated form per lane of the gel. The immunodetection of apo(a) was performed using a polyclonal anti-human apo(a) antibody (Immuno, Vienna, Austria) followed by a rabbit anti-sheep antibody (Sigma) and the gold-conjugated goat anti-rabbit anti-body with subsequent silver enhancement (Bio-Rad). The determinations of cholesterol and triglycerides were done at California Veterinary Diagnostics (Sacramento) using the enzyme assay of Boehringer Mannheim. Plasma ascorbate was determined by the dinitrophenylhydrazine method (Schaffer, et al., J. Biol. Chem., 212, 59 (1955)).

Vitamin C deficiency in the diet led to an increase of Lp(a) in the plasma of the guinea pig indicated by a clear band in the immunoblot of the plasma after 10 and 20 days of a hypoascorbic diet (FIG. 1). At necropsy the animals were anesthetized with metophase and were exsanguinated. Aorta, heart and various other organs were taken for biochemical and histological analysis. The aorta was excised, the adventitial fat was carefully removed, and the vessel was opened longitudinally. Subsequently the aorta was placed on a dark metric paper and a color slide was taken. The picture was projected and thereby magnified by an approximate factor 10. The circumference of the ascending aorta, the aortic arch and thoracic aorta as well as the atherosclerotic lesions in this area were marked and measured with a digitalized planimetry system. The degree of atherosclerosis was expressed by the ratio of plaque area to the total aortic area defined. The difference in the 3 one-year old animals of the experiment was significant and pronounced lesions were observed in the ascending aorta and the arch of the vitamin C deficient animal (FIG. 2B).

EXAMPLE 2

To confirm the data obtained in Example 1, a second guinea pig experiment was conducted, using 33 male animals with a mean weight of 550 g and an approximate age of 5 months. One group of 8 animals served as a control and received 40 mg ascorbate/kg BW/d (group A). To induce hypoascorbemia 16 animals were fed 2 mg ascorbate/kd/d (group B). Group A and half of the animals of group B (progression sub-group) were sacrificed after 5 weeks as described above. Half of group B was kept for 2 more weeks, receiving daily intraperitoneal injection of 1.3 g sodium ascorbate/Kg BW/d as a daily intra peritoneal injection with the intention to reduce the extent of atherosclerosis lesions. After this period these animals also were sacrificed.

Plasma ascorbate levels were negatively correlated with the degree of the atherosclerotic lesion. Total cholesterol levels increased significantly during ascorbic acid deficiency (Table 3).

The aortas of the guinea pigs receiving a sufficient amount of ascorbate were essentially plaque free, with minimal thickening of the intima in the ascending region. In contrast, the ascorbate-deficient animals exhibited fatty streak-like lesions, covering most parts of the ascending aorta and the aortic arch. In most cases the branching regions of the intercostal arteries of the aorta exhibited similar lipid deposits. The difference in the precentage of lesion area between the control animals and the hypoascorbic diet animals was 25% deposition of lipids and liporpoteins in the arterial wall.

TBL TABLE 3

     ______________________________________
     MEAN PLASMA
     PARAMETERS OF THE DIFFERENT GROUPS
     IN RELATION TO THE AREA OF AORTIC LESIONS
                                  Regression
                        Scurvy    (after
               Control  (progress)
                                  Scurvy)
     ______________________________________
     Plasma      39         54        33
     Chloesterol
     (mg/dl)
     Total Plasma
                 5.03       3.01      20.64
     Ascorbic
     Acid .mu.g/ml
     Atheroscl.  --         25        19
     Lesion
     (Percent of
     Aorta Thorac.
     Surface)
     ______________________________________

EXAMPLE 3

Human arterial wall was obtained post mortem from the aorta ascendens. The tissue showed homogeneous intimal thickening (early atherosclerotic lesion). It was cut into pieces, with 100 mg of the cut up tissue homogenized in a glass potter for a 1 minute in 2.5 ml of the following solutions:

TBL  ______________________________________
     PBS (Dulbeco) +    50 mg/ml
     NaAscorbate
     PBS + EACS         50 mg/ml
     PBS + Tranexamic Acid
                        50 mg/ml
     PBS + NaAscorbate +
                        50 mg/ml
     Tranexamic Acid
     ______________________________________

Results of this treatment are given in Table 4 and show that, compared to the control solution, a considerable amount of Lp(a) was released from the interior arterial wall.

TBL TABLE 4

     __________________________________________________________________________
     Lp(a) RELEASED FROM HUMAN AORTA
     IN RELATION TO SPECIFIC BINDING INHIBITORS
      ##STR1##
     __________________________________________________________________________

By now it is apparent that the methods and compositions of the present invention meet longstanding meeds in the field of prevention and treatment of occlusive cardiovascular disease. Although preferred embodiments and examples have been disclosed, it is understood that the invention is in no way limited by them, but rather is defined by the claims that follow and equivalents thereof.

CLMS Claims

STM Claim Statement: What is claimed is:

NUM Claim Number: 1.

  • 1. A pharmaceutical composition consisting essentially of ascorbate, traexamic acid, lysine and nicotinic acid said ingredients in an amount effective to treat Lp (a)-associated occlusive cardiovascular disease.
  • NUM Claim Number: 2. 2. A method of treatment of occlusive cardiovascular disease comprising th e step of administering to a subject a therapeutic composition comprising ascorbate and tranexamic acid in an amount sufficient to decrease the binding of liproprotein (a) to blood vessel walls.
  • NUM Claim Number: 3. 3. A method according to claim 2 wherein said ascorbate is selected from the group consisting of pharmaceutically acceptable ascorbate salts, ascorbic acid and mixtures thereof.
  • NUM Claim Number: 4. 4. A method for treatment of occlusive cardiovascular disease comprising the step of administering to a subject a therapeutic composition comprising tranexamic acid in an amount sufficient to decrease the binding of lipoprotein(a) to blood vessel walls.
  • NUM Claim Number: 5. 5. A method according to any one of the claims 2, 3 or 4 wherein occlusive cardiovascular disease comprises atherosclerosis and thrombosis and said vessel walls comprise arterial walls.
  • NUM Claim Number: 6. 6. A method according to any one of the claims 2, 3 or 4 wherein said therapeutic composition is administered to a subject at risk of developing and in need of preventing for Lp (a)-associated occlusive cardiovascular disease in an amount of effective to inhibit binding of liproprotein(a) to blood vessel walls.
  • NUM Claim Number: 7. 7. A method according to any one of the claims 2, 3 or 4 wherein said therapeutic composition is administered in an amount effective to release at least some lipoprotein(a) bound to blood vessels.
  • NUM Claim Number: 8. 8. A method according to any one of the claims 2, 3 or 4 wherein said therapeutic composition is administered in an amount effective to reduce concentrations of lipoprotein(a) in blood serum.
  • NUM Claim Number: 9. 9. A method for prevention of cardiovascular disease comprising the step o f administering to a subject at risk of developing and in need of prevention for Lp (a)-associated occlusive cardiovascular disease a therapeutic composition comprising ascorbate and tranexamic acid in an amount sufficient to decrease binding of liproprotein(a) to blood vessel walls.
  • NUM Claim Number: 10. 10. A method according to claim 9 wherein said ascorbate is selected from the group consisting of pharmaceutically acceptable salts of ascorbate, ascorbic acid and mixtures thereof.
  • NUM Claim Number: 11. 11. A method of prevention of occlusive cardiovascular disease comprising the step of administering to a subject at risk of developing and in need of prevention for Lp (a)-associated occlusive cardiovascular disease a therapeutic composition comprising tranexamic acid in an amount sufficient to decrease binding of lipoprotein(a) to blood vessel walls.
  • NUM Claim Number: 12. 12. A method according to any one of claims 9, 10 or 11 wherein said therapeutic composition is administered in an amount effective to inhibit binding of lipoprotein(a) to the blood vessel walls.
  • NUM Claim Number: 13. 13. A method according to any one of claims 9, 10, 11, or 12 wherein said therapeutic composition is administered in an amount effective to reduce concentrations of lipoprotein(a) in blood serum.
  • NUM Claim Number: 14. 14. A method according to any one of claims 2, 3, 4 or 9 wherein the administration is oral.
  • NUM Claim Number: 15. 15. A method according to any one of claims 2, 3, 4 or 9 wherein administration is by parenteral application.

Source: Advanced Health Plan

MORE on Linus Pauling, Mathias Rath, Ascorbates and Cardiovascular Disease

cure for heart disease


Thursday, May 17, 2012

BAKING SODA and CANCER CELLS

The cancer industry is closing in on baking soda and beginning to do research in earnest about sodium bicarbonate and how it is a primary tool in the treatment of fungus. Cancer is a fungus, can be caused by a fungus, or is accompanied by late-stage fungal infections, and now the Mayo Clinic confirms this. They are not the first to say so though. Many, even from the official world of orthodox oncology, recognize the similarities of cancer and fungal infections, the decay that ties these two together in a dance that all too often ends in miserable death.


The Mayo Clinic is saying that a fungal infection of the gastrointestinal tract mimics cancer and inflammatory bowel disease. The invasive fungus, Basidiobolus ranarum, is typically found in the soil, decaying organic matter and the gastrointestinal tracts of fish, reptiles, amphibians, and bats.

Patients with this fungal infection had non-specific symptoms such as abdominal pain or a mass that could be felt on examination. Before a conclusive diagnosis of the fungal infection was made, most patients were thought to have abdominal cancer, inflammatory bowel disease or diverticulitis. Surgical resection of the area of involvement and prolonged antifungal therapy successfully treated most patients.

Interestingly, a few years ago researchers at Johns Hopkins were surprised that the drug itraconazole, commonly used to treat toenail fungus, can also block angiogenesis, the growth of new blood vessels commonly seen in cancers. Tumor angiogenesis is the proliferation of a network of blood vessels that penetrates into cancerous growths, supplying nutrients and oxygen and removing waste products. Cancer researchers studying the conditions necessary for cancer metastasis have discovered that angiogenesis is one of the critical events required for metasteses to occur. In mice induced to have excess blood vessel growth, treatment with itraconazole reduced blood vessel growth by 67% compared to placebo. "We were surprised, to say the least, that itraconazole popped up as a potential blocker of angiogenesis," says Dr. Jun O. Liu, professor of pharmacology. "We couldn't have predicted that an antifungal drug would have such a role." Itraconazole was found to reduce the numbers of circulating cancer cells, prevent the worsening of prostate cancers, and delay the need for chemotherapy. However, it has serious side effects when given in the necessary high dosages that include hypertension, low potassium levels and fluid retention. These side effects require treatment with other medications. Effects of high doses of itraconazole could lead to heart failure.

For two decades John Hopkins has recognized the increasing frequency of severe fungal infections in patients with neoplastic diseases. Most fungal infections are caused by the commonly recognized opportunistic fungi Candida spp and Aspergillus spp, and the pathogenic fungi Cryptococcus neoformans, Histoplasma capsulatum, Coccidiodes immitis, and less often by Blastomyces dermatidis. However, recently newer pathogens such as Pheohyphomycetes, Hyalohyphomycetes, Zygomycetes and other fungi of emerging importance such as Torulopsis glabrata, Trichosporon beigelii, Malassezia spp, Saccharomyces spp, Hansenula spp, Rhodotorula spp, and Geotrichum candidum have appeared as significant causes of infection in this patient population.

Dr. Tullio Simoncini does not say that cancer is caused by yeast; what he is telling the world is that the cancer is a yeast overgrowth. What causes the cancer (or a yeast-filled tumor) is another thing. Simoncini has always insisted that tumors are white because they are fungi. Some have made fun of him, but looking around at the extremely sparse information about the subject, I ran into one person saying:

"If someone had asked me a year ago what color the inside of a tumor was, I would have guessed red and gray. When they did the biopsy, I asked to see the tissue specimens: five quarter-inch to half-inch strings of vermicelli (Italian for little worms) with little streakings of blood. They didn't look evil to me, just strings of fat. The entire mass was white inside as the pathology report stated.

Specialists in throat and mouth cancer say that cancers can be red or white patches: any patch that appears randomly and is red or white in color could be a mouth cancer symptom. The white patches in the mouth are called leukoplakia and the red patches are called erythroplakia, which are pre-cancerous conditions. Though these red or white patches are not always cancerous, it could be the result of a fungal infection caused by Candida called thrush. Thrush will lead to a red patch that often bleeds after the white patch disappears. A small amount of this fungus lives in your mouth most of the time. It is usually kept in check by your immune system and other types of germs that also normally live in your mouth. However, when your immune system is weak, the fungus can grow.

Fungal Mycotoxins

It just so happens that a toxin produced by mold on nuts and grains can cause liver cancer, according to University of California Irvine Researchers. And a French case-control study of 1,010 breast cancer cases and 1,950 controls with nonmalignant diseases found that breast cancer was associated with increased frequency of mold-fermented cheese consumption. Fungi produce mycotoxins, which can kill us or cause cancer.

Dr. Wang and Groopman from the Environmental Health Sciences Department at Johns Hopkins published on the effects of mold toxins on DNA in Mutation Research, a leading cancer journal. They said mycotoxins with carcinogenic potency include aflatoxins, sterigmatocystin, ochratoxin, fumonisins, zearalenone, and some Penicillium toxins. Most of these carcinogenic mycotoxins are genotoxic agents. Aflatoxin is a potent genotoxic agent, is mutagenic in many model systems and produces chromosomal aberrations, micronuclei, sister chromatid exchange, unscheduled DNA synthesis, and chromosomal strand breaks. Most strikingly, the relationship between aflatoxin exposure and development of human hepatocellular carcinoma (liver cancer) is demonstrated by studies.

Harrison et al. (1993) examined human breast cancer tissue for evidence of the presence of aflatoxin. The researchers examined human DNA from a variety of tissues and organs to identify and quantify aflatoxin DNA-adducts. Such adducts are considered to be proof of the mycotoxin's presence in a particular tissue. Aflatoxins may in fact be a risk factor for cancer induction in a variety of organs in man, in the same manner as that of cigarette smoking.

DNA from normal and tumorous tissue obtained from patients with cancer of the breast was examined. Tumor tissues had higher aflatoxin-adduct levels than did normal tissue from the same individual. The result of this study verifies the presence of carcinogenic aflatoxin within the cancer tissue and thus implicates aflatoxin as a cause of breast cancer. That is the same as saying cancer is a fungus or is caused by a fungus and this is what Dr. Simoncini has been saying all along.

Intensive Care Units are particularly on alert with immunocompromised and oncology patients for fungal infections. "Patients with brain tumors used to have a life expectancy of 3-12 months, but better treatment has allowed them to live a bit longer," said Brenda Shelton, clinical nurse specialist at the Sidney Kimmel Comprehensive Cancer Center, Johns Hopkins University, Baltimore. "The last two brain tumor ICU patients we treated died of infection, not of their disease. One patient had a rare fungus, and the other had candidemia. Years ago, you would not see most of these fungal infections in patients with brain tumors because they would not live long enough."

"The biggest misconception is the belief that fungal infections are rare," Shelton said. "Another misconception is fungal infections are like every other severe infection. They are harder to manage, harder to eradicate and more frequent than people realize." One of the most common complications involved in treating patients with hematologic cancer is fungal infections.

Aspergillus niger fungal infection in human lungs produces large amounts of oxalic acid, which is extremely toxic to the blood vessels and which may cause fatal pulmonary hemorrhages. Consequently, oxalic acid (calcium oxalate crystals) in the sputum or lung specimens of patients is also an indication of an Aspergillus infection of the lung. These calcium oxalate crystals are the same as the calcium oxalate found in breast cancers. The presence of oxalates in the breast is indicative of the presence of fungi interwoven within the stages of breast cancer development. Since humans do not make oxalic acid themselves, this is an appropriate conclusion.

Dr. Robert Young states, "Bacteria, yeast/fungi, and mold are not the cause of a cancerous condition but are the result and the evidence of cells and tissues biologically transforming from a healthy state and to an unhealthy state." Dr. Young astutely observed that, "over-acidification of the body leads to the development of chronic yeast and fungal infections and ultimately a cancerous condition of the cells and tissues."

If one has cancer, chances are pretty good that one also has a fungal infection to one degree or another.

According to The Home Medical Encyclopedia, in 1963 about one-half of all Americans suffered from an "unrecognized" systemic fungal condition. Far more Americans suffer from fungal infections today as antibiotics, hormone replacement therapies, and birth control pills continue to be consumed like candy. Thus more and more children are becoming infected with candidal meningitis or viral meningitis, which means their systems are suffering under the weight of fungi who put out an assortment of poisons - or mycotoxins.

Sodium Bicarbonate is an Antifungal Agent

The current controversy over sodium bicarbonate and its use in oncology might be relatively new but baking soda has a long history of helping people get through the worst medical conditions. The Eloquent Peasant, an Egyptian literary work dated around 2000 B.C., refers to a peddler selling natron, a natural blend of sodium bicarbonate, chloride and sodium carbonate used in mummification, just one of hundreds of uses this compound has been put to. Baking soda's first widespread use was probably as a leavening agent for bread and other baked goods. It has been used commercially since 1775, although the now-famous Arm & Hammer brand wasn't introduced until 1867.

Sodium bicarbonate (Na2HCO3) is recognized by most as ordinary baking soda, which is found in deposits around the globe. Its backbone characteristic is to maintain balance of carbon dioxide, bicarbonate and pH. Sodium bicarbonate is available and sold in every supermarket and pharmacy in the world and is widely used in emergency rooms and intensive care wards in injectable forms but is sold as a common household substance that is used for hundreds of different things.

Read my book, Sodium Bicarbonate, and see that something as inexpensive as baking soda will outperform the most expensive pharmaceuticals. Across a wide range of disorders, including cancer and diabetes, we find conclusive evidence and plenty of theoretical backing to suggest that sodium bicarbonate is a frontline universal medicine that should be employed by all practitioners of the healing and medical arts for a broad range of disorders that are afflicting contemporary man.

For all the references, sources and more articles, please visit Dr. Mark Sircus blog.

About the author:

Mark A. Sircus, Ac., OMD, is director of the International Medical Veritas Association (IMVA) http://www.imva.info/.

Dr. Sircus was trained in acupuncture and oriental medicine at the Institute of Traditional Medicine in Sante Fe, N.M., and at the School of Traditional Medicine of New England in Boston. He served at the Central Public Hospital of Pochutla in Mexico, and was awarded the title of doctor of oriental medicine for his work. He was one of the first nationally certified acupuncturists in the United States. Dr. Sircus's IMVA is dedicated to unifying the various disciplines in medicine with the goal of creating a new dawn in healthcare.

He is particularly concerned about the effect vaccinations have on vulnerable infants and is identifying the common thread of many toxic agents that are dramatically threatening present and future generations of children. His book, The Terror of Pediatric Medicine, is a free e-book offered on his web site. Humane Pediatrics will be an e-book available early in 2011 and then quickly as possible put into print.

Dr. Sircus is a most prolific and courageous writer and one can read through hundreds of pages on his various web sites.

He has recently released a number of e-books including Winning the War Against Cancer, Survival Medicine for the 21st Century, Sodium Bicarbonate, Rich Man’s Poor Man’s Cancer Treatment, New Paradigms in Diabetic Care and Bringing Back the Universal Medicine: IODINE.

Dr. Sircus is a pioneer in the area of natural detoxification and chelation of toxic chemicals and heavy metals. He is also a champion of the medicinal value of minerals and seawater.

Transdermal Magnesium Therapy, his first published work, offers a stunning breakthrough in medicine, an entirely new way to supplement magnesium that naturally increases DHEA levels, brings cellular magnesium levels up quickly, relieves pain, brings down blood pressure and pushes cell physiology in a positive direction. Magnesium chloride delivered transdermally brings a quick release from a broad range of conditions. His second edition of Transdermal Magnesium Therapy will be out shortly. In addition he writes critically about the political and financial crises occurring around us.

International Medical Veritas Association: http://www.imva.info//

http://publications.imva.info/

Source: http://cancerstopped.blogspot.com/2012/05/baking-soda-and-cancer-cells.html


Tuesday, May 15, 2012

FOR IMMEDIATE RELEASE


Orthomolecular Medicine News Service, May 14, 2012

Fukushima Radiation Release is Worse than You Have Been Told

What You Can Do to Protect Yourself and those you care for.

by Steve Hickey, PhD; Atsuo Yanagisawa, MD, PhD; Andrew W. Saul, PhD; Gert E. Schuitemaker, PhD; Damien Downing, MD

(OMNS May 14, 2012) People have been misinformed about the tragedy at Fukushima and its consequences. There is a continuing cover up, the reactors have not been stabilized, and radiation continues to be released. The Japanese College of Intravenous Therapy (JCIT) has recently released a video for people wishing to learn more about how to protect themselves from contamination by taking large doses of vitamin C.

Part 1 : http://www.youtube.com/watch?v=Rbm_MH3nSdM

Part 2 : http://www.youtube.com/watch?v=j4cyzts3lMo

Part 3 : http://www.youtube.com/watch?v=ZYiRo2Oucfo

Part 4 : http://www.youtube.com/watch?v=51Ie8FuuYJw

All four parts of the video are also available here http://firstlaw.wordpress.com/. Readers may link to, embed in their webpages, and make copies of the video for free distribution.

Japanese Government Minimizes Danger; Ignores Vitamin C

In the fall of 2011, JCIT presented a study that Fukushima workers had abnormality gene expression, which may be avoided using dietary antioxidants, especially vitamin C. The data was presented in Japan, Taiwan, and Korea. The JCIT sent letters to the government urging the government to tell the people how they may protect themselves from radiation. To date, the recommendation has been ignored by Japanese government and TEPCO (Tokyo Electric Power Company).

Linus Pauling gained the Nobel Peace Prize in part based on his calculations of the number of deaths from nuclear weapons fallout.[1] He was supported by physicist and father of the Soviet bomb Andrei Sakharov, who also later received the Nobel Prize for peace.[2] These and other scientists estimated that there would be an extra 10,000 deaths worldwide for each megaton nuclear test in the atmosphere. A nuclear reactor can contain much more radioactive material than a nuclear weapon. Fukushima had six reactors, plus stored additional radioactive material and nuclear waste.

How Radiation Damages Cells

Ionizing radiation acts to damage living tissue by forming free radicals. Essentially, electrons are ripped from molecules. Removing an electron from an atom or molecule turns it into an ion, hence the term ionizing radiation. X-rays, gamma rays, alpha- and beta-radiation are all ionizing.

Most of the damage occurs from ionizing radiation generating free radicals in water, as water molecules are by far the most abundant in the body. While avoiding unnecessary exposure to ionizing radiation is clearly preferable, people affected by Fukushima do not have the luxury of avoiding contamination.

Antioxidants: Free-Radical Scavengers

Free-radical scavengers, as the name suggests, mop up the damaging radicals produced by radiation. The more common term for free radical scavenger is antioxidant. Antioxidants replace the electrons stripped from molecules by ionizing radiation. Antioxidants have long been used in the treatment of radiation poisoning.[3-7] Most of the harm from ionizing radiation occurs from free radical damage which may be quenched by the free electrons antioxidants provide. Fortunately, safe antioxidants are widely available as nutritional supplements. Vitamin C is the prime example.

Why Vitamin C?

Vitamin C is of particular importance and should be included at high intakes for anyone trying to minimize radiation poisoning. High dose vitamin C provides continual antioxidant flow through the body. It is absorbed from the gut and helps to replenish the other antioxidants. When it is used up, it is excreted in the urine. Importantly, it can chelate, or grab onto, radioactive heavy metal atoms and help eliminate them from the body. Large dynamic flow doses of vitamin C (about 3,000 mg, taken 4 times a day for a total of 12,000 mg) would exemplify antioxidant treatment. Higher doses have been used by Dr. Atsuo Yanagisawa and colleagues. [8,9]

Shortly after the disaster, Dr. Damien Downing described how supplements can help protect against radioactive fallout.[10] OMNS issued an update on the response to Fukushima in Japan.[11] Recently, Dr. Gert Schuitemaker has provided a review of vitamin C as a radio-protectant for Fukushima contamination.[12]

Persons living in the areas affected by radioactive contamination can take antioxidant supplements, especially high doses of vitamin C, to counteract the negative consequences of long-term low dose radiation exposure, as well as to protect the health of coming generations.[12,13] People who have a possible internal or external radiation exposure should take antioxidant supplements to maintain an optimal antioxidant reserve. Because of the enormous size and oceanic spread of Fukushima contamination, this literally applies to everyone.

"The International Society for Orthomolecular Medicine is pleased to have participated in the making of this important DVD on the protective effects of intravenous vitamin C on radiation exposure from the Fukushima nuclear plant in March 2011. We are in full support of the valuable work of Dr. Yanagisawa and his colleagues, and we very much appreciate the commitment of Mr. Daisuke Shibata, who has made it possible for the free distribution of the video around the world. May this orthomolecular message raise awareness and foster improvement in the treatment of radiation exposure."

Steven Carter

Director, International Society for Orthomolecular Medicine

References:

1. The Nobel Foundation (1962) The Nobel Peace Prize 1962, Linus Pauling Biography, http://www.nobelprize.org/nobel_prizes/peace/laureates/1962/pauling-bio.html.

2. Sakharov A. (1975) The Nobel Peace Prize 1975, Andrei Sakharov, Autobiography, http://www.nobelprize.org/nobel_prizes/peace/laureates/1975/sakharov-autobio.html.

3. Brown SL, Kolozsvary A, Liu J, et al: Antioxidant diet supplementation starting 24 hours after exposure reduces radiation lethality. Radiat Res, 2010; 173: 462-468.

4. Zueva NA, Metelitsa LA, Kovalenko AN, et al: Immunomodulating effect of berlithione in clean-up workers of the Chernobyl nuclear plant accident [Article in Russian]. Lik Sprava, 2002; (1): 24-26.

5. Yamamoto T, Kinoshita M et al. Pretreatment with ascorbic acid prevents lethal gastrointestinal syndrome in mice receiving a massive amount of radiation. J Radiat Res (Tokyo) 2010; 51(2):145-56

6. Gaby A. Intravenous Nutrient Therapy: the "Myers' Cocktail". Alt Med Rev 2002; 7(5):389:403

7. Narra VR, Howell RW, Sastry KS, Rao DV. Vitamin C as a radioprotector against iodine-131 in vivo. J Nucl Med 1993; 34(4):637-40

8. Yanagisawa A. Orthomolecular approaches against radiation exposure. Presentation Orthomolecular Medicine Today Conference. Toronto 2011 http://www.doctoryourself.com/Radiation_VitC.pptx.pdf )

9. Green MH, Lowe JE et al. Effect of diet and vitamin C on DNA strand breakage in freshly-isolated human white blood cells. Mutat Res 1994; 316(2):91-102

10. Downing D. (2011) Radioactive Fallout: Can Nutritional Supplements Help?, A Personal Viewpoint, OMNS, May 10, http://www.orthomolecular.org/resources/omns/v07n04.shtml.

11. OMNS (2012) Vitamin C Prevents Radiation Damage, Nutritional Medicine in Japan, Orthomolecular Medicine News Service, February 1. http://orthomolecular.org/resources/omns/v08n06.shtml

12. Schuitemaker GE. Vitamin C as protection against radiation exposure. J Orthomolecular Med 2011, 26: 3; 141-145. [Also in Dutch: Schuitemaker G.E. Radioactiviteit in Japan: Orthomoleculair antwoord. Ortho 2011:3, June. http://www.ortho.nl/ ]

13. Yanagisawa A, Uwabu M, Burkson BE, Weeks BS, Hunninghake R, Hickey S, Levy T, (2011) Environmental radioactivity and health. Official JCIT Statement, March 29. http://media.iv-therapy.jp/wp-content/uploads/2012/05/Statement.pdf

Nutritional Medicine is Orthomolecular Medicine

Orthomolecular medicine uses safe, effective nutritional therapy to fight illness. For more information: http://www.orthomolecular.org/

Find a Doctor

To locate an orthomolecular physician near you: http://orthomolecular.org/resources/omns/v06n09.shtml

The peer-reviewed Orthomolecular Medicine News Service is a non-profit and non-commercial informational resource.

Editorial Review Board:

Ian Brighthope, M.D. (Australia)
Ralph K. Campbell, M.D. (USA)
Carolyn Dean, M.D., N.D. (USA)
Damien Downing, M.D. (United Kingdom)
Dean Elledge, D.D.S., M.S. (USA)
Michael Ellis, M.D. (Australia)
Martin P. Gallagher, M.D., D.C. (USA)
Michael Gonzalez, D.Sc., Ph.D. (Puerto Rico)
William B. Grant, Ph.D. (USA)
Steve Hickey, Ph.D. (United Kingdom)
James A. Jackson, Ph.D. (USA)
Michael Janson, M.D. (USA)
Robert E. Jenkins, D.C. (USA)
Bo H. Jonsson, M.D., Ph.D. (Sweden)
Thomas Levy, M.D., J.D. (USA)
Stuart Lindsey, Pharm.D. (USA)
Jorge R. Miranda-Massari, Pharm.D. (Puerto Rico)
Karin Munsterhjelm-Ahumada, M.D. (Finland)
Erik Paterson, M.D. (Canada)
W. Todd Penberthy, Ph.D. (USA)
Gert E. Schuitemaker, Ph.D. (Netherlands)
Robert G. Smith, Ph.D. (USA)
Jagan Nathan Vamanan, M.D. (India)

Source: http://orthomolecular.org/resources/omns/v08n17.shtml


RADIATION EXPOSURE & VITAMIN C

Obviously, it would be preferable to avoid unnecessary radioactive contamination, but that option is no longer available. It is particularly sad that the Japanese government has been inept, irrational, and dishonest in dealing with this tragedy.  The rest of the world needs to know how to deal with this exposure.














There are options for radioactive-protection that have not been disclosed.When people cannot avoid radioactive contamination there are safe radioprotectants that can help prevent the damage.

Eating the right foods providing cellular nutrition, cesium carbonate prevents uptake of the radioactive form C137 and educating ourselves and others on the ways to remove the toxic waste from our cells with Vitamin C. (buffered mineral form is the best form of ascorbate)

Video Source: http://firstlaw.wordpress.com/

Wednesday, March 28, 2012

Vitamin C: intravenous use

Vitamin C: intravenous use by complementary and alternative medicine practitioners and adverse effects.


Padayatty SJ, Sun AY, Chen Q, Espey MG, Drisko J, Levine M.

Source

Molecular and Clinical Nutrition Section, National Institute of Diabetes and Digestive and Kidney Diseases, National Institutes of Health, Bethesda, Maryland, United States of America.

Abstract

BACKGROUND:

Anecdotal information and case reports suggest that intravenously administered vitamin C is used by Complementary and Alternate Medicine (CAM) practitioners. The scale of such use in the U.S. and associated side effects are unknown.

METHODS AND FINDINGS:

We surveyed attendees at annual CAM Conferences in 2006 and 2008, and determined sales of intravenous vitamin C by major U.S. manufacturers/distributors. We also queried practitioners for side effects, compiled published cases, and analyzed FDA's Adverse Events Database. Of 199 survey respondents (out of 550), 172 practitioners administered IV vitamin C to 11,233 patients in 2006 and 8876 patients in 2008. Average dose was 28 grams every 4 days, with 22 total treatments per patient. Estimated yearly doses used (as 25 g/50 ml vials) were 318,539 in 2006 and 354,647 in 2008. Manufacturers' yearly sales were 750,000 and 855,000 vials, respectively. Common reasons for treatment included infection, cancer, and fatigue. Of 9,328 patients for whom data is available, 101 had side effects, mostly minor, including lethargy/fatigue in 59 patients, change in mental status in 21 patients and vein irritation/phlebitis in 6 patients. Publications documented serious adverse events, including 2 deaths in patients known to be at risk for IV vitamin C. Due to confounding causes, the FDA Adverse Events Database was uninformative. Total numbers of patients treated in the US with high dose vitamin C cannot be accurately estimated from this study.

CONCLUSIONS:

High dose IV vitamin C is in unexpectedly wide use by CAM practitioners. Other than the known complications of IV vitamin C in those with renal impairment or glucose 6 phosphate dehydrogenase deficiency, high dose intravenous vitamin C appears to be remarkably safe. Physicians should inquire about IV vitamin C use in patients with cancer, chronic, untreatable, or intractable conditions and be observant of unexpected harm, drug interactions, or benefit.
 
Source: http://www.ncbi.nlm.nih.gov/pubmed/20628650

Tuesday, March 27, 2012

High Daily Intake of Ascorbic Acid

Significance of High Daily Intake of

Ascorbic Acid in Preventive Medicine

Frederick Robert Klenner, M.D., F.C.C.P., A.A.F.P.,

Private practice, Reidsville, N. C.
 
Frederick Robert Klenner, B.S., M.S., M.D., F.C.C.P., A.A.F.P., after graduating Duke University School of Medicine, March, 1936, took three years of hospital training and then entered the private practice of medicine at Reidsville, N.C. Although specializing in diseases of the chest, Dr. Klenner is engaged in a limited general practice which has enabled him to make observations on the use of massive doses of ascorbic acid in virus diseases as well as on other pathological syndromes. He has published 28 scientific papers on these observations and has given numerous lectures to civic and other groups. Dr. Klenner is a Fellow of the American Association for Advancement of Science; Fellow and Diplomate of The International College of Applied Nutrition; Fellow of The Royal Society of Health, London, England; Honorary Fellow of The International Academy of Preventive Medicine and a member and fellow of many other medical and scientific organizations.

IntroductionThe American Medical Association in its introduction to Nostrums, Quackery and Pseudo-Medicine states: “In from 80 to 85 per cent of all cases of human ailment, it is probable that the individual will get well whether he does something for his indisposition or does nothing for it. The healing power of nature, fortunately for biologic perpetuity, works that way.” These percentages are relative. Increased population and greater concentration in terms of living patterns, as well as other types of insult to the body, will frequently change this index. As physicians we have a duty to get the patient well, irrespective of his chance for self-healing with diet or herbs. Hippocrates once declared, “Of several remedies physicians should choose the least sensational.” Vitamin C would seem to meet this requirement.

The Virus StoryThe common cold has received renewed interest since publication of Pauling’s book. [1] Brody, [2] in 1953, after studying vitamin C and its effect on colds in college students, advised that ascorbic acid be given early and often and in sufficient amounts. This confirmed what we had been experiencing and reporting over a period of several years. The response that we observed with massive and frequent doses of ascorbic acid in treating the common cold alerted us to the real significance of this treatment in preventive medicine.

In February 1948, [3] I published my first paper on the use of massive doses of vitamin C in treating virus pathology. By February 1960, [4] some 25 scientific papers later, I realized that every head cold must be considered as a probable source of brain pathology.

Many have died, especially children, following the sudden development of cerebral manifestations secondary to even a slight head and/or chest cold. These insidious cerebral happenings are responsible for the so-called crib deaths attributed to suffocation. They die by suffocation, but by way of a syndrome similar to that found in cephalic tetanus toxemia culminating in diaphragmatic spasm, with dyspnea and finally asphyxia. These infants and children who have been put to bed apparently well, except for an insignificant nasal congestion, will demonstrate bilateral pneumonitis at autopsy. Adequate vitamin C, taken daily, will eliminate this syndrome.

A similar pathology, dubbed Crib Syndrome, is less acute but unless recognized and treated heroically, the infant will also die. This condition is probably due to severe brain trauma received at time of delivery. Laryngismus stridulous will be present in this condition and the child will sound as if it has a cold. Calcium gluconate and massive, frequent injections of vitamin C will also reverse this pathology. The recognized treatment is daily oral dihydrotachysterol.

Adequate ascorbic acid taken during the period of gestation will also prevent the occurrence of this syndrome. The information relative to crib syndrome is backed by case histories at Annie Penn Memorial Hospital, Reidsville, N. C. I have seen children dead in less than two hours after hospital admission, having received no treatment, simply because the attending physicians were not impressed with their illness. A few grams of ascorbic acid, given by needle, while they waited for laboratory procedures or examination to fit their schedule, could have saved their lives. I know this to be a fact because I have been in similar situations and by routinely employing ascorbic acid have seen death take a holiday.

In a paper titled “An Insidious Virus,” [5] I reasoned that it should be a maxim of medicine for large doses of vitamin C to be given in all pathological conditions while the physician ponders his diagnosis. The wisdom of this dictum is backed by many hundred cases under our supervision. I have seen critically ill chest patients well enough to go home after intravenous injection of 1 or 2 liters of 5% dextrose in water, each carrying 50 gm ascorbic acid. This procedure resulted in a dramatic transition from sickness to health.

Virus encephalitis can also be associated with the common cold as a result of the presence of herpes simplex in cold sores. Lerner [6] and associates believe that thousands of cases exist yearly from this route. Of this number, they estimate that one third die; and of the survivors, eight out of nine have residual brain damage. Their work suggests that passive hemaggluting antibodies in the cerebrospinal fluid are a better indicator of the presence of infectious virus than are circulating antibody titers in the serum.

The simple herpes virus from the insignificant fever blister, but possessing the capability of producing encephalitis, can remain hidden for years in the neuron according to Drs. Stephens and Cook. [7] This confirms the thinking of Goodpasture [ 8] given to us many years ago. Thus, a herpes simplex virus once present in a cold sore, although healed and leaving no evidence of lip pathology, could ignite later by simple exposure to ultraviolet light. How many mothers are endangering the lives of their children by sun-bathing, laboring under the belief that they are improving their health? Roizman [ 9] believes that all children are infected by age 5, but that only 1% experience true clinical illness.

For many years investigators thought that each recurrence of fever blisters represented a new infection. Evidence is accumulating that shows the herpes simplex virus is harbored in dormant form until a physiologic or emotional event provokes the virus to produce the typical herpetic lesion. In one case with five repeats of herpes virus erupting at yearly intervals and at the same site, 7-10 gm ascorbic acid by mouth, daily, was found to eliminate this pathology.

Effecting a cure when a virus is the offending agent, and many times bringing about this change in the short space of 24 hours, is a rewarding moment in medicine. Vitamin C treatment must be intensive to be successful. Use veins when practical, otherwise give vitamin C intramuscularly. Never give less than 350 mg/kg body weight. This must be repeated every hour for 6 to 12 times, depending upon clinical improvement, then every two to four hours until the patient has recovered. Ice cubes held to the gluteal muscle before and after injection will reduce or eliminate pain and induration. When treatment continues for several days, the child can be placed on an ice cap between injections. When employing vitamin C intravenously, it is best to use sodium ascorbate and the solution free of all additives except sodium bisulfite. The dose of vitamin C using a syringe should range between 350 mg and 400 mg/kg body weight. In older patients or when very high doses are required the vitamin can be added to 5% dextrose in water, in saline solution or in Ringer’s solution. The concentration should approximately be 1 gm to 18 cc fluid. Bottle injections will need 1 gm calcium gluconate one to two times each day to replace calcium ions removed by the high intravenous schedule. One quart of milk daily will suffice when using the vitamin intramuscularly. In place of milk one can substitute calcium gluconate tablets. Supplemental vitamin C is always given by mouth. As a guide in determining the amount and frequency of injections we recommend our Silver Nitrate-Urine test. [10] This is done by placing ten drops of 5% silver nitrate in a Wasserman tube and adding ten drops urine. A color pattern will develop showing white, beige, smoke gray or one that looks like fine grain charcoal. Charcoal is the color needed and the test is performed at least every four hours. The test itself is read in one minute.

These large doses of ascorbic acid will also bring all body tissue back to saturation which means that the white blood cells will now be capable of destroying other pathogens that might be clouding the picture. Unless the white blood cells are saturated with ascorbic acid they are like soldiers without bullets. Research on this is now under way at the Bowman Gray School of Medicine by McCall and Cooper. [11] White cells ingest bacteria and in the process produce hydrogen peroxide. Hydrogen peroxide will combine with ascorbic acid to produce a substance which is lethal to bacteria. I have seen diphtheria, hemolytic streptococcus and staphylococcus infections clear within hours following injections of ascorbic acid in a dose range of from 500 mg to 700 mg/kg body weight given intravenously and run in through a 20G needle as fast as the patient’s cardiovascular system would allow.

Part of the white cells are lymphocytes. They, too, play an important role in survival from infection. We found in several cases of trichinosis [12] that the behavior of the lymphocytes was the real story of the changing blood picture and actually determined the course of the disease. Wintrobe [ 13] observed that the function of the lymphocytes was stimulation of antibody formation and that the lymphocytic response runs parallel with the recovery of the patient. This build-up of antibodies appears directly proportional to the concentration of ascorbic acid in all body tissue, and yet we give vaccines but pay no attention to the degree of tissue saturation of ascorbic acid. Dr. Nossal [14] of the Institute of Medical Research, Melbourne, Australia, wonders about the mechanism by which lymphocytes, on meeting antigens, decide to be turned on or off. He asks what physiological mechanism underlies the discrimination between immunization and the induction of immunological tolerance and would suggest that it is controlled by vitamin C which in turn affects the negative charge which then influences the response of the lymphocyte. Ginter [15] of the Research Institute of Human Nutrition, Bratislava, offers some evidence to this effect in his statement: “that all reactions which are connected with vitamin C have oxidation-reduction features. It is therefore probable that the biological function of vitamin C can be located in the metabolic reactions which are connected with electron transfer.”

The killing power of ascorbic acid is not limited to just herpes simplex and the adenovirus. When proper amounts are used it will destroy all virus organisms.

We found measles to be a medical curiosity. Specifically we observe that vitamin C given prophylactically, by mouth, was not protective unless 1 gm was given every two hours around the clock. One gram every four hours would modify the attack. One gram given every four hours intramuscularly was also protective. With our own children we kept the measle syndrome going off and on for 30 days by giving 1 gm every two hours for two days, then off for two days. The disease was then stopped by continuing 1 gm every two hours, by mouth, for four days. By 1950 we learned that we could kill the measles virus in 24 hours by giving intramuscular injections in a dose range of 350 mg/kg body weight every 2 hours. We also found that we could dry up chicken pox in the same time, but more dramatic results were obtained by giving 400 mg/kg body weight intravenously. Two to three injections in 24 hours were all that was required. We published these results in 1951. [16]

Recently, we cured a man weighing 85 kg in four days taking 30 gm each day by mouth. In conclusion, the killing power of ascorbic acid on virus bodies has been demonstrated by me in hundreds of cases, many of which were treated in our hospital with nothing but vitamin C. We have published some 28 papers on this matter.

In certain individuals some virus conditions have a slower response. Herpes zoster and mumps belong to this group. We found that in these conditions equally rapid destruction of the virus could be effected through the use of adenosine-5-monophosphate. Adenosine was given according to age and weight, 25 mg in children and 50-100 mg intramuscularly in adults. This was given every 12 hours along with ascorbic acid. Adenosine will sometimes precipitate a mild reaction in that the patient will feel a fullness in his head with varying degrees of nausea. Inhalation of aromatic spirits of ammonia will quickly relieve and, if used before injection, will prevent this condition. Their response, when adenosine was administered, led us to theorize that when a cell has been invaded by a foreign substance, like virus nucleic acid, enzymic action fostered by ascorbic acid contributes to the breakdown of virus nucleic acid to adenosine deaminase which converts adenosine to inosine.

Some individuals cannot manufacture sufficient adenosine to cope with this phase of purine metabolism under certain stress conditions associated with virus pathology. The net result from this chemical action is to catabolize purines rendering them unavailable for making additional virus nucleic acid. Ascorbic acid is further unique in that it possesses the capability of entering all cells. After entering a virus infected cell, ascorbic acid proceeds to take up the protein coats being manufactured by the virus nucleic acid, thus preventing the assembly of new virus units. These newly made macromolecules within the host cell soon create a situation where the tensile strength of the cell membrane is exceeded with resulting rupture and cell death.

Ascorbic acid, when given in the massive amounts that accomplish full tissue saturation, will also enter those cells harboring the so-called dormant virus. Where the vitamin C removes the protective protein coat of the virus the micromolecule formed will act in the capacity of a repressor factor inhibiting further activity of the virus nucleic acid which is then destroyed by additional vitamin C. We offer as proof of this the instance of a patient having herpetic lesions for five years and being cured with continuous high daily intake of ascorbic acid. In acute virus infection, associated with a virusemia, ascorbic acid given intravenously will remove the protein protective coat from the virus body, leaving the denuded virus unit vulnerable to the leukocytes for destruction. Note that adrenal cortex extract and/or desoxycorticosterone acetate must also be considered for support of the adrenals in a debilitated patient.

The Cholesterol Story

Next in importance to the virus is the story of cholesterol. One must understand, as noted by Ginter [17], that acute scurvy and chronic hypovitaminosis C are metabolically different conditions. On this point the Food and Life Yearbook, 1939, U. S. Department of Agriculture, had this to say: “Even when there is not a single outward symptom of trouble, a person may be in a state of vitamin C deficiency more dangerous than scurvy itself. When such a condition is not detected, and continues uncorrected, the teeth and bones will be damaged, and what may be even more serious, the blood stream is weakened to the point where it can no longer resist or fight infections not so easily cured as scurvy.”

Working with guinea pigs many research groups have proved that acute avitaminosis C produces an increase m cholesterol concentration in the whole body. This increased concentration of whole body cholesterol in scorbutic guinea pigs can be caused either by increased biosynthesis or by slowed down cholesterol metabolism. The main pathway of cholesterol catabolism is in conversion to bile salts.

The stimulating effect of ascorbic acid on the oxidation of polyunsaturated fatty acids and decreased oxidation of linolenic acid in the tissues of scorbutic guinea pigs has been well documented. Mjasnikova [ 18] found that intravenous injections of high doses of ascorbic acid to patients with high level blood cholesterol is followed by a distinct decrease of cholesterolemia. It must be remembered that the referred high doses of vitamin C employed by other scientists does not approach the dose schedule that we recommend.

For example, Tjapina [19] reported on the effect of intravenous doses of 500 mg ascorbic acid on cholesterolemia in patients suffering from atherosclerosis. The hypocholesterolemic effect from vitamin C was apparent within one hour. With continued daily injections of 500 mg there was continued drop in blood cholesterol. Spittle [20] showed that blood cholesterol levels, in humans, vary with the amount of vitamin C employed. In our own experience we lowered the blood cholesterol in one patient 42 points in six weeks by increasing the vitamin C intake by mouth from 10 gm to 20 gm each day. Spittle advanced the theory that atherosclerosis is a long-term deficiency or negative balance of vitamin C, which permits cholesterol levels to build up in the arterial system and results in changes in other fractions of the fats.

Ginter [21] also demonstrated that with a high cholesterol diet, guinea pigs used up all their dietary vitamin C while rats and rabbits who manufacture their own vitamin C showed a gain in ascorbic acid tissue levels. Ginter also showed that experimental animals given 50 mg vitamin C each day had cholesterol deposits 40% lower than animals fed the same diet but given only 5 mg of C daily. In a survey of 1000 school children Ginter et al showed that 97% suffered from vitamin C lack during winter months when C-rich fruits and vegetables were less abundant [22]. The children also showed corresponding rise in cholesterol.

Czechoslovakian workers also reported that when guinea pigs are fed a diet deficient in vitamin C and rich in cholesterol, they frequently develop gallstones [23]. Small reported to the Society of University Surgeons in New Orleans in 1973 that when gallstones are removed from patients they are 60%-70% cholesterol [24]. This suggests a causative factor in human gallstone formation. Reviewing the literature and summarizing his own studies, Ginter concluded that there is no doubt that the daily intake of ascorbic acid in the control of cholesterol will have a more pronounced effect in those persons who are already saturated with vitamin C. Tjapina and many others have reported that when amounts of ascorbic acid as low as 500 mg each day, by needle, were continued for 60 days, the clinical picture in the majority of the patients was dramatic, especially concerning the manifestations of coronary artery disease.

Willis [ 25] reported that in scorbutic guinea pigs, fatty deposits on the aorta were formed very quickly, even without adding cholesterol to their diet. In 1957, Willis [26] found that when ascorbic acid was given to these scorbutic guinea pigs, the atherosclerotic lesions were quickly absorbed. Ascorbic acid is directly associated with the mechanism involved in the pathogenesis of human atherosclerosis. Duguid [27] found alterations of ground substance observed in atherosclerosis that produced experimentally to be morphologically similar. Electrocardiographic tracings by Shafer [28] on scorbutic animals showed that with prolonged vitamin C therapy, abnormalities disappeared entirely. Stamler [ 29], following the mortality rate for middle aged persons, found a significant drop with improved nutrition with supplemental C.

We must protect our heart from stress. Adequate vitamin C is one answer. Asahina and Asano [30] of the Toho University School of Medicine in Tokyo found that the larger the dose of ascorbic acid given to experimental rats, the longer they survived in decompression chambers in which the air was made to approximate that found at elevations of 33,000 feet. When ascorbic acid was given in amounts representing 14 gm in a human, only half their animals expired. In humans we have observed that 30 gm in 24 hours is critical in any acute situation. Had the Japanese doubled their vitamin C dose they probably would have had no deaths.

The Heavy Metal Story

Heavy metal poisoning is another morbid chapter in medicine. Lead poisoning comes from many sources. Auto exhaust, smelter furnaces and storage battery factories lead the list. Mercury takes second place. It is estimated that at least I million children in the U. S. have some degree of lead poisoning.

In 1964 Mokranjac and Petrovic [ 31] studied the effect of mercury chloride in guinea pigs when ascorbic acid was administered in different ways. They first gave each animal 200 mg of vitamin C a day for one week (this roughly would represent 14 gm in a human) and then administered a dose of mercury proved beforehand to be 100% fatal. They then continued to give 0.2 gm of vitamin C daily. After 20 days the animals were all alive proving that vitamin C had protected them from certain death. If they gave vitamin C before and none after poisoning, two died. If vitamin C was given daily after poisoning, nine of 25 died; and if a single massive shot was given after poisoning, eight of 25 died. This again confirms that high daily intake of vitamin C will protect one from many of the ills seen today.

The same can be said for lead poisoning. One of the more common types of lead poisoning is seen in long-term workers in lead storage battery plants. All have subclinical scurvy. Adequate ascorbic acid intake would eliminate the monthly blood examination for red cell stippling. The report by Dannenberg [ 32] that high doses of ascorbic acid were without effect in treating lead intoxication in a child must be ignored, since his extremely high dose was 25 mg by mouth four times a day and one single daily injection of 250 mg of C. Had he administered 350 mg/kg body weight every two hours, he would have seen the other side of the coin.

Monoxide poisoning is another killer or crippler. Persons living in most American cities are frequently exposed to 100 ppm (that is, 115 mg/cu mm) of carbon monoxide in the ambient air for varying periods of time and may attain carboxyhemoglobin blood levels up to 10% [33]. Carboxyhemoglobin blood levels up to 7% have been reported in cigarette smokers. These levels of carbon monoxide are quite capable of causing considerable interference with tissue oxygenation in man by displacing oxygen from the hemoglobin molecule and shifting the oxyhemoglobin dissociation curve to the left. Anderson [ 34] reports a definite link between carbon monoxide, both in the atmosphere and in cigarette smoke, with cardiac function. Normal coronary arteries can readily dilate and supply an increased demand; while diseased coronary arteries (e.g., angina pectoris) may not be able to meet this challenge. The hypoxic 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.

Interesting is the report by Pelletier [ 35] who has shown experimentally that once you stop smoking, your ascorbic acid level approaches that of the nonsmoker. Victims of house fires, especially children, succumb more often to monoxide poisoning, which is overlooked in the course of treating the burn. Mayers [36] warns physicians that symptoms of smoke poisoning might be delayed from 3 to 48 hours.

In cases of this nature ascorbic acid serves a dual purpose. A dose of 500 mg/kg body weight of vitamin C given intravenously will immediately neutralize the carbon monoxide or smoke poisoning while at the same time it will prevent blood sludging which is a major factor in the development of third degree burns.
Other Applications

Other therapeutic effects of vitamin C include the following. Vitamin C will also destroy pseudamonis, locally as a 3% spray and systemically with massive frequent injections. This has been demonstrated in case histories on burns treated at Annie Penn Memorial Hospital, Reidsville, N. C. It is a demonstrated principle that the production of histamine and other end products from deaminized cell proteins, released by injury to cells, is a cause of shock.

The clinical value of ascorbic acid in combating shock is explained when we realize that the deaminizing enzymes from the damaged cells are inhibited by vitamin C.

Chambers and Pollock [ 37] have reported that mechanical damage to a cell results in pH changes which reverse the cell enzymes from constructive to destructive activity. The destructive activity releases histamine, a major shock-producing substance. Ascorbic acid, when present in sufficient amounts, inhibits this enzyme transition.

Ascorbic acid will reverse shock found in other areas of medicine. In one patient who had taken 2640 mg Lotusate (talbutal), the blood pressure was 60/0 when first seen in the emergency room. Twelve gm sodium ascorbate was administered with a 50 cc syringe. In ten minutes the blood pressure was recorded at 100/60. Over 100 additional grams were given intravenously over the following three hours, at which time the patient was awake. Shock from toxalbumin, neurotoxin, proteotoxin, muscarine and formic acid responds equally as well to high doses of vitamin C. Keeping the tissues saturated will prevent such experiences or make recovery by additional vitamin C a routine matter.

Blumberg, writing in Medical World News, noted that the discovery of the Australian antigen raises hopes for an effective hepatitis vaccine. Many controversial studies have been reported in the use of this antigen. Another controversial substance, vitamin C, will cure viral hepatitis in two to four days and allow the patient to immediately resume his usual activities. It should be given in a dose range of 500 to 700 mg/kg body weight every 8 to 12 hours. Our latest case was given 5 gm sodium ascorbate, as crystals dissolved in 200 cc water or fruit juice, every 4 hours — i.e., 30 grams per 24-hour period. All symptoms and signs were removed in 96 hours. By contrast treating virus hepatitis with an immunizing agent would possibly require several vaccines in a single hepatic epidemic. If you want results, use adequate ascorbic acid.
The Cancer Story

The question of virus and cancer association is still academic. Herpes simplex causing cervical cancer appears to be positive. We have cured many fever blisters by applying a 3% ointment of vitamin C to the lip 10-15 times a day. This is put in a water soluble base. I think that it is time for those women with a family history of cervical cancer to douche with a 3% solution of ascorbic acid at the first report of cervical erosion. Tamponing with a 3% solution should also be done by the physician. Twenty grams of vitamin C daily by mouth along with local application of vitamin C could erase this form of malignancy.

Virus and breast cancer, which in the mouse has been established, seems likely to be confirmed in women on the basis of a hereditary factor along with a virus role. Paul Broca (1866) pointed out that ten of 24 women among his immediate forebears had died of cancer of the breast. J. A. Murray (1911) demonstrated that mice with familial history of breast cancer developed breast cancer at an incidence three times that of mice with no familial history of tumor. Feller and associates found particles resembling type B and C viruses in eight of 16 human milk specimens from women with breast cancer but in only one of 43 apparently cancer-free women. These are stepping stones which serve to give warning that women from cancer-prone families should not breast feed their children. What will daily high intake of vitamin C do in altering the breast cancer picture? The answer is waiting for experimental work to be done with mice from knowledge gained from Bittner’s classic cross-suckling experiment.

The role of ascorbic acid in treating virus cancer pathology can be seen with its action in mononucleosis. Large doses of vitamin C, given intravenously, will eliminate this virus in just a few days, the actual time being directly proportional to the amount of the vitamin employed in relation to the severity of the infection. A research team at Yale, after studying hundreds of college students, believe they have evidence that associates the Epstein-Barr virus with Burkett lymphoma [38, 39]. This has also been confirmed by researchers at Children’s Hospital, Philadelphia, Pa. Many investigators have been working with immunological procedures for the treatment of malignant disease.

As we noted earlier, unless the patient’s tissues are saturated with vitamin C, the response in this area will be negated. Massive employment of vitamin C will make possible prolonged radiation therapy in late cases. It will also prevent radiation burns. Who can say what 100 gm or 300 gm given intravenously, daily, for several months might accomplish in cancer. The potential is so great and the employment so elementary that only the illiterate will continue to deny its use. Schlegel [ 40] has demonstrated that the use of ascorbic acid as low as 1.5 gm each day will prevent recurrence of bladder cancer. This is the so-called wasted vitamin C.
Other Applications

Rous [41] has found that just 3 gm daily, by mouth, for four days will completely relieve all symptoms of urethritis. He believes that the urethral irritation is caused by phosphatic crystals formed in the urine because of insufficient acidity. Ascorbic acid, in this case, acidified the urine enough to force the crystals back into solution. The neglected chronic cystitis which is the rule with ammonical decomposition in the bladder, most always associated with marked alkalinity of the freshly voided urine, will cease to be a clinical entity once people take at least 10 gm vitamin C every day. This will also eliminate the backwash type pyelitis so debilitating, especially in women of childbearing age.

In over 300 consecutive obstetrical cases, we found that the simple stress of pregnancy increased the ascorbic acid demand up to 15 gm daily. This simple stress of pregnancy becomes meaningful when we review the work of Conney [42] on mammalian synthesis of vitamin C in the rat. Compared to a 70 kg individual the rat would make, under stress, 15.2 gm of C each day. Compare this to the 100 mg now recommended in pregnancy by the National Academy of Science and National Research Council and the disparity is shocking. Fred Stare’s 40 mg/day is catastrophic.

This must be changed. There are at least 16 categories [42], not including scurvy, that cry out against minimal daily requirements for vitamin C. There can never exist a situation where a set numerical unit of vitamin C will meet the needs of all men. This is true because people are different and these same people experience different situations at various times. Roger Williams, speaking before the National Academy of Science in 1967, reported that among guinea pigs living in his laboratory, some needed 20 times more vitamin C than others to maintain health.

We must accept Ginter’s conclusion that acute scurvy and chronic hypovitaminosis C are metabolically different conditions. Antonowicz and Kodicek (1969), working with guinea pigs, discovered an extremely complex chemical process existing in animals receiving ascorbic acid which did not occur in the animals with scurvy. They found that glucosamine synthesis with the formation of galactosamine was normal in those animals receiving vitamin C but did not take place in those with scurvy.

Under a grant from the National Institute of Mental Health, Hepler and associates, according to Medical Tribune, reported that marijuana smoking caused a significant decrease in intraocular pressure. This decrease was found 30 minutes after smoking. In fine print they conceded that the drop was not significant after three hours. Thus, one would need be a chain-link smoker to maintain worthwhile levels [ 43, 44]. No mention was made of the many deleterious effects smoking marijuana has on the human body. Virno and associates [45], working in G. B. Bietti’s eye clinic observed a pronounced reduction in intraocular pressure in the glaucomatous eyes by giving high daily doses of vitamin C.

Bietti states that these high doses of vitamin C are a very effective hypotonic agent for intraocular pressure and when an intravenous dose calculated at 1 gm/kg body weight is administered, the action is predominantly by osmotic dehydration of the eyeball. Virno employed 35 gm by mouth in divided doses each day. This gave marked reduction of pressure within four hours and this was maintained even in patients where Diamox and Philocarpone had failed. Linner in several symposiums using 0.5 gm twice daily reported no significant changes in eye pressure. Linner used 1 gm and Virno 35 gm each day — thus the difference in results. In the 1940s patients died receiving 5,000-10,000 units penicillin every four to six hours. The same type pathology is cured today in 24 to 48 hours using 1-3 million units. The size of the dose does make a difference — a real difference.

Dr. Linus Pauling has written that “Biochemical and genetic arguments support the idea that orthomolecular therapy may be the preferred treatment for many ill patients.” It is difficult to understand why megavitamin therapy remains so controversial when massive doses of vitamin B12 are universally used in pernicious anemia and niacinamide to correct the pathology of pellagra. I have used 150,000-200,000 units of vitamin A in a case of ichthyosis. The patient has been taking this dose for ten years. His skin is clear with no signs or symptoms of vitamin A toxicity. During the same time he has taken 10 gm of vitamin C each day. Is vitamin C the answer?

Hoffer [46] and Osmond were probably the first to realize the value of ascorbic acid as an adjuvant with niacin in treating schizophrenics. They employed from 6 to 8 gm daily. One acute case was given 1 gm every hour for 48 hours at which time the patient was completely recovered and remained so for six months without further treatment.

Hawkins [47] found that by adding megavitamin treatment he doubled the recovery rate, half the rehospitalization rate and virtually eliminated self-destruction in dealing with schizophrenics who have a suicide rate 22 times that of the general population. Dr. Pauling enabled his clinic to treat seriously ill schizophrenics for $200 per patient per year and to reduce the number of patient visits from 150 per year to 15. Hawkins’ method gives schizophrenic patients four gm ascorbic acid and four gm niacin or the equivalent in niacinamide, in divided doses, each day.

Vanderkamp (1966) demonstrated that schizophrenics burn up ascorbic acid ten times faster than normal people. On an intake of four gm vitamin C each day, almost 100% of normal people will spill some degree of ascorbic acid into the urine. In schizophrenics one can often go as high as 40 grams/day before spilling occurs. I have observed this same picture in severe virus infections where the patient did not spill over the urine until the second or third day, when a clinical response was evident. Milmer in Great Britain and Lucksch in Germany have reported significant improvement in schizophrenics given vitamin C alone. Both investigators used the double blind approach.

Ascorbic acid has value as an adjuvant in other medical syndromes. With para-aminobenzoic acid (PABA), which is a fraction of the B vitamins, it will cure trichinosis in nine days [48]. Used with intravenous mephenesin or methocarbamol, it will cure tetanus in 96 hours.

Arthritis is not only a crippler but also a nagger. Aspirin is the favorite medication of many physicians because it will ease the arthritic pain. This makes aspirin a good guy and a bad guy. The bad side is that those who take high aspirin therapy will also have low platelet and plasma levels for vitamin C. With low plasma levels there will also be depletion in the white blood cells. We know what this will do. As to platelets, their main business is to keep people from bleeding to death.

When a blood vessel ruptures, collagen tissue, which makes up the basement membrane of blood vessels, is exposed. The collagen affects the platelets so that they release a mineral substance called adenosine diphosphate. This substance makes the platelets very sticky so that they cling together. Aspirin can destroy this substance, but adequate vitamin C will prevent this action. As the platelets act to seal off the wound, a second mechanism for clot formation comes into play. This is a liquid protein called fibrinogen. In a recent case in which the platelet count was abnormally low and bleeding was a serious problem, 25 gm of ascorbic acid daily by mouth raised the platelet count back to normal with cessation of bleeding. Vitamin C is also the number one agent in collagen formation.

A person who will take 10-20 gm of ascorbic acid a day along with other nutrients might very well never develop arthritis. Abrams and Sandson [49] have pointed out that synovial fluid becomes thinner, thus allowing easier movement, when serum levels of ascorbic acid are high. Drugs such as ACTH and cortisone are noted for their ability to drain ascorbic acid in prolonged usage. In our experience we found that the patient who took vitamin C to tolerance made more rapid progress in reversing arthritic joints.

The importance of daily high intake of ascorbic acid in preventive medicine has no limits. Crest and Colgate might limit tooth decay to one cavity every checkup, a relatively high index. Ten or more gm of ascorbic acid from age 10 up and at least 1 gm for each year of life, each day, through age 9 will record no cavities. Our son who is 20 has never had a tooth cavity. The same schedule could eliminate disc pathology. McCormick believes the problem is avitaminosis C [ 50].

Greenwood [ 51] believes that adequate amounts of ascorbic acid seem necessary to disc metabolism and maintenance. In surgery we found that plasma determinations taken before starting anesthesia, at the conclusion of surgery, and six hours later, were constant. At 12 hours postoperative, there was a significant drop in vitamin C levels and at 24 hours there was a dramatic loss of the vitamin. We have always required the surgeon to give 10 gm before surgery, 10 gm in each postoperative bottle of fluids and 10 gm by mouth after discontinuing fluids. Crandon et al state that postoperative disruption of abdominal wounds occurs eight times more often in patients with vitamin C deficiency. Not only surgery but any type of wound or fracture will heal slowly or not heal at all without the benefits of adequate vitamin C.

Powdered vitamin C mixed with water to form a paste and applied to poison ivy or oak will usually effect a cure in 24 hours when adequate vitamin C is also taken by mouth. Ascorbic acid does have a definite influence on the rheumatic heart, especially in the acute stage [52]. I have seen children with the heart impulse so great that it raised the bed covers with each contraction recover so completely that later in life they were inducted into the armed services.

Massive daily doses will also cure tuberculosis by removal of the organisms’ polysaccharide coat. It does the same with pneumococci. I am convinced that ten or more grams a day will prevent cancer of the lung in tobacco smokers.

It will relieve prickly heat and prevent heat stroke. Vitamin C will immediately reverse heat collapse, cramps or exhaustion if 12 to 40 gm are given intravenously. It will bring recovery to electric shock victims if sufficient amounts are administered soon after the accident. Lightning victims can also be saved. I have done it. Chronic myelocytic leukemia responds dramatically to 30 or more grams daily by mouth.

Pancreatitis can be cured in less than three hours with 50 gm intravenously, and ten gm daily by mouth is positive insurance that it will never return. Virus pancarditis as a sequela of an adenovirus infection can be relieved in 36 hours giving 400 mg/kg body weight, intravenously, every four to six hours. I have never seen a patient that vitamin C would not benefit. And, too, never send a boy to do a man’s job; meaning the dose level is very important.

In closing, I would like to quote Herbert Spencer, who summed up rather well a caution I would like all of us to take to heart: “There is a principle which is a bar against all information, which is proof against all argument, and which cannot fail to keep a man in everlasting ignorance. That principle is condemnation without investigation.”

Summary

The drug evaluation book of the American Medical Association (1971) gives information on the value of ascorbic acid which is at least 30 years behind present day knowledge. The 200-500 mg of ascorbic acid which is recommended as the 24-hour dose in burn cases is a typical example. From clinical experience we know that ascorbic acid must be given to burn victims in massive, frequent intravenous injections. Thirty to one hundred grams daily is the proper amount to employ and this is given until healing takes place — 7-30 days depending upon the degree of burn.

We have found and reported that this massive vitamin C therapy will eliminate skin grafting by keeping the tissues oxygenated. Ample supply of oxygen to the tissues will prevent blood sludging and in place of the third degree burns that develop on the fourth or fifth day, the eschars will drop off leaving normal tissue.

These high doses of ascorbic acid will also remove the smoke poisoning found in many fire victims and save many lives, especially children who expire from the effects of monoxide gas. The statement found in the A.M.A. book mentioned above — that controlled studies have shown no benefit from large doses of ascorbic acid in human subjects — must be ignored. The large doses referred to never exceeded 5 gm and in most cases not more than that found in a quart of orange juice, for a 24-hour period. It is unfortunate that the editorial staff of the AMA failed to check out the world literature. An example of their high doses was an article by Dannenberg [ 32] which was published in the JAMA in which the author found no value in lead poisoning by giving extremely high doses of ascorbic acid to a child. Dannenberg’s extremely high dose was 25 mg four times a day, by mouth, and one single intramuscular injection of 250 mg. Had Dannenberg employed 350 mg/kg body weight and given it, intramuscularly, every two to four hours he would have had a recovered patient in less than 72 hours.

The amount of ascorbic acid employed in any given case is the all important factor. In 28 years of research we have observed that 30 gm each day is critical in terms of response. This seems to be true regardless of age and weight. In certain pathological conditions like barbiturate intoxication, snake bite or virus encephalitis, higher doses are required in some individuals. We have observed from experience and from review of the literature that 15%-20% of humans require much more ascorbic acid than do others.

Approximately 15% is in evidence when giving vaccines, since they make no antibodies. Roughly 15% of pregnant humans were scheduled, in the past, to become paralyzed if hit with the polio virus. Fifteen percent of over 3000 cases in our files required more ascorbic acid to prevent colds or to relieve the cold once infected. This percentage difference is the reason why one patient would die with pneumonia while another lived, when all other factors were apparently equal. This dosage factor alone has misled many scientists to disregard the value of ascorbic acid in virus pathology because they would see dogs die with distemper when they knew that the dog could make his own vitamin C. What they did not appreciate was that even the animal could not make enough vitamin C under certain situations. I have cured many dogs suffering with distemper by giving several grams ascorbic acid, by needle, every two hours.

We also found in over 300 obstetrical cases that roughly 15% require as much as 15 gm supplemental vitamin C each day just to remain within normal limits. Ten grams each day was the highest requirement of the other 85%.

Herpes simplex virus and the adenovirus can be destroyed with high doses of ascorbic acid. Many infections can be prevented by taking adequate vitamin C, daily, by mouth — 1 gm for each year of life up to age 10 and after 10 years of age at least 10 gm vitamin C daily. With these amounts the patient will spill varying amounts into the urine. The kidneys have a threshold for vitamin C much like the spillway of a dam. Spilling is necessary to assure adequate amounts for various body tissues.

For example, white blood cells are useless unless they are full of ascorbic acid, since it is the ascorbic acid which makes their phagocytosis and/or destruction of pathogens possible. Although herpes simplex usually shows itself as a small lip sore and the adenoviruses as a mild but lingering cold, both can become killers through passage of the virus to the brain. Either one can cause crib deaths, which is truly the real cause.

Again, we point out that high daily intake of vitamin C can prevent this tragic incident. For this reason, if for no other, the National Research Council and the National Academy of Science must remove the so-called minimal daily requirement for this substance. Williams has shown and reported to the National Academy that even guinea pigs living in his laboratory differ in their requirements for vitamin C and that they differ each day, sometimes 20 times a given unit. Guinea pigs, like man, cannot manufacture ascorbic acid due to genetic fault. Scurvy which accounts for the thinking on the amount of vitamin C needed is actually of no consequence m terms of avitaminosis C, which can determine one’s future existence.

Ginter, after ten years of research with vitamin C, concluded that acute scurvy and chronic hypovitaminosis C are metabolically different conditions. Antonowicz and Kodick confirmed this by finding that glucosamine synthesis in the guinea pig with the formation of galactosamine was normal in those animals receiving vitamin C but did not take place in the presence of acute scurvy.

Ascorbic acid when taken in sufficient quantities will relieve the intraocular pressure in the glaucomatous eyes, will relieve such things as prickly heat, and is a positive reversal for pemphigus.

Vitamin C when given by needle will destroy all viruses and many can be destroyed by taking 25-30 gm each day by mouth. Lesser amounts will protect against these pathogens.

I have cured diphtheria, hemolytic streptococcus and staphylococcus infections by employing vitamin C intravenously in a dose range of 500 to 700 mg/kg body weight. Doses under 400 mg/kg body weight can be given with a syringe using the sodium salt. This will always produce thirst. Fluids taken just before or immediately after will eliminate this annoyance. Doses above 400 mg/kg body weight must be diluted to at least 1 gm to 18 cc solution, using 5% dextrose in water, saline in water or Ringer’s solution. One gram calcium gluconate must be added to these bottle injections to replace Ca ions pulled from the calcium-prothrombin complex. There is no limit to the amount that can be administered by vein when honoring these two precautions.

The use of vitamin C in cancer will prove to be a very beneficial agent.

We recommend bottle doses containing 60 gm vitamin C and such fractions of the B complex as 500 mg thiamin HCl, pyridoxine 300 mg, calcium pantothenate 400 mg, riboflavin 100 mg and niacinamide 300 mg. This is to be given daily or even twice daily. Vitamin C is a positive neutralizing agent in snake bite [53], spider bite [54] and insect stings.

Our use of ascorbic acid in snake bite has been limited to the Highland moccasin, a member of the copperhead family. Other poisonous snakes are more deadly but we can easily calculate from our experience what dose to employ. In a 4-year-old receiving a full strike from a mature Highland moccasin, 12 gm was required. Unlike a virus that will continue production until completely destroyed, the venom of the snake is constant in that there will exist no later increase in amount. I would suggest 40-60 gin, as a starter, in a large diamondback or cottonmouth. Additional vitamin C can be given if needed since the patient will be well on the road to recovery with the first injection.

Adenosine monophosphate given with ascorbic acid will increase the potential of the vitamin. This can be given in doses from 25 mg in children to as much as 200 mg in adults. Our use of this agent has been limited to mumps and herpes zoster but we are now of sufficient knowledge to believe that its use should be routine. The aqueous solution is more efficacious than the gel. Some patients experience a fullness in the head, a sickish feeling in the chest and a slowed pulse rate. Aromatic spirits of ammonia as a smelling agent relieves or prevents this syndrome. At present we are using 50 mg doses more frequently, until we can establish a reason for this type response.

Ascorbic acid can be lifesaving in shock. Twelve grams of the sodium salt given with a 50 cc syringe will reverse shock in minutes. In barbiturate poisoning and monoxide poisoning the results are so dramatic that it borders on malpractice to deny this therapy.

Surgeons must learn to employ ascorbic acid more liberally. Ten to twenty grams in the preoperative solutions and 10 gm in each postoperative bottle will all but eliminate surgical deaths and will reduce hospital stay by 50%. The same can be said for obstetrical cases. We found that obstetrical cases needed 4 gm each day the first trimester, 6 gm the second trimester and 8-10 gm the third trimester. Fifteen percent of the patients required 15 gm each day just to stay within normal limits.

Ascorbic acid is the safest and the most valuable substance available to the physician. Many headaches and many heartaches will be avoided with its proper use.
References

Pauling, L.: Vitamin C and the Common Cold San Francisco: W. F. Freeman & Co., 1970.
Brody, H. D.: J. Amer. Diet. Ass., 29:588, 1953.
Klenner, F. R.: Virus pneumoniaand its treatment with vitamin C Southern Med. Surg., Feb. 1948.
Klenner, F. R.: Encephalitis as a sequelae of the pneumonias. Tri-State Med. J., Feb. 1960.
Klenner, F. R.: An insidious virus. Tri-State Med. J., June 1957.
Lerner, M. et al: Detecting herpes encephalitis earlier. Med. World News, May 26, 1972.
Stephens, J. C. and Cook, M. Cases of the hidden herpes virus. Med. World News, Feb. 25, 1972.
Goodpasture, E. W.: Case of the hidden herpes virus. Med. World News, Feb. 25, 1972.
Roizman, B. et al: Tracing herpes viruses. Med. World News, Oct. 1, 1971.
Klenner, F. R.: A new office procedure for the determination of plasma levels for ascorbic acid. Tri-State Med. J., 5, 1956.
McCall, C. E. and Copper, R.: Vitamin C shows promise as a bactericidal agent. Bowman Gray School Med. Med. Alumni News, 14:1, Feb., 1972.
Klenner, F. R.: The treatment of trichinosis with massive doses of vitamin C and para-aminobenzoic acid. Tri-State Med. J., 1952.
Wintrobe, M. M.: Clinical Hematology. Text Book. Lea and Febiger, 3rd Edition, 1952.
Nossal, G.: Most killed vaccines in use termed not fit for a mouse. Medical Tribune, April 5, 1972.
Ginter, E.: The Role of Ascorbic Acid In Cholesterol Metabolism. Research Institute of Human Nutrition, Bratislava, 1970.
Klenner, F. R.: Massive doses of vitamin C and the virus diseases. Southern Med. Surg., 1951.
Ginter, E.: Cholesterol and vitamin C. Amer. J. Clin. Nutr., 24:1238-1245, 1971.
Mjasnikova, I. A.: O vlijaniji vodorastvorimych vitaminov na nekororyje storony obmena vescesty. Tr. Vojennomorskof medicinsk. akademiji Leningr., 8:140-148, 1947.
Tjapina, L. A.: Vlijanie askorbovoj kisloty na cholesterinemiju pri giper toniceskoj bolezm i ateroskleroze. Gipertoniceskaja bolezn. Tr. AMN SSSR, 2:108-113, 1952.
Spittle, C.: Atherosclerosis and vitamin C. Lancet, 11:1280-1281, 1971.
Ginter, E.: Effects of dietary cholesterol on vitamin C metabolism in laboratory animals. Acta med. Acad. Sci Hung., 27:23-29, 1970.
Ginter, E., Kajabal, I. and Nizner, O.: The effects of ascorbic acid on cholesterolemia in healthy subjects with seasonal deficit of vitamin C. Nutr. MetaboL, 12:76-86, 1970.
Ginter, E., Bilisics, I. and Cerven, J.: Cholesterol metabolism under conditions of acute and chronic vitamin C deficiency in guinea pigs. PhysioL Bohemoslov., 14:466-471, 1965.
Small, D.: Med. World News, March 30, 1971.
Willis, G. C.: An experimental study of the intimal ground substance in atherosclerosis. Canad. Med. Ass. J., 69:17-22, 1953.
Willis, G. C.: The Reversibility of Atherosclerosis. Canad. Med. Ass. J., 77:106-109, 1957.
Duguid, J. B.: Pathogenesis of atherosclerosis. Lancet, 2:925, 1957.
Shafer, C. F.: Ascorbic acid and atherosclerosis. Amer. J. Clin. Nutr., 23:27, 1970.
Stamler, J.: Comprehensive Treatment of Essential Hypertensive Diseases. Monograph on Hypertension. Merck, Sharp and Dohme.
Asahina and Asano: Prevention, July 1972. pp. 8 1-82.
Mokranjac, M., Petrovic, C.: Report on mercury studies in guinea pigs in relation to amounts of vitamin C administered. C. R. Acad. Sci., Paris.
Dannenberg, A. M. et al: Ascorbic acid in the treatment of chronic lead poisoning. JAMA, 114:1439-1440, 1940.
Klenner, F. R.: The role of ascorbic acid in therapeutics. Tri-State Med. J., Nov. 1955.
Anderson, E: W. et al: Carbon monoxide linked to heart disease. JAMA,22:5, July 1972.
Pelletier, O.: Experiments with smokers and non-smokers. JAMA, April 1969.
Mayers, B. W.: Where there’s smoke there may be carbon monoxide. Med. World News, Jan. 21, 1972.
Chambers, R. and Pollock, H.: J. Gen. Physiol., 10:739, 1927.
Hellne, G. and Helene, W.: EB virus in the etiology of infectious mononucleosis. Hosp. Practice, July 1970.
Niderman, J. C.: College findings tie mono to EB virus. Med. World News, Dec. 1968.
Schlegel, G. E. et al: The role of ascorbic acid in the prevention of bladder tumor formation. Trans. Amer. Ass. Genitourin. Surg., 61, 1969.
Rous, S.: Urethritis in men. N. Y. Soc. Med., Dec. 15, 1971.
Klenner, F. R.: Observations on the dose and administration of ascorbic acid when employed beyond the range of a vitamin in human pathology. J. Appl. Nutr., 23:3-4, 1971.
Leuchtenberger, C. and Leuchtenberger, R.: New dangers seen in marijuana. Nature, Nov. 1971.
Campbell, A. M. G. et al: Significant brain damage caused by smoking marijuana. Lancet, Dec. 1971.
Virno, M. et al: Eye, Ear, Nose, Throat Monthly, 64, Dec. 1967.
Hoffer, A.: Use of ascorbic acid with niacin in schizophrenia. Canad. Med. J., Nov. 6, 1971.
Hawkins, D.: Back to reality the megavitamin way. Med. World News, September 24, 1971.
Klenner, F. R.: Recent discoveries in the treatment of lockjaw with vitamin C and Tolserol. Tri-State Med. J., July 1954.
Abrams, E. and Sandson, J.: Ann. Rheum. Dis., 27, 1964.
McCormick, W. J.: Intervertable Disc Pathology: A new etiologic concept. Arch. Pre., 71:29, 1954.
Greenwood, J.: Optimum vitamin C intake as a factor in the preservation of disc integrity. Med. Ann. D. C., 33:6, June 1964.
Massell, B. F., Warren, J. E., Patterson, P. R. et al: Antirheumatic activity of ascorbic acid in large doses. New Eng. J. Med., 1950.
Klenner, F. R.: Case history: Cure of a 4 year old child bitten by a mature Hiland moccasin with vitamin C. Tri-State Med. J., July, 1954.
Klenner, F. R.: Case history: The black widow spider. Tri-State Med. J., Dec. 1957.

From Journal of the International Academy of Preventive Medicine, Spring 1974, Volume 1, Number 1, pp. 45-69

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