DMSO long printout

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Dimethyl sulfoxide (DMSO), a by-product of the wood

industry, has been in use as a commercial solvent

since 1953. It is also one of the most studied but least

understood pharmaceutical agents of our time--at least

in the United States. According to Stanley Jacob, MD, a

former head of the organ transplant program at Oregon

Health Sciences University in Portland, more than

40,000 articles on its chemistry have appeared in

scientific journals, which, in conjunction with

thousands of laboratory studies, provide strong

evidence of a wide variety of properties. (See Major

Properties Attributed to DMSO) Worldwide, some

11,000 articles have been written on its medical and

clinical implications, and in 125 countries throughout

the world, including Canada, Great Britain, Germany,

and Japan, doctors prescribe it for a variety of

ailments, including pain, inflammation, scleroderma,

interstitial cystitis, and arthritis elevated intercranial

pressure. Yet in the United States, DMSO has Food and

Drug Administration (FDA) approval only for use as a

preservative of organs for transplant and for interstitial

cystitis, a bladder disease. It has fallen out of the

limelight and out of the mainstream of medical

discourse, leading some to believe that it was

discredited. The truth is more complicated.

 

DMSO: A History of Controversy

 

The history of DMSO as a pharmaceutical began in

1961, when Dr. Jacob was head of the organ transplant

program at Oregon Health Sciences University. It all

started when he first picked up a bottle of the

colorless liquid. While investigating its potential as a

preservative for organs, he quickly discovered that it

penetrated the skin quickly and deeply without

damaging it. He was intrigued. Thus began his lifelong

investigation of the drug.

 

The news media soon got word of his discovery, and it

was not long before reporters, the pharmaceutical

industry, and patients with a variety of medical

complaints jumped on the news. Because it was

available for industrial uses, patients could dose

themselves. This early public interest interfered with

the ability of Dr. Jacob--or, later, the FDA--to see that

experimentation and use were safe and controlled and

may have contributed to the souring of the mainstream

medical community on it.

 

Why, if DMSO possesses half the capabilities claimed

by Dr. Jacob and others, is it still on the sidelines of

medicine in the United States today?

 

" It's a square peg being pushed into a round hole, "

says Dr. Jacob. " It doesn't follow the rifle approach of

one agent against one disease entity. It's the aspirin of

our era. If aspirin were to come along today, it would

have the same problem. If someone gave you a little

white pill and said take this and your headache will go

away, your body temperature will go down, it will help

prevent strokes and major heart problems--what would

you think? "

 

Others cite DMSO's principal side effect: an odd odor,

akin to that of garlic, that emanates from the mouth

shortly after use, even if use is through the skin.

Certainly, this odor has made double-blinded studies

difficult. Such studies are based on the premise that no

one, neither doctor nor patient, knows which patient

receives the drug and which the placebo, but this drug

announces its presence within minutes.

 

Others, such as Terry Bristol, a Ph.D. candidate from

the University of London and president of the Institute

for Science, Engineering and Public Policy in Portland,

Oregon, who assisted Dr. Jacob with his research in

the 1960s and 1970s, believe that the smell of DMSO

may also have put off the drug companies, that feared

it would be hard to market. Worse, however, for the

pharmaceutical companies was the fact that no

company could acquire an exclusive patent for DMSO,

a major consideration when the clinical testing

required to win FDA approval for a drug routinely runs

into millions of dollars. In addition, says Mr. Bristol,

DMSO, with its wide range of attributes, would

compete with many drugs these companies already

have on the market or in development.

 

The FDA and DMSO

 

In the first flush of enthusiasm over the drug, six

pharmaceutical companies embarked on clinical

studies. Then, in November 1965, a woman in Ireland

died of an allergic reaction after taking DMSO and

several other drugs. Although the precise cause of the

woman's death was never determined, the press

reported it to be DMSO. Two months later, the FDA

closed down clinical trials in the United States, citing

the woman's death and changes in the lenses of

certain laboratory animals that had been given doses

of the drug many times higher than would be given

humans.

 

Some 20 years and hundreds of laboratory and human

studies later, no other deaths have been reported, nor

have changes in the eyes of humans been documented

or claimed. Since then, however, the FDA has refused

seven applications to conduct clinical studies, and

approved only 1, for intersititial cystitis, which

subsequently was approved for prescriptive use in

1978.

 

Dr. Jacob believes the FDA " blackballed " DMSO,

actively trying to kill interest in a drug that could end

much suffering. Jack de la Torre, MD, Ph.D., professor

of neurosurgery and physiology at the University of

New Mexico Medical School in Albuquerque, a pioneer

in the use of DMSO and closed head injury, says,

" Years ago the FDA had a sort of chip on its shoulder

because it thought DMSO was some kind of snake oil

medicine. There were people there who were openly

biased against the compound even though they knew

very little about it. With the new administration at that

agency, it has changed a bit. " The FDA recently

granted permission to conduct clinical trials in Dr. de

la Torre's field of closed head injury.

 

DMSO Penetrates Membranes and Eases Pain

 

The first quality that struck Dr. Jacob about the drug

was its ability to pass through membranes, an ability

that has been verified by numerous subsequent

researchers.1 DMSO's ability to do this varies

proportionally with its strength--up to a 90 percent

solution. From 70 percent to 90 percent has been found

to be the most effective strength across the skin, and,

oddly, performance drops with concentrations higher

than 90 percent. Lower concentrations are sufficient to

cross other membranes. Thus, 15 percent DMSO will

easily penetrate the bladder.2

 

In addition, DMSO can carry other drugs with it across

membranes. It is more successful ferrying some drugs,

such as morphine sulfate, penicillin, steroids, and

cortisone, than others, such as insulin. What it will

carry depends on the molecular weight, shape, and

electrochemistry of the molecules. This property would

enable DMSO to act as a new drug delivery system that

would lower the risk of infection occurring whenever

skin is penetrated.

 

DMSO perhaps has been used most widely as a topical

analgesic, in a 70 percent DMSO, 30 percent water

solution. Laboratory studies suggest that DMSO cuts

pain by blocking peripheral nerve C fibers.3 Several

clinical trials have demonstrated its effectiveness,4,5

although in one trial, no benefit was found.6 Burns,

cuts, and sprains have been treated with DMSO. Relief

is reported to be almost immediate, lasting up to 6

hours. A number of sports teams and Olympic athletes

have used DMSO, although some have since moved on

to other treatment modalities. When administration

ceases, so do the effects of the drug.

 

Dr. Jacob said at a hearing of the U.S. Senate

Subcommittee on Health in 1980, " DMSO is one of the

few agents in which effectiveness can be

demonstrated before the eyes of the observers....If we

have patients appear before the Committee with

edematous sprained ankles, the application of DMSO

would be followed by objective diminution of swelling

within an hour. No other therapeutic modality will do

this. "

 

Chronic pain patients often have to apply the

substance for 6 weeks before a change occurs, but

many report relief to a degree they had not been able

to obtain from any other source.

 

DMSO and Inflammation

 

DMSO reduces inflammation by several mechanisms. It

is an antioxidant, a scavenger of the free radicals that

gather at the site of injury. This capability has been

observed in experiments with laboratory animals7 and

in 150 ulcerative colitis patients in a double-blinded

randomized study in Baghdad, Iraq.8 DMSO also

stabilizes membranes and slows or stops leakage from

injured cells.

 

At the Cleveland Clinic Foundation in Cleveland, Ohio,

in 1978, 213 patients with inflammatory genitourinary

disorders were studied. Researchers concluded that

DMSO brought significant relief to the majority of

patients. They recommended the drug for all

inflammatory conditions not caused by infection or

tumor in which symptoms were severe or patients

failed to respond to conventional therapy.9

 

Stephen Edelson, MD, F.A.A.F.P., F.A.A.E.M., who

practices medicine at the Environmental and

Preventive Health Center of Atlanta, has used DMSO

extensively for 4 years. " We use it intravenously as

well as locally, " he says. " We use it for all sorts of

inflammatory conditions, from people with rheumatoid

arthritis to people with chronic low back

inflammatory-type symptoms, silicon immune toxicity

syndromes, any kind of autoimmune process.

 

" DMSO is not a cure, " he continues. " It is a

symptomatic approach used while you try to figure out

why the individual has the process going on. When

patients come in with rheumatoid arthritis, we put

them on IV DMSO, maybe three times a week, while we

are evaluating the causes of the disease, and it is

amazing how free they get. It really is a dramatic

treatment. "

 

As for side effects, Dr. Edelson says: " Occasionally, a

patient will develop a headache from it, when used

intravenously--and it is dose related. " He continues: " If

you give a large dose, [the patient] will get a

headache. And we use large doses. I have used as

much as 30ÝmlÝIV over a couple of hours. The odor is

a problem. Some men have to move out of the room

[shared] with their wives and into separate bedrooms.

That is basically the only problem. "

 

DMSO was the first nonsteroidal anti-inflammatory

discovered since aspirin. Mr. Bristol believes that it

was that discovery that spurred pharmaceutical

companies on to the development on other varieties of

nonsteroidal anti-inflammatories. " Pharmaceutical

companies were saying that if DMSO can do this, so

can other compounds, " says Mr. Bristol. " The shame is

that DMSO is less toxic and has less int he way of side

effects than any of them. "

 

Collagen and Scleroderma

 

Scleroderma is a rare, disabling, and sometimes fatal

disease, resulting form an abnormal buildup of collagen

in the body. The body swells, the skin--particularly on

hands and face--becomes dense and leathery, and

calcium deposits in joints cause difficulty of

movement. Fatigue and difficulty in breathing may

ensue. Amputation of affected digits may be necessary.

The cause of scleroderma is unknown, and, until DMSO

arrived, there was no known effective treatment.

 

Arthur Scherbel, MD, of the department of rheumatic

diseases and pathology at the Cleveland Clinic

Foundation, conducted a study using DMSO with 42

scleroderma patients who had already exhausted all

other possible therapies without relief. Dr. Scherbel

and his coworkers concluded 26 of the 42 showed good

or excellent improvement. Histotoxic changes were

observed together with healing of ischemic ulcers on

fingertips, relief from pain and stiffness, and an

increase in strength. The investigators noted, " It

should be emphasized that these have never been

observed with any other mode of therapy. " 10

Researchers in other studies have since come to

similar conclusions.11

 

Does DMSO Help Arthritis?

 

It was inevitable that DMSO, with its pain-relieving,

collagen-softening, and anti-inflammatory

characteristics, would be employed against arthritis,

and its use has been linked to arthritis as much as to

any condition. Yet the FDA has never given approval for

this indication and has, in fact, turned down three

Investigational New Drug (IND) applications to conduct

extensive clinical trials.

 

Moreover, its use for arthritis remains controversial.

Robert Bennett, MD, F.R.C.P., F.A.C.R., F.A.C.P.,

professor of medicine and chief, division of arthritis

and rheumatic disease at Oregon Health Sciences

University (Dr. Jacob's university), says other drugs

work better. Dava Sobel and Arthur Klein conducted

their own informal study of 47 arthritis patients using

DMSO in preparation for writing their book, Arthritis:

What Works, and came to the same conclusion.12

 

Yet laboratory studies have indicated that DMSO's

capacity as a free-radical scavenger suggests an

important role for it in arthritis.13 The Committee of

Clinical Drug Trials of the Japanese Rheumatism

Association conducted a trial with 318 patients at

several clinics using 90 percent DMSO and concluded

that DMSO relieved joint pain and increased range of

joint motion and grip strength, although performing

better in more recent cases of the disease.14 It is

employed widely in the former Soviet Union for all the

different types of arthritis, as it is in other countries

around the world.

 

Dr. Jacob remains convinced that it can play a

significant role in the treatment of arthritis. " You talk

to veterinarians associated with any race track, and

you'll find there's hardly an animal there that hasn't

been treated with DMSO. No veterinarian is going to

give his patient something that does not work. There's

no placebo effect on a horse. "

 

DMSO and Central Nervous System Trauma

 

Since 1971, Dr. de la Torre, then at the University of

Chicago, has experimented using DMSO with injury to

the central nervous system. Working with laboratory

animals, he discovered that DMSO lowered intracranial

pressure faster and more effectively than any other

drug. DMSO also stabilized blood pressure, improved

respiration, and increased urine output by five times

and increased blood flow through the spinal cord to

areas of injury.15-17 Since then, DMSO has been

employed with human patients suffering severe head

trauma, initially those whose intracranial pressure

remained high despite the administration of mannitol,

steroids, and barbiturates. In humans, as well as

animals, it has proven the first drug to significantly

lower intracranial pressure, the number one problem

with severe head trauma.

 

" We believe that DMSO may be a very good product for

stroke, " says Dr. de la Torre, " and that is a devastating

illness which affects many more people than head

injury. We have done some preliminary clinical trials,

and there's a lot of animal data showing that it is a

very good agent in dissolving clots. "

 

Other Possible Applications for DMSO

 

Many other uses for DMSO have been hypothesized

from its known qualities hand have been tested in the

laboratory or in small clinical trials. Mr. Bristol speaks

with frustration about important findings that have

never been followed up on because of the difficulty in

finding funding and because " to have on your resume

these days that you've worked on DMSO is the kiss of

death. " It is simply too controversial. A sampling of

some other possible applications for this drug follows.

 

DMSO as long been used to promote healing. People

who have it on hand often use it for minor cuts and

burns and report that recovery is speedy. Several

studies have documented DMSO use with soft tissue

damage, local tissue death, skin ulcers, and

burns.18-21

 

In relation to cancer, several properties of DMSO have

gained attention. In one study with rats, DMSO was

found to delay the spread of one cancer and prolong

survival rates with another.22 In other studies, it has

been found to protect noncancer cells while

potentiating the chemotherapeutic agent.

 

Much has been written recently about the worldwide

crisis in antibiotic resistance among bacteria (see

Alternative & Complementary Therapies, Volume 2,

Number 3, 1996, pages 140-144) Here, too, DMSO may

be able to play a role. Researcher as early as 1975

discovered that it could break down the resistance

certain bacteria have developed.23

 

In addition to its ability to lower intracranial pressure

following closed head injury, Dr. de la Torre's work

suggests that the drug may actually have the ability to

prevent paralysis, given its ability to speedily clean out

cellular debris and stop the inflammation that prevents

blood from reaching muscle, leading to the death of

muscle tissue.

 

With its great antioxidant powers, DMSO could be used

to mitigate some of the effects of aging, but little work

has been done to investigate this possibility. Toxic

shock, radiation sickness, and septicemia have all

been postulated as responsive to DMSO, as have other

conditions too numerous to mention here.

 

DMSO in the Future

 

Will DMSO ever sit on the shelves of pharmacies in this

country as a legal prescriptive for many of the

conditions it may be able to address? Will the studies

we need to discover when this drug is most appropriate

ever be done? Given the difficulties the drug has run

into so far and the recent development of new drugs

that perform some of the same functions, Mr. Bristol is

doubtful. Others, however, such as Dr. Jacob and Dr.

de la Torre, see the FDA approval of DMSO for

interstitial cystitis and the more recent FDA go-ahead

for DMSO trials with closed head injury as new

indications of hope. The cystitis approval means that

physicians may use it at their discretion for other uses,

giving DMSO a new legitimacy.

 

Dr. Jacob continues to believe that DMSO should not

even be called a drug but is more correctly a new

therapeutic principle, with an effect on medicine that

will be profound in many areas. Whether that is true

cannot be known without extensive a publicly reported

trials, which are dependent on the willingness of

researchers to undertake rigorous studies in this

still-unfashionable tack and of pharmaceutical

companies and other investors to back them up. That

this is a live issue is proved by the difficulty the

investigators with approval to test DMSO for closed

head injury clinically are having finding funds to

conduct the trials.

 

In 1980, testifying before the Select Committee on Agin

of the U.S. House of Representatives, Dr. Scherbel

said, " The controversy that exists over the clinical

effectiveness of DMSO is not well-founded--clinical

effectiveness may be variable in different patients. If

toxicity is consistently minimal, the drug should not be

restricted from practice. The clinical effectiveness of

DMSO can be decided with complete satisfaction if the

drug is made available to the practicing physician. The

number of patient complaints about pain and the

number of phone calls to the doctor's office will decide

quickly whether or not the drug is effective. "

 

It may be premature to call for the full rehabilitation of

DMSO, but it is time to call for a full investigation of its

true range of capabilities.

 

Current Status of DMSO

 

Stanley W. Jacob, M.D

 

Gerlinger Professor • Department of Surgery • Oregon

Health Sciences University , 3181 S.W. Sam Jackson

Park Road • Portland, Oregon 97201 • (503) 494-8474

January, 1996

 

DMSO (dimethyl sulfoxide), as a therapeutic principle,

was first introduced to the scientific community in

1963 by a research team headed by Stanley W. Jacob,

MD, at the University of Oregon Medical School. While

DMSO has been called " the most controversial

therapeutic advance of modern times, " the

" controversy " seems to be bureaucratic and economic

rather than scientific. Over the past thirty years, more

than 11,000 articles on the biologic implications of

DMSO have appeared in the scientific literature. The

results of these studies strongly support the view that

DMSO may be the most significant new therapeutic

principle presented to science in the last half of the

20th century.

 

When organ systems are injured or deteriorate, the

damaged tissue produces agents we call " free

radicals. " These further harm cells and prevent or slow

healing. DMSO is a potent scavenger of these radicals,

maintaining the normal integrity of cells and tissues.

 

Another important component of DMSO activity is its

synergism with other therapeutic agents. For example,

Charles Dake, D.V.M. (Annals of the N.T. Academy of

Sciences, 1967, Vol. 141) found that cats with

overwhelming viral infection treated with either DMSO

alone or conventional therapy for viral infections all

died. When DMSO was combined with standard antiviral

treatment, the figures were reversed with the majority

of the cats surviving.

 

At this time, DMSO is a respected, approved

pharmaceutical agent in over one hundred countries. In

1978, it was approved by the FDA for the therapy of

interstitial cystitis (a painful disabling urinary bladder

inflammation). Additionally, in 1970, the FDA approved

DMSO for the treatment of musculoskeletal disorders in

dogs and horses. Many veterinarians consider DMSO to

be the most valuable therapeutic substance in their

armamentarium. In many ways, DMSO represents the

" aspirin " of our era. If aspirin had been introduced in

1963 with its multiple properties, it might very well

have been similarly restricted in the scope of its

application.

 

DMSO became prescriptive for humans in the USSR n

1971. Since that time, it has become more and more

widely used alone and in combinations. Dr. Balabanova

of the Moscow Institute of Rheumatology estimates

that about 50% of the Russian arthritic population

receive DMSO as a part of their therapy. There are over

one hundred articles in the world's literature relating

to DMSO and arthritis. These include both clinical

results and mechanism of action. Among the well

documented pharmacologic properties of DMSO include

analgesia, anti-inflammation, softening of scar tissue,

and hydroxyl radical scavenging.

 

Pharmacology of DMSO Stanley W. Jacob and Robert

Herschler Department of Surgery • Oregon Health

Science University • Portland, Oregon 97201

 

Abstract

 

A wide range of primary pharmacological actions of

dimethyl sulfoxide (DMSO) has been documented in

laboratory studies: membrane transport, effects on

connective tissue, anti-inflammation, nerve blockade

(analgesia), bacteriostasis, diuresis, enhancements or

reduction of the effectiveness of other drugs,

cholinesterase inhibition, nonspecific enhancement of

resistance to infection, vasodilation, muscle

relaxation, antagonism to platelet aggregation, and

influence on serum cholesterol in emperimental

hypercholesterolemia. This substance induces

differntiation and function of leukemic and other

malignant cells. DMSO also has prophylactic

radioprotective properties and cryoprotective actions.

It protects against ischemic injury. (1986 Academic

Press, Inc.)

 

The pharmacologic actions of dimethyl sulfoxide

(DMSO) have stimulated much research. The purpose of

this report is to summarize current concepts in this

area.

 

When the theorectical basis of DMSO action is

described, we can list literally dozens of primary

pharmacologic actions. This relatively brief summary

will touch on only a few:

 

(A) membrane penetration

 

(B) membrane transport

 

© effects on connective tissue

 

(D) anti-inflamation

 

(E) nerve blockade (analgesia)

 

(F) bacteriostasis

 

(G) diuresis

 

(H) enhancement or reduction of effectiveness of other

drugs

 

(I) cholinsterase inhibition

 

(J) nonspecific enhancement of resistance of infection

 

(K) vasodilation

 

(L) muscle relaxation

 

(M) enhancement of cell differentiation and function

 

(N) antagonism to platelet aggregation

 

(O) influence on serum cholesterol in experimental

hypercholesterolemia

 

(P) radio-protective and cryoprotective actions

 

(Q) protection against ischemic injury

 

Primary Pharmocological Actions

 

A. Membrane Penetration

 

DMSO readily crosses most tissue membranes of lower

animals and man.

 

Employing [35S] DMSO, Kolb et al,59 evaluated the

absorption and distribution of DMSO in lower animals

and man. Ten minutes after the cutaneous application

in the rat, radioactivity was measured in the blood. In

man radioactivity appeared in the blood 5 minutes after

cutaneous application. One hour after application of

DMSO to the skin, radioactivity could be detected in

the bones.

 

Denko22 and his associates applied 35S-labeled DMSO

to the skin of rats. Within 2 hour a wide range of

radioactivity was distributed in all organs studied. The

highest values occurred in decreasing order in the

following soft tissues; spleen, stomach, lung, vitreous

humor, thymus, brain, kidney, sclera, colon, heart,

skeletal muscle, skin, liver, aorta, adrenal, lens of eye,

and cartilage.

 

Rammler and Zaffaroni80 have reviewed the chemical

properties of DMSO and suggested that the rapid

movement of this molecule through the skin, a protein

barrier, depends on a reversible configurational change

of the protein occurring when DMSO substitutes for

water.

 

B. Membrane Transport

 

Nonionized molecules of low molecular wight are

transported through the skin with DMSO. Substance of

high molecular weight such as insulin do not pass

through the skin to any significant extent. Studies in

our laboratory have revealed that a 90% concentration

of DMSO is optimal for the passage of morphine sulfate

dissoved in DMSO.77 It would have been expected that

100% would provide better transport than 90%, and the

reason for an optimal effect at 90% DMSO remains

unexplained. It is of course well known that 70%

alcohol has a higher phenol:water partition coefficient

than 100% alcohol.

 

Elfbaum and Laden27 conducted an in vitro skin

penetration study employing guinea pig skin as the

membrane. They concluded that the passage of picrate

ion through this membrane in the presence of DMSO

was a passive diffusion process which adhered to

Fick's first law of diffusion. It is demonstrated by

diffusion and isotope studies that the absolute rate

constant for the penetration of DMSO was

approximately 100 times greater than that for the

picrate ion. Thus, the two substances were transferred

through the skin independently of each other. The

exact mechanisms involved in the membrane penetrant

action of DMSO have yet to be elucidated.

 

Studies on membrane penetration and carrier effect

have been carrier effect have been carried out in

agriculture, basic biology, animals, and man. In field

tests with severely diseased fruit, Keil55 demonstrated

that oxytetracycline satisfactorily controlled bacterial

spot in peaches. Control was significantly enhanced by

adding DMSO to the antibiotic spray. DMSO was applied

to 0.25 and 0.5% with 66 ppm of oxytetracycline. This

application gave control of the disease similar to that

produced alone by 132 ppm of oxytetracycline and

suggested the possibility of diluting the high-priced

antibiotic with relatively inexpensive DMSO. There is

no good evidence in animals that 0.5% DMSO has

significant carrier effects. It could well be that Keil's

results were attributable to a carrier effect, but the

possibility should always be considered that when

DMSO is combined with another substance a new

compound results which can then exert a greater or

lesser influence on a given process.

 

Leonard63 studied different concentrations of several

water-soluable iron sources applied as foliage sprays

to orange and grapefruit trees whose leaves showed

visible signs of iron deficiency. The application of iron

in DMSO as a spray was followed by a rapid and

extensive greening of the leaves, with a higher

concentration of chlorophyll.

 

Amstey and Parkman2 evaluated the influence of DMSO

on the infectivity of viral nucleic acid, an indication of

its transmembrane transport. It was found that DMSO

enhanced polio RNA infectivity in kidney cells from

monkeys. Enhancement occurred with all DMSO

concentrations from 5 to 80% and was optimal at 40%

DMSO, with a 20-minute absorption period at room

temperature. A significant percentage of nucleic acid

infection was absorbed within the first 2 minutes.

 

Cochran and his associates14 concluded that

concentrations of DMSO below 20% did no influence

the infectivity of tobacco mosaic virus (TMV) or the

viral RNA. With concentrations between 20 and 60%

the infectivity of TMV and TMV RNA varied inversely

with the DMSO concentration.

 

Nadel and co-workers72 suggested that DMSO

enhanced the penetration of the infectious agent in

experimental leukemia of gunea pigs. Previously

Schreck et al.97 had demonstrated that DMSO was

more toxic in vitro to lymphocytic leukemia than to

lymphocytes from normal patients.

 

Djan and Gunberg24 studied the percutaneous

absorption of 17-estradiol dissolved in DMSO in the

immature female rat. These steroids were given in

aqueous solutions subcutaneously or were applied

topically in DMSO. Vaginal and uterine weight

increases resulting from estrogen in DMSO

administered topically were comparable to results

obtained in animals in which the drugs were

administered in pure form subcutaneously.

 

Smith102 reported that a mixture of DMSO and

diptheria toxoid applied frequently to the backs of

rabbits causes a reduction of the inflammation

produced by the Shick test, indicating that a partial

immunity of diphtheria has been produced.

 

Finney and his associates29 studied the influence of

DMSO and DMSO-hydrogen peroxide on the pig

myocardium after acute coronary ligation with

subsequent myocardial infaction. The addition of DMSO

to a hydrogen peroxide perfusion system fascilitated

the difffusion of oxygen into the ischemic myocardium.

 

Maddock et al.66 designed experiments to determine

the usefulness of DMSO as a carrier for antitumor

agents. The agents were dissoved in 85-100%

concentrations of DMSO. One of the tumors studied

was the L1210 leukemia. Survival time without

treatment was appoximately 8 days. The standard

method of employing Cytoxan intraperitoneally

produced a survival time of 15.5 days. When Cytoxan

was applied topically in water, the survival time was

12.6 days, and topical Cytoxan dissolved in DMSO

resulted in survival time of 15.3 days.

 

Spruance recently studied DMSO as a vehicle for

topical antiviral agents, concluding that the

penetration of acyclovir (ACV) through guinea pigs skin

in vitro was markedly greater with DMSO than when

ployethylene glycol (PEG) was the vehicle. When 5%

ACV in DMSO was compared with 5% ACV in PEG in the

treatmental herpes infection in the guinea pig, ACV

DMSO was more effective.103

 

The possibility of altering the blood-brain diffusion

barrrier with DMSO needs additional exploration. Brink

and Stein10 employed [14C]pemoline dissolved in

DMSO and injected intraperitoneally into rats. It was

found in larger amounts in the brain than was a similar

dose given in 0.3% tragacanth suspension. The authors

postulated that DMSO resulted in a partial breakdown

of the blood-brain diffusion barrier in vitro.

 

There is conflicting evidence as to whether dimethyl

sulfoxide can reversibly open the blood-brain barrier

and augment brain uptake of water-soluable

compounds, including anticancer agents. To

investigate this, 125[-Human serum albumin,

horse-radish peroxidase, or the anticancer drug

melphalan was administered iv to rats or mice, either

alone or in combination with DMSO. DMSO

administration did not significantly increase the brain

uptake of any of the compounds as compared to

control uptakes. These results do not support prior

reports that DMSO increases the permeability of

water-soluable agents across the blood-brain barrier.43

 

 

Maibach and Feldmann67 studied the percutaneous

penetration of hydrocortisone and testosterone in

DMSO. The authors concluded that there was a

threefold increase in dermal penetration by these

steroids when they were dissolved in DMSO.

 

Sulzberger and his co-workers107 evaluated the

penetration of DMSO into human skin employing

methylene blue, iodine, and iron dyes as visual tracers.

Biopsies showed that the stratum corneum was

completely stained with each tracer applied to the skin

surface in DMSO. There was little or no staining below

this layer. The authors concluded that DMSO carried

substances rapidly and deeply into the horny layer and

suggested the usefulness of DMSO as a vehicle for

therapeutic agents in inflammatory dermatoses and

superficial skin infections such as pyodermas.

 

Perliman and Wolfe76 demonstrated that allergens of

low molecular weight such as penicillin G potassium,

mixed in 90% DMSO, were readily carried through

intact human skin. Allergens having molecular weights

of 3000 or more dissolved in DMSO did not penetrate

human skin in these studies. On the other hand, Smith

and Hegre101 had previously recorded that antibodies

to bovine serum albumin developed when a mixture of

DMSO and bovine serum albumin was applied to the

skin of rabbits.

 

Turco and Canada112 have studied the influence of

DMSO on lowering electrical skin resistance in man, In

combination with 9% sodium chloride in distilled water,

40% DMSO decreased resistance by 100%. It was

postulated that DMSO in combination with electrolytes

reduced the electrical resistance of the skin by

facilitating the absorption of these electrolytes while it

was itself being absorbed.

 

DMSO in some instances will carry substances such as

hydrocortisone or hexachlorophene into the deeper

layers of the stratum corneum, producing a

reservoir.104 This reservoir remains for 16 days and

resists depletion by washing of the skin surface with

soap, water, or alcohol.105

 

C. Effect on Collagen

 

Mayer and associates69 compared the effects of

DMSO, DMSO with cortisone acetate, cortisone acetate

alone, and saline solutions on the incidence of

adhesions following vigorous serosal abrasions of the

terminal ileum of Wistar rats. Their technique had

developed adhesions in 100% of control animals in 35

days. The treatments were administered daily as

postoperative intraperitoneal injections for 35 days.

The incidence of adhesions in different groups was

DMSO alone: 20%, DMSO-cortisone: 80%, cortisone

alone: 100%, saline solution: 100%.

 

It has been observed in serial biopsy specimens taken

from the skin of patients with scleroderma that there is

a dissolution of collagen, the elastic fibers remaining

intact.93 Gries et al.44 studied rabbit skin before and

after 24 hour in vitro exposure to 100% DMSO. After

immersion in DMSO the collagen fraction extractable

with neutral salt solution was significantly decreased.

The authors recorded that topical DMSO in man

exerted a significant effect on the pathological

deposition of collagen in human postirradiation

subcutaneous fibrosis but did not appear to change the

equilibrium of collagen metabolism in normal tissue.

Urinary hydroxyproline levels are increased in

scleroderma patients treated with topical DMSO.93

Keloids biopsied in man before and after DMSO therapy

show histological improvement toward normalcy.28

 

D. Anti-Inflammation

 

Berliner and Ruhmann7 found that DMSO inhibited

fibroblastic proliferation in vitro. Ashley et al.3

reported that DMSO was ineffective in edema following

thermal burns of the limbs of rabbits. Formanek and

Kovak31 showed that topically applied DMSO inhibited

traumatic edema induced by intrapedal injection of

autologous blood in the leg of a rat.

 

DMSO showed no anti-inflammatory effect when

studied in experimental effect when studied in

experimental inflammation induced in the rabbit eye by

mustard oil in the rat ear by croton oil.79

 

Gorog and Kovacs40 demonstrated that DMSO exerted

minimal anti-inflammation effects on edema induced by

carrageenan. These authors also studied the

anti-inflammatory potential of DMSO in

adjuvant-induced polyarthritis of rats. Topical DMSO

showed potent anti-inflammatory properties in this

model. Gorog and Kovacs41 have also studied the

anti-inflammatory activity of topical DMSO, in contact

dermatitis, allergic eczema, and calcification of the

skin of the rat, using 70% DMSO to treat the

experimental inflammation. All these reactions were

significantly inhibited.

 

The study of Weissmann et al.114 deserves mention in

discussing the anti-inflammatory effects of DMSO.

Lysosomes can be stabilized against a variety of

injurious agents by cortisone, and the concentration of

the agent necessary to stabilize lysosomes is reduced

10- to 1000-fold by DMSO. The possibility was

suggested that DMSO might render steroids more

available to their targets within tissues (membranes of

cells or their organelles).

 

Suckert106 has demonstrated anti-inflammatory

effects with intra-articular DMSO in rabbits following

the creation of experimental [croton oil] arthritis.

 

E. Nerve Blockade (Analgesia)

 

Immersion of the sciatic nerve in 6% DMSO decreases

the conduction velocity by 40%. This effect is totally

reversed by washing the nerve in a buffer for 1 hour.89

Shealy99 studied peripheral small fiber after-discharge

in the cat. Concentrations of 5-10% DMSO eliminated

the activity of C fibers with 1 minute: activity of the

fibers returned after the DMSO was washed away.

 

DMSO injected subcutaneously in 10% concentration

into cats produced a total loss of the central pain

response. Two milliliters of 50% DMSO injected into

the cerebrospinal fluid led to total anesthesia of the

animal for 30 minutes. Complete recovery of the animal

occurred without apparent ill effect.100

 

Haigler concluded that DMSO is a drug that produced

analgesia by acting both locally and systemically. The

analgesia appeared to be unrelated to that produced by

morphine although the two appear to be a comparable

magnitude. DMSO had a longer duration of action than

morphine, 6 hr vs 2 hr, respectively.45

 

F. Bacteriostasis

 

DMSO exerts a marked inhibitory effect on a wide

range of bacteria and fungi including at least one

parasite, at concentrations (30-50%) likely to be

encountered in antimicrobial testing programs in

industry.6

 

DMSO at 80% concentration inactivated viruses tested

by Chan and Gadenbusch. These viruses included four

RNA viruses, influenza A virus, influenza A-2 virus,

Newcastle disease virus, Semliki Forest virus, and DNA

viruses.12

 

Seibert and co-worker98 studied the highly

pleomorphic bacteria regularly isolated from human

tumors and leukemic blood. DMSO in 12.5-25%

concentration caused complete inhibition of growth in

vitro of 27 such organisms without affecting the intact

blood cells.

 

Among the intriguing possibilities for the use of DMSO

is its ability to alter bacterial resistance. Pottz and

associates78 presented evidence that the tubercle

bacillus, resistant to 2000Ýg of treptomycin or

isoniazide, became sensitive to 10Ýg of either drug

after pretreatment with 0.5-5% DMSO.

 

Kamiya et al.54 found that 5% DMSO restored and

increased the sensitivity of antibiotic-resistant strains

of bacteria. In particular, the sensitivity of all four

strains of Pseudomonas to colistin was restored when

the medium contained 5% DMSO. The authors recorded

that antibiotics not effective against certain bacteria,

such as penicillin to E. coli, showed growth inhibitory

effects when the medium contained DMSO.

 

Ghajar and Harmon35 studied the influence of DMSO on

the permeability of Staphylococcus aureau,

demonstrating that DMSO increased the oxygen uptake

but reduced the rate of glycine transport. They could

not define the exact mechanism by which DMSO

produced its bacteriostatic effect.

 

Gillchriest and Nelson37 have suggested that

bacteriostasis from DMSO occurs due to a loss of RNA

conformational structure required for protein

synthesis.

 

G. Diuresis

 

Formanek and Suckert32 studied the diuretic effects of

DMSO administered topically to rats five times daily in

a dosage of 0.5 ml of 90% DMSO per animal. The urine

volume was increased 10-fold, and with the increase in

urine volume, there was an increase in sodium and

potassium excretion.

 

H. Enhancement or Reduction of Concomitant Drug

Action

 

Rosen and associates84 employed aqueous DMSO to

alter the LD50 in rats and mice when oral quaternary

ammonium salts were used as test compounds. In rats,

the toxicity of pentolinium tartrate and hexamethonium

bitartrate was increased by DMSO, while the toxicity of

hexamethonium iodide was decreased.

 

Male68 has shown that DMSO concentrations of upward

to 10% lead to a decided increase in the effectiveness

of griseofulvin.

 

Melville and co-workers70 have studied the

potentiating action of DMSO on cardioactive glycosides

in cats, including the fact that DMSO potentiates the

action of digitoxin. This effect, however, does not

appear to involve any change in the rate of uptake

(influx) or the rate of loss (efflux) of glycosides in the

heart.

 

I. Cholinesterase

 

Sams et al.90 studied the effects of DMSO on skeletal,

smooth, and cardiac muscle, employing concentrations

of 0.6-6%. DMSO strikingly depressed the response of

the diaphragm to both direct (muscle) and indirect

(nerve) electrical stimulation, and caused spontaneous

skeletal muscle fasciculations. DMSO increased the

response of the smooth muscle of the stomach to both

muscle and nerve stimulations. The vagal threshold

was lowered 50% by 6% DMSO. Cholinesterase

inhibition could reasonably explain fasciculations of

skeletal muscle, increased tone of smooth muscle, and

the lower vagal threshold observed in these

experiments. In vitro assays show that 0.8-8% DMSO

inhibits bovine erythrocyte cholinesterase 16-18%.

 

J. Nonspecific Enhancement of Resistance

 

In a study of antigen-antibody reactions, Reattig81

showed that DMSO did not disturb the immune

response. In fact, the oral administration of DMSO to

mice for 10 days prior to an oral infection with murine

typhus produced a leukocytosis and enhanced

resistance to the bacterial infection.

 

K. Vasodilation

 

Adamson and his co-workers1 applied DMSO to a 3-1

pedicle flap raised on the back of rats. The anticipated

slough was decreased by 70%. The authors suggested

that the primary action of DMSO on pedicle flap

circulation was to provoke a histamine-like reponse.

Roth87 has also evaluated the effects of DMSO on

pedicle flap blood flow and survival, concluding that

DMSO does indeed increase pedicle flap survival, but

postulating that this increase takes place by some

mechanism other than augmentation of perfusion.

Kligman56, 57 had previously demonstrated that DMSO

possesses potent histamine-liberating properties.

 

Leon62 has studied the influence of DMSO on

experimental myocardial necrosis. DMSO therapy

effected a distinct modification with less myocardial

fiber necrosis and reduced residual myocardial

fibrosis. The author reported that neither myocardial

rupture nor aneurysm occured in the group treated with

DMSO.

 

L. Muscle Relaxation

 

DMSO applied topically to the skin of patients produces

electromyographic evidence of muscle relaxation 1

hour after application.8

 

M. Antagonism to Platelet Aggregation

 

Deutsch23 has presented experimental data showing

that 5% DMSO lessons the adhesiveness of blood

platelets in vitro. Gorog39 has shown that DMSO is a

good antagonist to platelet aggregation as well as

thrombus formation in vivo. Gorog evaluated this in the

hamster cheek pouch model.

 

N. Enhancement of Cell Differentiation and Function

 

It has been shown that dimethyl sulfoxide induces

differentiation and function of leukemic cells of mouse

11, 33, 46, 65, 92, 115, rat,58 and human.9, 15, 16, 34,

109 DMSO was also found to stimulate albumin

production in malignantly transformed hepatocytes of

mouse and rat49 and to affect the

membrane-associated antigen, enzymes, and

glycoproteins in human rectal adenocarcinoma

cells.111 Hydrocortisone-induced keratinization of

chick embryo cells74 and adriamcycin-induced

necrosis of rat skin108 were inhibited by DMSO.

 

Furthermore, modification by DMSO of the function of

normal cells has been reported. DMSO stimulates

cyclic AMP accumulation and lipolysis and decreases

insulin-stimulated glucose oxidation in free white fat

cells of [the] rat. It also enhances heme synthesis in

quail embryo yolk sac cells.110

 

Leukemic blasts can be induced by external chemical

agents to mature to neutrophils, monocytes, or RBCs.

The phenotype of leukemic cells thus results from both

internal genetic aberrations and the response of

leukemic cells to their external environment. When

human myeloid leukemia cells are exposed in vitro to a

variety of agents (e.g.vitamin A or dimenthyl sulfoxide)

the blasts lose their proliferative potential, the

expression of oncogene products is sharply decreased,

and after 5 days the leukemic cells become

morphologically mature and functional neutrophils.

Some patients with myeloid leukemias have responded

to therapy designed to induce maturation in vivo. The

induced maturation of leukemic cells is a new

therapeutic tactic-alternative to cytotoxic drug

therapy-wherein leukemic cells are destroyed by

transforming them into neutrophils.86

 

O. Influence on Serum Cholesterol in Experimental

Hypercholesterolemia

 

Rabbits given a high cholesterol diet with 1% DMSO

showed one-half as much hypercholesterolemia as

control animals.48

 

P. Radioprotective and Cryoprotective Actions

 

M.J. Ashwood-Smith has written a comprehensive

review of these actions.4

 

Q. Protection against Ischemic Injury

 

De la Torre has advanced a scheme based on both

investigated and theoretical actions of DMSO on the

biochemical events generated after an ischemic injury.

He previously proposed this hypothetical model to help

conceptualize how DMSO, or similar drugs, mights

affect the pathochemical balance that results in lack

of tissue perfusion following trauma.19

 

The biochemical and vascular responses to injury

appear to have a cause and effect relationship that can

be integrated in terms of substances that either

increase or decrease blood flow. The substance's

effect can be physical, i.e. reduce or increase the

vessel lumen obstruction, or chemical, i.e. reduce or

increase the vessel lumen diameter

(vasoconstriction/vasodilation).

 

Platelets, for example, can induce both conditions.

Obstruction of the vessel lumen can result from

platelet adhesion (platelet buildup in damaged vessel

lining) or platelet aggregation. Platelet damage

moreover can cause vasoconstriction or vasospasm by

liberating vasoactive substances locally with the blood

vessel or perivascularly, if penetrating damage to the

vessel has occurred. There are two storage sites

within platelets that contain most of these vasoactive

substances. The alpha granules contain fibrinogen,

while the dense bodies store ATP, ADP, serotonin, and

calcium, which can be secreted by the platelet into the

circulation by a canalicular system.5 Thromboxane A2

has also been shown to be manufactured in the

microsomal fraction of animal and human platelets.73

All these vasoactive substances (with the exception of

ATP) can cause significant reduction of blood flow by

physical or chemical reactivity on the vasculature.

 

DMSO can antagonize a number of these vasoactive

substances released by the platelets, which could

consequently induce vasoconstriction, vasospasm, or

obstruction of vessel lumen. For example, a study has

shown that DMSO can inhibit ADP and

thrombin-induced platelet aggregation in vitro.95 It

may presumable do this by increasing the evels of

cAMP (a strong platelet deaggregator) through

inhibition of its degradative enzyme,

phosphodiesterase.26, 51 DMSO is reported to

deaggregate platelets in vivo following experimental

cerebral ischemia.26, 51 This effect may be

fundamental in view of the finding that cerebral

ischemia produces transient platelet abnormalities

that may promote microvascular aggregation formation

and extend the area of ischemic injury.25

 

The biochemical picture is further complicated by the

possible activity of DMSO on other vasoactive

substances secreted by the platelets during injury or

ischemia. For example, the release of calcium from

cells from cells or platelets and its effect on

arteriolar-wall muscle spasm may be antagonized by

circulating DMSO.13, 88 Collagen-induced platelet

release may also be blocked by DMSO.44, 94

 

The following effects of DMSO are likely to be involved

in its ability to protect against ischemic injury.

 

DMSO and PGTX System

 

Little is known about the actions of DMSO on the

prostanoids (PG/TX). Studies have reported that DMSO

can increase the synthesis of PGE1, a moderate

vasodilator.61. PGE1 can reduce platelet aggregation

by increasing cAMP levels and also inhibit the

calcium-induced release of noradrenalin in nerve

terminals, an affect that may antagonize

vasoconstriction and reduction of cerebral blood

flow.53

 

DMSO, it will be recalled, also has a direct effect on

cAMP. It increases cAMP presumably by inhibiting

phosphodiesterase,113 although an indirect action on

PGI2-induced elevation of platelet cAMP by DMSO

should not be ruled out. Any process that increases

platelet cAMP will exert strong platelet deaggregation.

 

 

It has also been reported that DMSO can block PFG2

receptors and reduce PFE2 synthesis.82 Both these

compounds can cause moderate platelet aggregation

and PFG2 is known to induce vasoconstriction.60 The

effects of DMSO on thromboxane synthesis are

unknown. It could, however, inhibit TXA2, biosynthesis

in much the same way as hydralazine or

dipyridamole42 since it shares a number of similar

properties with these agents: specifically, their

increase of cAMP levels.

 

DMSO and Cell Membrane Protection

 

The ability of DMSO to protect cell membrane integrity

in various injury models is well documented.38, 64, 91,

114

 

Cell membrane preservation by DMSO might help

explain its ability to improve cerebral and spinal cord

blood flow after injury.18 DMSO could be preventing

impairment of cerebrovascular endothelial surfaces

where PGI2 is elaborated and where platelets can

accumulate following injury. The effects of DMSO may

be two-fold: reduction of platelet adhesion by

collagen,44 and reduction of platelet adhesion by

protecting the vascular endothelium and ensuring PGI2

release.

 

DMSO, Hydroxyl Radicals, and Calcium

 

Although many hormones, chemical transmitters,

peptides, and numerous enzymes can be found in

mammalian circulation at any given time, it is the

hydrozyl radicals that have drawn attention by playing

an important role in the pathogenesis of ischemia.21,

30 Free radicals can be elaborated by peroxidation of

cellular membrane-bound lipids where oxygen delivery

is not totally abolished, as in ischemia and hypoxia, or

when oxygen is resupplied after an ischemic

episode.83

 

One of the significant sites where hydroxyl radicals

can form following ischemia is in mitochondria. DMSO

is known to be an effective hydroxyl radical

scavenger.4, 20, 75 Since it has been shown that DMSO

can improve mitochondrial oxidative phosphorylation,

it has been suggested that DMSO may act to neutralize

the cytotoxic effects of hydroxyl radicals in

mitochondria themselves.96 Oxidative phosphorylation

is one of the primary biochemical activities to be

negatively affected following ischemic injury. DMSO

has also been reported to reduce ATPase activity in

submitochondrial particles,17, 36 an effect that can

lower oxygen utilization during cellular ischemia.

 

It has been proposed that DMSO may reduce the

utilization of oxygen by an inhibiting effect on

mitochondrial function. In one experiment the energy

loss due to inhibition of oxidative activity after brain

tissue was perfused with DMSO was compensated for

by an increase in glycolysis.36

 

It seems probable that the neutralizing action of DMSO

on hydroxyl radical damage following injury could

diminish the negative outcome of ischemia. However

the formation of hydroxyl radicals is dependent on time

and oxygen availability, but the development of

ischemia is immediate and its reversal may depend on

more prevalent subsystems such as the PG/TX and

platelet interactions. Maintaining the balance of these

subsystems appears more critical in predisposing the

outcome of cerebral ischemia.

 

Another interesting effect of DMSO is on calcium. When

isolated rat hearts are perfused with calcium-free

solution followed by reperfusion with a

calcium-containing solution, a massive release of

creatine kinase (indicating cardiac injury) is observed.

This creatine kinase level increase is accompanied by

electrocardiographic (EKG) changes and ultrastructural

cell damage.50 DMSO has been reported to

significantly reduce the release of creatine kinase and

prevent EKG and ultrastructural changes if it is present

during reperfusion of the isolated rat heart with a

calcium-containing solution.88 Moreover, examination

of the heart tissue by electron microscopy showed that

DMSO-treated preparations lacked the mitochondrial

swelling and contraction band formation otherwise

induced by the reentry of calcium.88 These findings

are supported by another investigation showing that

DMSO can block calcium-induced degeneration of

isolated myocardial cells.13 This protective effect by

DMSO on myocardial tissue may be critical during

ischemic myocardial infarction when evolutionary EKG

changes, serum creates kinase levels are elevated, and

myocardial necrosis can develop rapidly.

 

DMSO2 is not an effective cryoprotective agent;

however, Herschler47 has recorded that DMSO

(dimethyl sulfone) is a natural source of

biotransformable sulfur in plants and lower animals.

Jacob and Herschler have reported a number of unique

properties possessed by DMSO.52 Since DMSO is

oxidized to DMSO2 in vivo, scientists should include

DMSO as a control in basic biologic studies on DMSO in

plants and animals.

 

Footnotes

 

(a) Although the abbreviation " Me2SO " has been

recommended for chemists by the IUPAC, the

abbreviation for dimethyl sulfoxide most familiar to

those concerned with its medicinal uses is " DMSO. "

Consequently, this generic pharmacological name for

dimethyl sulfoxide will be employed throughout this

paper.

 

(b) Supported in part by a grant from The Ronald J.

Purer Foundation. Presented at the Symposium

Biological Effects of Cryoprotective Agents at the

Cryobiology Meeting, June 1985, Madison, Wis.

 

© Stanley W. Jacob, MD, Gerlinger Associate

Professor of Surgery and Surgical Research.

 

New Possibilities in the Treatment of Patients with

Alzheimer's Disease S.A. Goppa Department of

Neurology & Neurosurgery • Medical University •

Kisheinev • 277072 • Moldova

 

Abstracts

 

The Fourth International Conference on Alzheimer's

Disease and Related Disorders

 

Conveners

 

James Mortimer, Ph.D. Khalid Iqbal, Ph.D. Bengt

Winblad, MD, Ph.D.

 

Henry M. Wisniewski, MD, Ph.D. Organized by: Al

Snider, Ph.D.

 

The Role of Amyloid Proteins in Alzheimer's Disease

 

The effect of the drug, dimethyl sulfoxide, was studied

in 18 patients with " probable AD " diagnosed according

to NINCDA-ADRDA criteria. Patients were repeatedly

tested for a period of 9 months. Efficacy was estimated

from the results of neurological and

neuropsychological testing, immunological

examination of neurospecific proteins (NSP) and

autoantibodies (AAB) to them.

 

The obtained results indicated that the severity of

mental-amnestic disturbances and disorientation in

time and space reliably decreased after 3 and

especially 6 months of treatment. There was also a

trend for praxic and speech impairments to decrease

from baseline, in addition, indices of concentration and

communicability improved.

 

The results of immunoenzyme analysis of NSP and AAB

to them showed a decrease of NSP serum

concentration and a stabilizing influence of dimethyl

sulfoxide on the blood brain barrier.

 

The action mechanism, clinical efficacy and adverse

reactions will be discussed.

 

Fybromyalgia Syndrome

 

Fibromyalgia Syndrome (FMS) is pronounced

" fie-bro-my-al-jia sind-rome. " The word fibromyalgia is a

combination of the Latin roots " fibro " (connective

tissue fibers), " my " (muscle), " al " (pain), and " gia "

(condition of). The word syndrome simply means a

group of signs and symptoms that occur together

which characterize a particular abnormality.

 

For many years the medical profession called FMS

many different names, including chronic rheumatism,

myalgia, pressure point syndrome, and fibrositis. It is

important to understand that FMS is not a catch-all,

" wastebasket " diagnosis. " FMS is a specific, chronic

non-degenerative, non-progressive, non-inflammatory,

truly systemic pain condition- a true syndrome.

 

The Copenhagen Declaration defines FMS as a painful,

but not articular (not present in the joints), condition

predominantly involving muscles, and as the most

common cause of chronic, widespread musculoskeletal

pain. Other symptoms include: the presence of

unexplained widespread pain or aching, persistent

fatigue, generalized morning stiffness, non-refreshing

sleep, and multiple tender points. Most patients with

these symptoms have 11 or more tender points.

 

In addition, the Copenhagen Declaration states that

fibromyalgia syndrome is " part of a wider syndrome

encompassing headaches, irritable bladder,

dysmenorrhea, cold sensitivity, Raynaud*s

phenomenon, restless legs, atypical patterns of

numbness and tingling, exercise intolerance and

complaints of weakness. "

 

Over the last few years, we have been treating patients

with fibromyalgia. Seventy percent of the patients have

experienced benefit. No serious side effects have been

encountered.

 

The properties of our regime contributing to benefit

included free-radical scavenging, analgesia,

anti-inflammation, softening of scar tissue, reduction

of muscle spasm, and stimulation of healing.

 

DMSO Carries Relief for Birthmark Removal

 

Research on dimethyl sulfoxide (DMSO) continues, and

scientists are finding more and more beneficial uses

for this medical and solvent compound first discovered

by Dr. Stanley Jacob at the Oregon Health Science

University.

 

Although DMSO has been labeled an " orphan drug, " it

has proven by researchers to have many useful medical

applications.

 

Recently reported is its use in patients undergoing

pulsed dyelaser treatment for vascular malformations.

 

Scientists at Washington University School of

Medicine, St.Louis, and the University of Arkansas

departments of dermatology, looking for a topical

agent that would wouldproduce anesthesia for painful

procedures but would not have to be injected, report

that topical lidocaine at 25% concentration indimethyl

sulfoxide 70% was most effective.

 

" Pulsed dye laser treatment of vascular

malformations,including strawberry birthmarks in

children, has now become avaluable treatment option

for capillary vascular malformationsand hemangiomas,

but is moderately painful. Since many of the patients

are children who do not tolerate painful procedures

well, the length of a single treatment is often limited

by pain. Many of these lesions are large and may

encompass half of theface, or an entire limb.

 

" The object of the study was to develop a rapidly

acting, topicalanesthetic formulation to reduce the

pain associated with pulseddye therapy, yet wear off

within a few hours and have noprolonged side effects, "

according to the researchers.

 

The lidocaine DMSO topical application was " well

tolerated onthe evaluated patients, age 6 years and

older, and had no sideeffects except transient mild

erythema. "

 

This article appeared in " The Oregon Scientist, " Spring,

1995.

 

Treating Extravasation Injury

 

Soft-tissue damage can be reversed with topical DMSO

Stephen B. Strum, MD

 

Extravasation injury, which occurs in about 1% of

patients undergoing chemotherapy, is associated with

significant morbidity. Topical application of dimethyl

sulfoxide (DMSO), an anti-inflammatory agent, has been

shown to be effective in treating this problem in

several studies.1-2 In a pilot study, DMSO therapy over

3 months significantly improved

anthracycline-associated extravasation in 16 of 20

patients.2

 

In our experience, regular DMSO application can

completely reverse extravasation injury even when

treatment is delayed. For example, in one patient

receiving continuous-infusiondoxorubicin for hepatoma,

chest-wall induration of 5 days standing decreased

more than 50% after 4 weeks of DMSO therapy and

completely resolved after 8 weeks. The induration

resulted from inadvertent extravasation that occurred

when the catheter needle worked its way out of the

port.

 

Even days after injury, we instruct patients to liberally

apply70% DMSO using cotton swabs and remove any

excess remaining after 45 minutes with a white cotton

cloth or tissue.This treatment is repeated every 3 to 4

hours during the day untilall evidence of injury has

disappeared.

 

In 20 years of using DMSO, the only toxicity we have

seen has been a stinging or burning sensation during

initial application. If the problem becomes severe, aloe

vera gel can be applied after wiping off the remaining

DMSO. Patients treated with DMSO also may develop a

characteristic breath odor. Other practitioners and

researchers also have had positive results with

DMSO.1-10 We suggest that a central repository be

formed for the study of extravasation injury and DMSO.

 

Dr. Strum is a medical oncologist in private practice in

CulverCity, Calif.

 

O