The Nature of Stress - Hans Selye

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The Nature of Stress

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Jan 09, 2007 16:59 PST

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The Nature of Stress

by Hans Selye

 

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International Institute of Stress

University of Montreal

Montreal, Quebec, Canada

 

 

The Nature of Stress was submitted to Dr. Fonder shortly before

Selye's

death. Dr. Fonder knew him well having been invited by Selye to

share

his lecture platform on several occasions.

 

This treatise is presented as prepared by Hans Selye as if he is

still

living, which indeed he is through his monumental works, for Dr.

Stress,

as he was occasionally entitled, will live forever since so many

believe

that Hans Selye is the foremost medical researcher of the 20th

century.

 

About the Author: Dr. Hans Selye is without question one of the

great

pioneers of medicine. His famous and revolutionary concept of stress

opened countless avenues of treatment through the discovery that

hormones participate in the development of many degenerative

diseases,

including coronary thrombosis, brain hemorrhage, hardening of the

arteries, high blood pressure and kidney failure, arthritis, peptic

ulcers and even cancer. At present, most of his research is

concerned

with formulating a code of behavior based on the laws governing the

body's stress resistance in dealing with personal, interpersonal and

group problems.

 

Dr. Selye has served since 1945 as professor and Director of the

Institute of Experimental Medicine and Surgery at the University of

Montreal. Now he is President of the International Institute of

Stress,

founded by him in 1976 at the University of Montreal.

 

Born in Vienna in 1907, he studied in Prague, Paris, and Rome. He

received his medical degree and his Ph.D. (chemistry) from the

German

University in Prague, and his D.Sc. at McGill University in

Montreal. He

is the author of 38 volumes and more than 1600 technical articles.

In

addition to his doctorates he holds 20 honorary degrees from

universities around the world. He is a Fellow of the Royal Society

of

Canada and an Honorary Fellow of 68 other scientific societies. A

recipient of numerous honorary citizenships, he counts among his

medals

the Starr Medal (highest distinction of the Canadian Medical

Association); the Prix de I'Oeuvre Scientifique (highest award of

the

Canadian Association of Frenchspeaking Physicians); the Killam

Scholarship (highest award of the Canada Council); the International

Kittay Award (top prize in psychiatry); the American Academy of

Achievement's Golden Plate Award,- and the 1977 Canadian Authors

Association Literary Award for nonfiction. He has, in addition, been

made a Companion of the Order of Canada (the highest decoration

awarded

by his country).

 

When I wrote the first paper on the stress syndrome in 1936, 1 tried

to

demonstrate that stress is not a vague concept, somehow related to

the

decline in the influence of traditional codes of behavior,

dissatisfaction with the world, or the rising cost of living, but

rather

that it is clearly a definable biological and medical phenomenon

whose

mechanisms can be objectively identified and with which we can cope

much

better once we know how to handle it.

 

Since then, a great deal of progress has been made in identifying

the

mechanisms of stress-induced bodily responses. And during recent

years,

considerable knowledge has been acquired about comprehending and

controlling stress through scientific techniques. The results are of

immense practical value for further improving the understanding of

stress mechanisms by scientists, and for the treatment of certain

stress-induced derangements by competent physicians.

 

Yet today, though everyone talks about stress, only a few people

know

exactly what it is. It is hard to read a newspaper or watch a

television

program without hearing about stress, and literally hundreds of

people

now lecture and write about it. They are ever ready to give advice,

usually based on the teachings of an Eastern guru or Western

" stressologist " - advice that works well provided that one has

absolute

faith in the master's divine infallibility. Far be it from me to

suggest

that these people have nothing to offer, but in the absence of a

clear

concept of exactly what stress is, one is not likely to find it easy

to

maintain faith should difficulties crop up. Besides, in the modern

world

there are so many prophets around trying to convince us that a

desire to

adopt their faith is enough.

 

When confusions and arguments about stress - indeed about any

concept -

start to prove a barrier to communication and progress, it is always

best to revert to the undisputed facts, the original observations

that

gave rise to the field. Accordingly, let us proceed to a discussion

of

the nature of stress.

 

What stress is not

The word stress has been used so loosely, and so many confusing

definitions of it have been formulated, that I think it will be best

to

start by clearly stating what it is not. Contrary to current popular

or

medical opinion:

 

Stress is not nervous tension. Stress reactions do occur in lower

animals and even in plants, which have no nervous system. The

general

manifestations of an alarm reaction can be induced by mechanically

damaging a denervated limb. Indeed, stress can be produced under

deep

anesthesia in patients who are unconscious, and even in cell

cultures

grown outside the body.

Stress is not an emergency discharge of hormones from the adrenal

medulla. An adrenaline discharge is frequently seen in acute stress

affecting the whole body, but it plays no conspicuous role in

generalized inflammatory diseases (arthritis, tuberculosis) although

they can also produce considerable stress. Nor does an adrenaline

discharge play any role in " local stress " reactions, limited to

directly

injured regions of the body.

Stress is not that which causes a secretion by the adrenal cortex of

its

hormones (the corticoids). ACTH, the adrenal-stimulating pituitary

hormone, can discharge these hormones without producing any evidence

of

stress.

Stress is not the nonspecific result of damage only. Normal and even

pleasant activities - a game of tennis or a passionate kiss - can

produce considerable stress without causing conspicuous damage.

Stress Is not the deviation from homeostasis, the steady state of

the

body. Any specific biologic function, e.g., the perception of sound

or

light, the contraction of a muscle, eventually causes marked

deviations

from the normal resting state in the active organs. This is

undoubtedly

associated with some local demand for increased vital activity, but

it

can cause only " local stress " and even this does not necessarily

parallel the intensity of the specific activity.

Stress is not that which causes an alarm reaction. The stressor does

that, not stress itself.

Stress is not identical with the alarm reaction or with the G.A.S.

as a

whole. These are characterized by certain measurable organ changes

which

are caused by stress.

Stress itself is not a nonspecific reaction. The pattern of the

stress

reaction is very specific: it affects certain organs (e.g., the

adrenal,

the thymus, the gastrointestinal tract) in a highly selective

manner.

Stress is not a reaction to a specific thing. The stress response

can be

produced by virtually any agent.

Stress is not necessarily undesirable. It all depends on how you

take

it. The stress of failure, humiliation, or infection is detrimental;

but

that of exhilarating, creative, successful work is beneficial. The

stress reaction, like energy consumption, may have good or bad

effects.

Stress cannot and should not be avoided. Everybody is always under

some

degree of stress. Even while quietly asleep our heart must continue

to

beat, our lungs to breathe, and even our brain works in the form of

dreams. Stress can be avoided only by dying. The statement " He is

under

stress " is just as meaningless as " He is running a temperature. "

What

we actually refer to by means of such phrases is an excess of stress

or

of body temperature.

If we consider these points, we may easily be led to conclude that

stress cannot be defined, and that perhaps the concept itself is

just

not sufficiently clear to serve as the object of scientific study.

 

Nevertheless, stress has a very clear, tangible form. Countless

people

have actually suffered or benefited from it. Stress is very real and

concrete indeed, and is manifested in precisely measurable changes

within the body. So before we proceed to a formal definition of the

nature of stress, we will describe these manifestations.

 

What stress is

Mechanism. The workings of stress are extremely complex (see

Figure).

Apart from specific stimuli, which need not be discussed here, the

first

effect of any, agent or demand made upon the body - be it running up

a

flight of stairs, dealing with a viral infection, or performing a

dance

- is to produce a nonspecific stimulus (the agent's " stressor

effect " .)

This may be a nervous impulse, a chemical substance or lack of an

indispensable metabolic factor; it is referred to simply as

the " first

mediator, " because we know nothing about its nature. We are not even

certain that it has to be an excess or deficiency of any particular

substance; it is possible that various derangements of homeostasis

can

activate the stress mechanism. I

 

Although we have still to identify the first mediator(s), we do know

that eventually stress acts upon the hypothalamus and particularly

upon

the median eminence (ME). This action appears largely to be mediated

through or modified by nervous stimuli coming from the cerebral

cortex,

the reticular formation and the limbic system (especially the

hippocampus and amygdala). The incoming nervous stimuli reach

certain

neuroendocrine cells, most of which are located in the ME. These act

as

" transducers, " transforming nervous signals into a humoral

messenger,

the corticotrophic hormone releasing factor (CRF), which can be

demonstrated histochemically in the ME region and can also be

extracted

from it. Oddly enough, the posterior pituitary contains the highest

concentration of CRF, and it has been isolated from this source in

pure

form, thus permitting the determination of its chemical formula as a

polypeptide which subsequently was synthesized. Yet we have no

conclusive proof that the CRF-active material extracted from the

hypothalamus is identical with that obtained from the posterior lobe

since only the structure of the latter has been definitely

ascertained.

Although vasopressin (antidiuritic hormone) possesses considerable

CRF

activity it is not identical with CRF; this has been shown by the

welldocumented differences in their chemical structure and

physiologic

activity.

 

CRF reaches the anterior lobe through the hypothalamo-hypophyseal

portal

system that originates in the ME region within a network of

capillaries

into which CRF is discharged by the local neuroendocrine cells. It

is

then carried down through the larger veins of the pituitary stalk to

a

second capillary plexus in the pituitary.

 

The hypothalamus does not stimulate the adrenocorticotrophic hormone

(ACTH) secretion of the anterior lobe through nervous pathways

descending in the pituitary stalk but rather through blood-borne

substances carried by way of the portal veins. That is why

transection

of the stalk inhibits the ACTH secretion only before vascular

connections between the hypothalamus and the gland are

reestablished; if

regeneration of these vessels is prevented by interposing a plate

between the cut ends of the stalk, this pathway is permanently

blocked.

 

Both in vivo and in vitro experiments have proven that CRF elicits a

discharge of ATCH from the adenohypophysis into the general

circulation.

Upon reaching the adrenal cortex, it causes secretion of corticoids,

mainly glucocorticoids such as cartisol or corticosterone. These

induce

glyconeogenesis, thereby supplying a readily-available source of

energy

for the adaptive reactions necessary to meet the demands faced by

the

body. In addition, they facilitate various other enzymatically

regulated

adaptive metabolic responses and suppress immune reactions as well

as

inflammation, assisting the body to coexist with potential pathogens

(syntoxic reactions). Furthermore, the glucocorticoids are

responsible

for the thymicolymphatic involution, eosinopenia and lymphopenia

characteristic of acute stress. Curiously, glucocorticoids are

needed

for the acquisition of adaptation primarily during the alarm

reaction,

but not so much to maintain the adjustment during the stage of

resistance. ACTH plays a comparatively minor role in the secretion

of

mineralocorticoids, such as aldosterone, which is regulated mainly

by

the renin-hypertension system and the blood electrolytes, whose

homeostasis is in turn influenced by them.

 

This chain of events is cybernetically controlled by several

biofeedback

mechanisms. Whether an excess of CRF can inhibit its own endogenous

secretion is still doubtful because its lifespan in the circulating

blood is very short. On the other hand, there is definite proof of

an

ACTH feedback (short-loop feedback) by a surplus of the hormone,

which

returns to the hypothalamo-pituitary system and inhibits further

ACTH

production. We have even more evidence to substantiate the existence

of

a corticoid feedback mechanism (long-loop feedback) in that a high

blood

corticoid level similarly inhibits ACTH secretion. It is still not

quite

clear to what extent these feedbacks act upon the neuroendocrine

cells

of the hypothalamus, the adenohypophysis or both. (Hence, in the

Figure

the corresponding arrowheads merely point towards the

hypothalamo-hypophyseal region in general, without specifying

exactly

where their target areas are situated.)

 

Another major pathway involved in the stress mechanism is carried

through the catecholamines liberated under the influence of an

acetylcholine discharge, at autonomic nerve endings and in the

adrenal

medulla. The chromaffin cells of the latter secrete mainly

epinephrine,

which is of considerable value in that it stimulates mechanisms of

general utility to meet various demands for adaptation. Thus it

provides

readily available sources of energy by forming glucose from glycogen

depots and free fatty acids from the triglyceride stores of adipose

tissue; it also quickens the pulse, raises the blood pressure to

improve

circulation into the musculature, and stimulates the CNS. In

addition,

epinephrine accelerates blood coagulation and thereby protects

against

excessive hemorrhage should wounds be sustained in conflicts. All of

this is helpful in meeting the demands, whether they call for fight

or

flight.

 

At this point it will be helpful to discuss two apparent objections

to

accepting the concept of a single stereotyped response to stress:

 

Qualitatively different agents of equal toxicity or stressor potency

do

not necessarily elicit exactly the same reactions in different

people.

Even the same degree of stress, induced by the same agent, may

produce

different effects and even lesions in different individuals.

The effects specific to any given agent usually modify the effects

and

manifestations of the general stress syndrome. (thus, it took many

years

to recognize and prove the existence of the latter.)

The fact that the state of stress, even if due to the same agent,

can

cause different effects in different individuals, has been traced to

" conditioning factors " that can selectively enhance or inhibit one

or

the other stress effect. This conditioning may be endogenous

(genetic

predisposition, age or sex) or exogenous (treatment with certain

hormones, drugs, or dietary factors.) (See Figure.) Under the

influence

of such conditioning factors, a normally well-tolerated degree of

stress

can even become pathogenic, selectively affecting those parts of the

body that are particularly sensitized both by those conditioning

factors

and by the specific effects of the eliciting agent, just as physical

tensions of equal strength in different chains will break the

particular

link that is the weakest as a result of internal or external

factors.

The foregoing processes are the principal ones involved in the

stress

reaction, but by no means the only ones. As well, the level of STH,

the

growth hormone, may rise, and changes in the output of thyroid

hormones

of the ovary or testis may take place.

 

Stressors. The agents or demands that evoke this coordinated

response

which I have designated 11 stress " are referred to, quite naturally,

as

stressors; and of course something is a stressor to the same degree

that

it calls forth the syndrome.

 

When the stressor in question is some organism or substance foreign

to

the body, the curative process resulting from the stress reaction

can

take either of two forms, according to whether the pathogen causes

trouble directly or indirectly. Direct pathogens cause disease

irrespective of our body's reaction, whereas indirect pathogens

produce

damage only through the exaggerated and purposeless defensive

responses

they provoke. If a patient accidentally exposes his hand to a strong

acid, alkali, or boiling water, damage will occur irrespective of

his

reactions. Because all these are direct pathogens; they would cause

damage even to the body of a dead man who obviously could not put up

any

vital defense reactions. On the other hand, most common inflammatory

irritants, including allergens, are essentially indirect pathogens,

which do not themselves cause disease, but are damaging only by

stimulating an inopportune and harmful fight against what is

innocuous.

 

During evolution, immunologic reactions which lead to destruction of

microbes, grafts, and other foreign tissues undoubtedly developed as

useful defensive mechanisms against potentially dangerous foreign

materials. However, when - as in the case of many allergens, heart

transplants, etc. - the attack against the " foreign " agent is

unnecessary or even harmful, man can improve upon the wisdom of

Nature

by suppressing this hostility. Nevertheless, when the aggressor is

dangerous, the defensive reaction should not be suppressed but, if

possible, increased above the normal level, which can be done, for

ex

ample, by catatoxic substances that carry the chemical message to

the

tissues to destroy the invaders even more actively than would

normally

be the case.

 

However, stressors are not exclusively physical in nature. Emotions,

e.g., love, hate, joy, anger, challenge and fear, also call forth

the

changes characteristic of the stress syndrome.

 

Stress and disease. In general, the hormonal responses outlined

above

aid adaptation to environmental change or stimuli; but they are

sometimes the cause of disease, especially if the state of stress is

prolonged or intense. In this latter case, the body goes through the

three stages of what I call the " general adaptation syndrome "

(G.A.S.).

The first is the alarm reaction, characterized by the changes above

described. Of course, if the stressor (stress-producing agent) is so

severe that continued exposure is incompatible with life, the

organism

will die within a few hours during this stage; otherwise, a stage of

adaptation of resistance will ensue, since no organism can be

maintained

continuously in a state of alarm. The adaptive stage is

characterized by

the vanishing or diminishing of the initial symptoms, since the body

has

achieved optimal adaptation. After still more prolonged exposure to

the

stressor, however, this acquired adaptation is lost and a third

stage of

exhaustion is entered into, which, unless the organism receives

emergency aid from some outside source, leads to death. Apparently,

the

adaptability of an organism is finite.

 

An important instance of prolonged stress is that brought about by

various dental problems such as tooth loss and the resultant

malocclusion, muscular imbalances and ensuing unrelenting muscle

tensions which create both physical and psychological demands. These

conditions are often left untreated for years and even decades, and

it

is easy to see how trouble in this area might lead not only to local

wear and tear but also to general, systemic stress, which in turn

may

create other problems or intensify the original ones. As Dr. Fonder

says, describing the ailments associated with malocclusion: " It is

interesting to note the routine interplay of the autonomic nervous

system in the symptomotology throughout this total person when

analysing

the data on each patient. Also of interest is the routine picture of

endocrine gland disturbance that Selye [The Stress of Life, New

York,

McGraw-Hill, Inc., 19561 so ably depicted in the General Adaptation

Syndrome brought on by any Stress to the body. " '

 

Definition. Let us see now whether the following definition will fit

all

our facts:

 

Stress is the state manifested by a specific syndrome which consists

of

all the nonspecifically-induced changes within a biologic system.

Thus,

stress has its own characteristic form and composition, but no

particular cause. The elements of its form are the visible changes

due

to stress, which are addictive indicators expressing the sum of all

the

different adjustments that are going on in the body at any time.

 

The above is essentially an " operational definition " ; it tells what

must

be done to produce and recognize stress. A state can be recognized

only

by its manifestations; you have to observe a great many living

beings

exposed to a variety of agents before you can see the shape of

stress as

such. Those changes which are induced by only one or the other agent

must first be rejected; if you then take what is left - that which

is

induced by many agents - you have uncovered stress itself.

 

For simplicity's sake we have attempted to state the essence of this

concept in the following, less formal terms:

 

Stress is the nonspecific response of the body to any demand,

whether is

is caused by, or results in, pleasant or unpleasant conditions.

Stress

as such, like temperature as such, is all-inclusive, embodying both

the

positive and the negative aspects of these concepts.

 

Within the general concept of stress, however, we must differentiate

between distress (from the Latin dis = bad, as in dissonance,

disagreement), and eustress (from the Greek eu = good, as in

euphonia,

euphoria). During both eustress and distress the body undergoes

virtually the same nonspecific responses to the various positive or

negative stimuli acting upon it. However, the fact that eustress

causes

much less damage than distress graphically demonstrates that it

is " how

you take it " that determines, ultimately, whether you can adapt

successfully to change.

 

The general adaptation syndrome

Definition. While stress is reflected by the sum of the nonspecific

changes as they develop throughout time during continued exposure to

a

stressor, the G.A.S. encompasses all nonspecific changes as they

occur

during continued exposure to a stressor. One is a snapshot, the

other a

motion picture of the response to demands.

 

Thus, the G.A.S. may be defined as the manifestation of stress in

the

whole body, as they develop in time. As we have seen, a fully-

developed

G.A.S. consists of three stages: the alarm reaction, the stage of

resistance, and the stage of exhaustion. Yet it is not necessary for

all

three stages to develop before we can speak of G.A.S. Only the most

severe stress leads rapidly to the stage of exhaustion and death.

Most

of the physical or mental exertions, infections, and other

stressors,

which act upon us during a limited period, produce changes

corresponding

only to the first and second stages: at first they may upset and

alarm

us, but then we adapt to them.

 

Normally, in the course of our lives, we go through these first two

stages many, many times. Otherwise we could never become adapted to

all

the activities and demands which are man's lot. Even the stage of

exhaustion does not always need to be irreversible and complete, as

long

as it affects only parts of the body. For instance, running produces

a

stress situation, mainly in our muscles and cardiovascular system.

To

cope with this, we first have to limber up and get these organs

ready

for the task at hand; then for a while we will be at the height of

efficiency in running, but eventually exhaustion will set in. This

could

be compared with an alarm reaction, a stage of resistance, and a

stage

of exhaustion, all limited primarily to the muscular and

cardiovascular

system. But such exhaustion is reversible; after a good rest we will

be

back to normal.

 

Most human activities go through three stages analogous to those of

the

G.A.S.: we first have to get into the swing of things, then we get

pretty good at them, but finally we tire and lose our acquired

efficiency. This triphasic evolution of adaptation is quite

characteristic also of all bodily activities, including those that

only

the physician can fully appraise; for instance, of inflammation. If

some

virulent microbes get under the skin, they first cause what we call

acute inflammation (reddening, swelling, pain); then follows chronic

inflammation (ripening of a boil or abcess); and finally an

exhaustion

of tissue resistance takes place, which permits the inflamed,

purulent

fluid to be evacuated (breaking through of an abcess).

 

The diseases of adaptation. Many maladies are due not so much to

what

happens to us as to our inability to adapt, and they have therefore

been

called " diseases of adaptation. " The most common of such diseases

are

peptic ulcers in the stomach and upper intestine, high blood

pressure,

heart accidents, and nervous disturbances. Of course, any event

makes

demands upon us and, hence, causes some stress, but it is only

people

who cannot cope, either because of innate defects or lack of

knowledge,

who develop stress diseases.

 

Yet this is a relative concept. No malady is just a disease of

adaptation. Nor are there any disease producers which can be so

perfectly handled by the organism that maladaptation plays no part

in

their effects upon the body. Such agents would not produce disease.

This

haziness in its delimitation does not interfere with the practical

utility of our concept. We must put up with the same lack of

precision

whenever we have to classify any other kind of disease. There is no

pure

heart disease, in which all other organs remain perfectly

undisturbed,

nor can we ever speak of a pure kidney disease or a pure nervous

disease

in this sense.

 

The concept of adaptation energy. The selective exhaustion of

muscles,

eyes, or inflamed tissue all represent final stages in local

adaptation

syndromes (L.A.S.) only. Several of these may develop simultaneously

in

various parts of the body; in proportion to their intensity and

extent,

they can activate the G.A.S. mechanism. It is when the whole

organism is

exhausted - through senility at the end of a normal life-span, or

through the accelerated aging caused by stress - that we enter into

the

(fatal) stage of exhaustion of the G.A.S.

 

Apparently, we have hidden reserves of adaptability, or adaptation

energy, in ourselves throughout the body. As soon as local stress

consumes the most readily accessible local reserves, local

exhaustion

sets in and activity in the strained part must stop. This is an

important protective mechanism because, during the period of rest

thus

enforced, more adaptation energy can be made available, either from

less

readily accessible local stores or from reserves in other parts of

the

body. Only when all of our adaptability is used up will

irreversible,

general exhaustion and death follow.

 

Adaptation energy and a natural code of behavior

There seem to be close interrelations between the G.A.S. and aging.

We

have already mentioned that several local adaptation syndromes may

develop consecutively or even simultaneously in the same individual.

People can get used to a number of things (cold, heavy muscular

work,

worries), which at first had a very alarming effect; yet, upon

prolonged

exposure, sooner or later all resistance breaks down and exhaustion

sets

in. The term " adaptation energy " has been coined for that which is

consumed during continued adaptive work, to indicate that it is

something different from the caloric energy we receive from food;

but

this is only a name, and even now we still have no precise concept

of

what this energy might be. Further research along these lines would

seem

to hold great promise, since we appear to touch upon the

fundamentals of

fastigue and aging.

 

Seemingly, each individual inherits a certain amount of adaptation

energy, the magnitude of which is determined by his genetic

background,

his parents. He can draw upon this capital thriftily for a long but

monotonously uneventful existence, or he can spend it lavishly in

the

course of a stressful, intense, but perhaps more colorful and

exciting

life. In any case, there is just so much of it, and he must budget

accordingly.

 

How can we, as individuals, best manage our limited store of this

energy? Surely scientists have found enough evidence to justify

trying

to develop the fundamentals of a code of behavior based only on the

laws

of Nature, though we may need much more scientific work to learn how

to

apply them in our daily life and to make them easily understandable.

 

In the light of what my own laboratory and clinical study of somatic

diseases has taught me concerning stress, I have tried to arrive at

a

code of ethics based not on the strictures and traditions of

society,

inspiration, or blind faith in the infallibility of a particular

prophet, religious leader or political doctrine, but on the

scientifically verifiable laws that govern the body's reactions in

maintaining homeostasis and living in satisfying equilibrium with

its

environment. By means of such a code, we can adjust our personal

reactions to enjoy fully the eustress of success and accomplishment

without suffering the distress commonly generated by frustrating

friction and purposeless, aggressive behavior against our

surroundings.

 

It is a biologic fact that man - like the lower animals - must fight

and

work for some goal that he considers worthwhile. We must use our

innate

capacities to enjoy the eustress of fulfillment. Only through

effort,

often aggressive, egoistic effort, can we maintain our fitness and

assure our homeostatic equilibrium with both the social and the

inanimate world. To achieve this state, our activities must earn

lasting

results; the fruits of work must be cumulative and must provide a

capital gain to meet future needs. To succeed, we have to accept the

scientifically established fact that man has an inescapable natural

urge

to work egoistically for things that can be stored to strengthen his

homeostasis in the unpredictable situations with which life may

confront

him.

 

We should not combat or be ashamed of these instincts. We can do

nothing

about having been built to work, and it is primarily for our own

good.

Organs that are not used (muscles, bones, even the brain) undergo

inactivity atrophy, and every living being looks out first of all

for

itself. Neither should we feel guilty because we work for treasures

that

can be stored to ensure our future homeostasis. Hoarding is a

vitally

important biologic instinct that we share with animals such as ants,

bees, squirrels and beavers. In man, the urge first manifests itself

when children start to gather match boxes, shells or stickers; it

continues when adults collect stamps or coins. Such a universal

drive

cannot be an artificial, indoctrinated tradition.

 

On the other hand, there is no example in Nature of a creature

guided

exclusively by altruism and the desire to protect others. In fact, a

code of universal altruism would be highly immoral, since it would

expect others to look out for us more than themselves. Of

course, " Love

thy neighbor as thyself " is a command full of wisdom; but, as

originally

expressed, it is incompatible with biologic laws; no one needs to

develop an inferiority complex if he cannot love all his fellow men

on

command.

 

What are the ingredients of a code of ethics that accepts egoism and

working to hoard personal capital as morally correct? After four

decades

of clinical and laboratory research, I would summarize the most

important principles briefly as follows:

 

Find you own stress level - the speed at which you can run toward

your

own goal. Make sure that both the stress level and the goal are

really

your own, an not imposed upon you by society, for only you yourself

can

know what you want and how fast you can accomplish it. There is no

point

in forcing a turtle to run like a racehorse or in preventing a

racehorse

from running faster than a turtle because of some " moral

obligation. "

The same is true of people.

Be an altruistic egoist. Do not try to supress the natural instinct

of

all living beings to look after themselves first. Yet the wish to be

of

some use, to do some good to others, is also natural. We are social

beings, and everybody wants somehow to earn respect and gratitude.

You

must be useful to others. This gives you the greatest degree of

safety,

because no one wishes to destroy a person who is useful.

Earn thy neighbor's love. This is a contemporary modification of the

maxim " Love thy neighbor as thyself. " It recognizes that not all

neighbors are lovable and that it is impossible to love on command.

Perhaps two short lines can encapsulate what I have discovered from

all

my thought and research:

 

Fight for your highest attainable aim,

But do not put up resistance in vain.

 

So far as possible, I myself have followed this philosophy, and it

has

made my life a happy one. Frankly, in looking back, I realize that I

have not always succeeded to perfection, but this has been due to my

own

shortcomings, not those of the philosophy. As I have often said. The

builder of the best racing car is not necessarily its best driver.

 

Notes

Undoubtedly, in man, with his highly developed central nervous

system

(CNS), emotional arousal is one of the most frequent activators. Yet

it

cannot be regarded as the only factor, since typical stress

reactions

can occur in patients exposed to muscle fatigue, trauma, hemorrhage,

etc. while under deep anesthesia. Indeed anesthetics themselves are

commonly used in experimental medicine to produce stress, and 11

stress

of anesthesia " is a serious problem in clinical surgery.

A.C. Fonder, " Malocclusion as it relates to general health, "

Illinois

Dent. J. 34 (5) (May 1965): pp.292-302.

Bibliography

Appley, Mortimer H., and Trumball, Richard. Psychological Stress:

issues

in research. New York: Appleton-Century-Crofts, 1967.

Klausner, Samuel Z. Why Man Takes Chances. Garden City (New York):

Anchor Books, Doubleday, 1968

Mason, J.W. A historical view of the stress field. Part 1. J. hum.

Stress 1(1): 6-12 (1975).

Mason, J.W. A historical view of the stress field. Part 11 J. hum.

Stress 1 (2): 22-36 (1975).

Selye, H. Confusion and controversy in the stress field. J. hum.

Stress

1 (2): 37-44 (1975) (Answer to the preceding articles.)

Selye, H. From Dream to Discovery. New York: McGraw-Hill, 1964.

Selye, H. Hormones and Resistance. BerlinHeidelberg-New York:

Springer-Verlag, 1971.

Selye, H. In Vivo. The Case for supramolecular biology. New York:

Liveright, 1967.

Selye, H. The Story of the Adaptation Syndrome. Montreal: Acta,

Inc.,

1952.

Selye, H. Stress in Health and Disease. Reading (Mass.):

Butterworths,

1976.

Fonder, A.C. The Dental Physician. The University Press, Blacksburg,

VA., 1977.

Selye, H. The Stress of Life. New York: McGrawHill, 1956. Rev. ed.

1976.

 

Selye, H. Stress without Distress. New York: Lippencott, 1974.

Selye, H. A Syndrome produced by diverse nocuous agents. Nature 138:

32

(1936).

Fonder, A.C. Malocclusion as it relates to general health. Illinois

Dental Journal 34 (5) (May 1965): pp. 292-302.

 

JoAnn Guest

mrsjo-

www.geocities.com/mrsjoguest/Diets