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MedGenMed Neurology & Neurosurgery

The Therapeutic Potential of Melatonin: A Review of the Science

Samir Malhotra, MD; Girish Sawhney, MD; Promila Pandhi, MD

Medscape General Medicine 6(2), 2004. © 2004 Medscape

Posted 04/13/2004

Summary

Melatonin is a ubiquitous natural neurotransmitter-like compound produced

primarily by the pineal gland. This agent is involved in numerous aspects of

the biological and physiologic regulation of body functions. The role of

endogenous melatonin in circadian rhythm disturbances and sleep disorders is

well established. Some studies have shown that melatonin may also be

effective in breast cancer, fibrocystic breast diseases, and colon cancer.

Melatonin has been shown to modify immunity, the stress response, and

certain aspects of the aging process; some studies have demonstrated

improvements in sleep disturbances and " sundowning " in patients with

Alzheimer's disease. The antioxidant role of melatonin may be of potential

use for conditions in which oxidative stress is involved in the

pathophysiologic processes. The multiplicity of actions and variety of

biological effects of melatonin suggest the potential for a range of

clinical and wellness-enhancing uses. This review summarizes the physiology

of melatonin and discusses the potential therapeutic uses of melatonin.

Melatonin is a widely occurring neurotransmitter-like compound derived

primarily from the pineal gland. It is also produced in a number of other

areas, for example the gastrointestinal tract.[1-3] Once labeled as a master

hormone, it has been found to be involved in numerous aspects of biological

and physiologic regulation.

Synthesis and Physiologic Role in Humans

Melatonin is an indole hormone, widely distributed in both plant and animal

sources, such as human milk,[4] bananas, beets, cucumbers, and tomatoes.[5]

Chemically, melatonin is N-acetyl-5-methoxytryptamine, a derivative of

serotonin, which in turn is derived from tryptophan. Serotonin is first

acetylated by N-acetyltransferase (probably the rate-limiting step) and then

methylated by hydroxyindole orthomethyltransferase to form melatonin.[6]

Melatonin synthesis depends on intact beta-adrenergic receptor function.[7]

Norepinephrine activates the N-acetyltransferase and beta-receptor blockers

depress melatonin secretion.[8]

The enzymes of melatonin synthesis are activated and depressed,

respectively, by darkness and light. Release of melatonin follows a

circadian (circa: about; dias: a day) rhythm generated by the

suprachiasmatic nuclei in response to daylight alterations.

Through melatonin release, the pineal gland maintains the internal clock

governing the natural rhythms of body function. This apparent clock-setting

property of melatonin has led to the suggestion that it is a " chronobiotic "

substance that alters and potentially normalizes biological rhythms and

adjusts the timing of other critical processes and biomolecules (hormones,

neurotransmitters, etc) that, in turn, exert numerous peripheral actions.[9]

Sleep Disturbances

Studies[10-13] have suggested that a relationship exists among sleep, pineal

function, and melatonin levels. Nocturnal melatonin levels and the quality

of sleep both decline at puberty;[10] in elderly populations, periods of

sleep tend to become shorter and the quality of sleep poorer. Controlled

clinical trials have shown that melatonin is effective as a chronobiotic in

a number of circadian rhythm sleep disorders.

Jet Lag

When melatonin is taken at the destination, between 10 pm and midnight, it

can correct the sleep disturbances, mental inefficiency, and daytime fatigue

(cumulatively known as " jet lag " ) that occur after flights across several

time zones.[11-13] The biological rhythm disorganization caused by the rapid

change of environment (and associated light/dark cues) apparently can be

corrected by melatonin. The benefit is likely to be greater as more time

zones are crossed and less for westward flights.[12] However, melatonin

taken before travel can actually worsen symptoms as opposed to the benefit

of melatonin initiated immediately upon arrival.[13] Parry[14] has reviewed

the use and effectiveness of melatonin as a 'dark pulse' at night, with

appropriately timed bright light to reduce symptoms of jet lag.

Insomnia

Nocturnal melatonin levels are reduced in primary insomnia.[15] Supplemental

melatonin has been used successfully as a hypnotic for delayed sleep-phase

syndrome, a type of insomnia characterized by wakefulness and the inability

to fall asleep before 2:00 to 3:00 am. In several small studies, 5-mg doses

of melatonin given at 10 pm resulted in an advance of the sleep phase

(shortening of time to sleep) by about 1.5 hours[16,17] and reduced sleep

duration by about 30 minutes,[16] suggesting a lowered sleep requirement as

a consequence of improved sleep quality.[18]

Narcolepsy

Melatonin has also been used to alter sleep architecture in narcolepsy, a

disorder of disturbed circadian sleep/wake rhythm and rapid-eye-movement

(REM) sleep deficit. Changes in REM sleep patterns similar to those of

narcolepsy also occur in animals and humans after removal of the pineal

gland.[19] Pharmacologic doses of melatonin (50 mg) dramatically increased

REM sleep time in both narcoleptics and normals and greatly intensified

subjective dream phenomena.[19]

Several studies using varying doses of melatonin (2-20 mg/daily) have

reported improved sleep quality, accelerated sleep initiation, and improved

sleep maintenance without significantly altering memory, in contrast to

benzodiazepines.[20,21]

Sleep Disorders in Children

Melatonin has also been used successfully to treat serious sleep disorders

in hyperactive and neurologically compromised children, such as those with

attention-deficit/hyperactivity disorder. In 1 study, doses of 2.5-5 mg

nightly provided prompt sedation and improved sleep quality, noted in almost

all the 15 subjects, with no side effects.[22] Irritability has been

reduced, children have tended to become more alert and sociable, and

developmental gains have been reported in children treated with

melatonin.[22]

Endocrine Function and Immunity

A close, reciprocal relationship exists between the pineal and the

pituitary/adrenal axis. Melatonin modulates the activity of this axis and

the peripheral actions of corticoids. One study found that melatonin

releases vasotocin, which lowers corticoid levels;[13] however, this work

has never been confirmed, and recently, another study found that melatonin

reduces the basal release of vasotocin.[23] In this latter study, substance

P-induced secretion of vasotocin was also found to be inhibited.

The different responses observed in these studies may have been the result

of the different doses used. Forsling and [24] elegantly

demonstrated that the increase in vasotocin secretion during hypertonic

saline infusion and exercise was attenuated by high doses (5 mg) but

augmented by low doses (0.5 mg) of melatonin. Pinealectomy causes adrenal

hypertrophy, which is reversed by melatonin administration.[25] Some have

proposed that melatonin acts as a corticotropin-releasing factor inhibitor,

and that disinhibition of the pituitary/adrenal axis in major depression, in

which melatonin levels are low,[26] results from a lack of this modulating

influence by the pineal gland.[27] Melatonin levels are low in patients with

Cushing's disease,[26] a pathologic variety of hyperadrenocorticism.

Melatonin antagonizes several effects of exogenous corticoids: immune

depression[28] and hypercatabolism, thymic involution, and adrenal

suppression.[29] These findings have led to the suggestion that melatonin

might work as an antiadrenocortical or antistress factor.[29] The

melatonin/corticoid relationship is significant because chronic

hypercortisolemia has been linked to several aspects of aging and

age-associated phenomena, including glucose intolerance, atherogenesis,

impaired immune function, and cancer.[30]

In addition to high absolute levels of corticoids, disorganization of the

normal rhythm of corticoid release is also pathogenic. Corticoids are

normally high in the early morning and daytime, and low at night. Properly

timed exogenous melatonin may entrain, or reorganize, this critical

endocrine rhythm, resulting in long-term systemic benefit. Indeed, the

immune-enhancing and anticorticoid effects of melatonin, or putative

mediators of melatonin action, appear to depend on nocturnal

administration.[28,31] This may represent an integral immune-recovery

mechanism by which melatonin acts as a kind of buffer against the harmful

effects of stress on immune homeostasis.[28]

Beta-adrenoceptor blockers, which depress melatonin secretion, exert

immunosuppressive effects, but only when given in the evening.[32,33] This

is when blood melatonin (and the immunoenhancing effect of melatonin) is

highest. Exogenous melatonin reverses beta-blocker-induced immunosuppression

and enhances immune parameters in animals. A preliminary report of patients

with AIDS who took melatonin 20 mg daily in the evening revealed uneven but

generally beneficial effects on immune parameters.[34] It has been

recommended that the dose be timed not only periodically within each day (at

night only) but also periodically within the month, with treatment periods

of 3-4 weeks, followed by a week-long " washout " period.[33]

Immunomodulatory effects of melatonin were also observed recently in healthy

subjects and patients with bronchial asthma.[35] Melatonin increased

production of interleukin (IL)-1, IL-6, and tumor necrosis factor-alpha,

indicating the possibility of an adverse effect of exogenous melatonin in

patients with asthma. On the other hand, in a model of adjuvant-induced

arthritis, both prophylactic and therapeutic melatonin administrations

inhibited the inflammatory response.[36] This inhibition was accompanied by

enhanced thymocyte proliferation and IL-2 production by melatonin. In

another animal study, melatonin was shown to possess both cellular and

humoral immunoenhancing effects, and immune responses were augmented even in

the absence of previous immunosuppression.[37] Melatonin-receptor

immunoreactivity has also been detected in the human eye,[38] the

physiologic function of which remains unclear.

Predictably, melatonin-induced corticoid antagonism and immune enhancement

may not always be desirable. Melatonin should be used cautiously, if at all,

in patients with autoimmune conditions and in those with known or suspected

adrenocortical insufficiency. The effects of melatonin on the immune system

are complex, occasionally contradictory, and depend on several factors,

including the dose of melatonin, the immune status of the animal (as well as

its age, sex, and species), the season during which the immune system is

studied, circadian rhythm of immunity, pineal gland status, and presence of

a stressful condition.[39]

Cancer

It has been suggested that the steady rise in the incidence of cancer in

developed countries during the last 100 years is caused by the routine,

artificial extension of the photoperiod by electric lights, or " light

pollution. " [40] A long photoperiod results in depressed melatonin secretion

during the night. In animals, melatonin inhibits the incidence of chemically

induced tumors, which is increased by pineal suppression (long light phase)

or pinealectomy.[41] Pinealectomy stimulates and/or melatonin inhibits the

growth and sometimes the metastasis of experimental cancers of the lung,

liver, ovary, pituitary, and prostate as well as melanoma and leukemia.[42]

Breast cancer

Clinical evidence suggests a role for melatonin in the prevention and even

the treatment of breast cancer.[43] For example, the circadian amplitude of

melatonin was reduced by more than 50% in patients with breast cancer vs

patients with nonmalignant breast disease,[44] and high melatonin levels

have been found in morning urine samples of breast cancer patients,[45]

suggesting circadian disorganization. Melatonin downregulates estrogen

receptors; inhibits estrogen-stimulated, breast cancer growth; and

complements the oncostatic action of antiestrogen drugs (tamoxifen), leading

to the suggestion that melatonin is a 'natural antiestrogen.'[46] Moreover,

a synergy has been demonstrated between melatonin and all-trans-retinoic

acid (ATRA), allowing the use of lower doses of ATRA and thus avoiding its

adverse effects.[47]

The molecular mechanisms of melatonin have also begun to be better

understood. Melatonin has been shown to shift forskolin- and

estrogen-induced elevation of cyclic adenosine monophosphate (cAMP) levels

by 57% and 45%, respectively,[48] thereby affecting signal-transduction

mechanisms in human breast cancer cells.

Anisimov and coworkers[49] have found that constant treatment with melatonin

reduced the incidence and size of breast carcinomas as well as lowered the

incidence of lung metastasis, but interrupted treatment-promoted, mammary

carcinogenesis in transgenic mice. They further observed that the life span

of the group receiving interrupted treatment was shorter; however, this

outcome could be attributed to the transgenic nature of mice used, but this

needs further evaluation.

Prostate and Colorectal Cancers

Melatonin may also play a special role in prostate and colorectal cancers.

Circadian amplitude of melatonin is reduced by two thirds in patients with

prostate cancer as compared with those who have benign prostate disease,[44]

and similar phenomena have been observed in patients with colorectal

cancer.[50] In prostatic carcinoma, melatonin exerts complex interactions

with androgen receptors and affects intracellular trafficking; melatonin

does not affect cell growth in the absence of dihydrotesterone.[51] In 1

study, 54 patients with metastatic solid tumors, primarily lung and

colorectal, received intramuscular melatonin, 20 mg daily at 3 pm for 2

months and then 10 mg daily. This regimen resulted in stabilization of the

disease and improved quality of life for about 40% of the recipients.[52]

The antiproliferative and proapoptotic actions of melatonin on experimental

colon carcinoma are probably mediated by melatonin MT(1) and MT(2)

receptors.[53]

In another study, melatonin 10-50 mg daily at 8 pm potentiated IL-2

immunotherapy of pulmonary metastases.[33] As with melatonin therapy in

patients with AIDS, the study encouraged treatment periods of 3-4 weeks with

a 1-week washout.

Melatonin injections have been found to stimulate tumor growth if given in

the morning, have no effect when given in midafternoon, and have a retarding

effect in the evening.[45,46]

Some have suggested that melatonin be administered to patients at earlier

stages of cancer, in parallel with standard oncologic treatment

regimens.[54] However, some questions remain concerning the anticancer

effects of melatonin,[55] and data from stringent, large, randomized

clinical trials are required before melatonin can be universally accepted as

an anticancer drug.

Brain Function, Neuropsychiatry, and Behavior

Seizures

The pineal, acting primarily but not exclusively through melatonin, is

proposed to be a " tranquilizing organ " that promotes homeostatic

equilibrium.[7] Melatonin stabilizes the electrical activity of the central

nervous system and causes rapid synchronization of the

electroencephalogram.[9] By contrast, pinealectomy predisposes animals to

seizures.[9] Recent evidence from experimental work suggests that melatonin

provides anticonvulsant activity in various models of epilepsy. In mice,

intracerebroventricular administration of melatonin protected against

seizures induced by kainate, glutamate, and N-methyl-D-aspartate;[56]

however, it was ineffective against pentylenetertrazol-induced seizures,

thereby suggesting a potential role in grand mal epilepsy. Similarly,

melatonin antagonized the seizure-producing effects of cyanide[57] and

ferric chloride.[58] The anticonvulsant effect of melatonin has also been

demonstrated in amygdala-kindled rats.[59]

Some of these experimental data have been corroborated by clinical studies

in patients with epilepsy. Bazil and colleagues[60] found melatonin levels

to be reduced in patients with intractable epilepsy. In a study of 6

children with intractable seizures, administration of 3 mg of oral melatonin

30 minutes before bedtime in addition to the antiepileptic regimen led to

clinical improvement in seizure activity in 5 of the children, by parent

report.[61] However, because of the paucity of well-controlled studies,

melatonin cannot, as yet, be recommended in any form of epilepsy, although

it may have some role as an adjuvant therapy for children with intractable

seizures.

Depression

Nocturnal melatonin levels are low in subjects with major depressive

disorder and panic disorder.[62,63] This is particularly marked in subjects

with abnormal pituitary-adrenal responses to exogenous corticoids (abnormal

dexamethasone suppression)[27] who also have disturbed corticoid-secretion

patterns. Healthy individuals with a dysthymic disposition (mild or episodic

depression) also had lower-than-normal nocturnal melatonin levels[27] as did

subjects with melancholic depression.[64] By contrast, higher-than-normal

melatonin levels have been observed in manic subjects during the manic

phase.[64] More significant than changes in the absolute melatonin level at

any given time is the amplitude of the circadian melatonin rhythm, which is

blunted in patients with depression and becomes normal on recovery.[65]

The link among melatonin levels, pineal function, and mood disorders is

strengthened by epidemiologic and chronobiological evidence. Both seasonal

affective disorder (SAD) and classic " nonseasonal " depressions demonstrate a

marked seasonal incidence with peaks in the fall and spring,

respectively.[66,67] This coincides with the troughs of the circannual

melatonin rhythm.[68]

The requirement of intact beta-receptor function for melatonin synthesis and

the stimulatory effect of norepinephrine on melatonin synthesis and

release[7] point toward a theoretic relation of melatonin to depression.

Several of the tricyclic antidepressants dramatically increase melatonin

synthesis in humans.[69,70] In one study, 8 weeks of clomipramine treatment

resulted in a lowering of melatonin levels at 12 am, 2 am and 4 am as well

as an elevation of melatonin levels at 8 am, 2 pm, and 8 pm.[70] Thus, it is

possible that the relation of norepinephrine action to affective disorders

is mediated in part by effects on melatonin synthesis. Tricyclics often

exert sedative effects and for this reason are often administered at

night -- an appropriate time to enhance melatonin rhythm amplitude.

Furthermore, beta-receptor blockers depress melatonin secretion[8] and can

cause neuropsychiatric problems, such as nightmares, insomnia, lassitude,

dizziness, and depression.[71]

Brain serotonin levels rise after melatonin administration,[72] which may be

significant because serotonin has been linked with an array of

neuropsychiatric phenomena.[73-77] Diminished central serotonin, as

indicated by low levels of the serotonin marker 5-hydroxy indole acetic acid

(5-HIAA) in cerebrospinal fluid, is associated with impulsiveness,

aggression and autoaggression,[73-75] alcoholism,[76] compulsive gambling,

overeating, and other obsessive-compulsive behaviors.[77] Support of the

serotonin system with serotonergic nutrients or drugs can elevate mood,

reduce aggression, increase the pain threshold, reduce anxiety, relieve

insomnia, improve impulse control, and ameliorate obsessive-compulsive

syndromes.[77-79]

Endogenous Depression

Classic endogenous or " nonseasonal " depression is characterized by insomnia

(especially early-morning awakening), appetite suppression and weight loss,

and advanced onset of nocturnal melatonin release; these individuals are

probably phase-advanced ( " morning people " ), although not very

effectively.[80] Classic depression typically begins in the spring and

persists through the summer,[67] the period of light-phase lengthening. This

group may benefit from an induced phase delay (and light-phase shortening)

effected by bright light exposure in the evening,[81] later rising with

avoidance of bright light in the morning and melatonin administration

(especially delayed-release melatonin) in the late evening or immediately

before bed. Melatonin administration that prolongs the nocturnal melatonin

rise may exacerbate SAD[82] and bipolar and classic depression.[83] In this

latter study,[83] large quantities (> 1 g/day) of melatonin were taken in

divided doses throughout the day, thus abolishing the normal, daily

melatonin rhythm.

The use of large doses of melatonin in the morning and early afternoon

represents exceedingly poor design for a study examining the hormone's

effects on depression (or any other condition), especially when one

considers the clear evidence that blunted amplitude and disturbed melatonin

rhythm play a role in depression, rather than low absolute levels at any

given time.[65,84] Thus, melatonin should be used only with caution in

patients with depression and should always be appropriately timed and in

conjunction with light therapy and sleep-phase change. Disruption of normal

circadian rhythm by poorly timed melatonin administration can logically

worsen depression.

In a recent study of postmenopausal women, melatonin administration led to a

significant mitigation of depression.[85] In a large-dose-range trial,

agomelatine, a melatoninergic agonist, was found to alleviate depression as

well as anxiety.[86] However, another study found that the addition of

melatonin to ongoing fluoxetine treatment had no beneficial effect on the

3-month outcome, postelectroconvulsive therapy.[87]

Seasonal Affective Disorder

SAD is characterized by late sleep, morning hypersomnia, increased appetite,

and retarded onset of nocturnal melatonin release. SAD subjects are probably

phase-delayed ( " night people " ).[74,75] SAD typically begins in the fall and

persists through the winter,[67] during the period of light-phase

shortening. SAD sufferers may benefit from induced-phase advance (and

light-phase lengthening), effected by bright light exposure in the morning

(especially predawn), early rising (to the point of partial morning sleep

deprivation, eg, rising at 3-4 am), and melatonin administration before bed,

which should be early in the evening.[88]

The relationship between depression and light deprivation has been

reviewed.[89,90] Phototherapy as an adjuvant in depression may accelerate

responses to antidepressants among patients with depression.[91] Moreover,

melatonin secretion has been shown to be wavelength-dependent as exposure to

monochromatic light at 460 nm produced a 2-fold greater circadian phase

delay.[92]

Antioxidant Uses

The antioxidant effects of melatonin have been well described[93-95] and

include both direct as well as indirect effects. The mechanism of

antioxidant effects has also been evaluated. Melatonin administration leads

to increased expression of the antioxidant enzymes superoxide dismutase and

glutathione peroxidase[96]

Central Nervous System

Melatonin has been found to prevent cell death and

methylphenyltetrahydropyridine- (MPTP) induced damage to the substantia

nigra in experimental parkinsonism, and thus prevented disease progression

in these animals.[97] Melatonin pretreatment reduced cerebral infarct size

and edema after middle cerebral artery occlusion and ischemia-reperfusion

injury in rats.[98] Melatonin has been suggested as a candidate

neuroprotective compound for patients with amyotrophic lateral

sclerosis.[99] Furthermore, a study examining the neuroprotective effects of

melatonin in various regions of the central nervous system demonstrated an

antioxidant effect of melatonin in the total spinal cord, optic nerve,

brain, and spinal cord white matter, with the most potent effects seen in

the spinal cord white matter.[100]

In a rodent model of Alzheimer's disease, melatonin reduced plasma

homocysteine and lipid levels,[101] and the investigators suggested that the

antioxidant effect of melatonin may have been responsible for these results.

In patients with Alzheimer's disease, cerebrospinal fluid melatonin levels

have been found to be significantly reduced.[102] In a study of 14 patients

at various stages of Alzheimer's disease,[103] melatonin supplementation for

22-35 months improved sleep and significantly reduced the incidence of

" sundowning. " Furthermore, patients experienced no cognitive or behavioral

deterioration during the study period. The neuroprotective effects of

melatonin are not mediated by membrane melatonin receptors and, thus, they

may result from the antioxidant and antiamyloidogenic property of

melatonin.[104]

Cardiovascular System

Cardioprotective activity,[105-109] mediated by antioxidant effects of

melatonin,[109] has been observed in experimental models of myocardial

ischemia-reperfusion[105,107] and myocardial infarction.[105,106] Melatonin

reduced infarct size, suppressed the frequency as well as duration of

ventricular tachycardia and fibrillation, and improved survival in these

models.

One review noted that melatonin has cut cholesterol levels by 38% in human

subjects and has reduced blood pressure and catecholamine levels, perhaps

via relaxation of smooth muscles in aortic walls.[108] Melatonin also

inhibits copper-induced oxidation of low-density lipoprotein (LDL),[109]

thereby potentially contributing to an antiatherosclerotic effect. A study

of 5 patients with cardiac syndrome X found that nocturnal melatonin levels

were markedly reduced.[110]

Gastrointestinal System

Gastroprotective effects of melatonin have been observed in various models

of gastric ulcers at several laboratories, including ours.[111-113] These

effects may also be related to the antioxidant effects of melatonin. In

experimental models of acute pancreatitis, melatonin has shown beneficial

effects.[114,115] Other diseases for which melatonin may be added to

existing therapies include irritable bowel syndrome, ulcerative colitis, and

diarrhea.[3]

Renal Diseases

Melatonin has been found to be protective against glycerol-induced renal

failure because of its antioxidant effect.[116] Melatonin also reduced

interstitial renal inflammation and improved hypertension in spontaneously

hypertensive rats.[117] More evidence from well-conducted clinical trials is

required before a final recommendation can be made.

Miscellaneous Conditions

An animal study found melatonin and vitamins C and E to be protective

against lung injury.[118] A series of 3 cases reported that melatonin

improved platelet counts in patients with idiopathic thrombocytopenic

purpura.[119] Melatonin was also found to be useful in cisplatin-[120] and

cyclosporine-[121] induced acute renal injury, doxorubicin-induced

cardiotoxicity,[122] and a number of other drug-induced diseases. The

beneficial effects of melatonin in this field have been reviewed.[123]

Comparison of Melatonin With Vitamins C and E in Animal Models

A few studies have compared the antioxidant effects of melatonin with other

antioxidants.[124-126] Melatonin has been found to be more efficient than

vitamin C in reducing the extent of oxidative stress in an experimental

model of Alzheimer's disease.[124] In another animal model, melatonin was

found to be at least as effective as a combination of vitamins C and E in

reducing the oxidative stress induced by chlorpyrifos-ethyl in rats.[125]

Melatonin was also found to reduce markers of oxidative stress more

significantly than vitamin E or N-acetylcysteine against acetaminophen

toxicity in mice.[126]

The antioxidant benefit of pharmacologic melatonin therapy has been

questioned, however.[127] Moreover, in a 2003 study,[128] in ion-free

medium, melatonin did not scavenge hydrogen peroxide and was found to be

devoid of direct antioxidant effects. Only placebo-controlled, randomized

trials with hardcore clinical end points will provide a definite answer.

Antiaging Hormone

Studies linking melatonin loss to age-related phenomena and the case for

melatonin as an antiaging substance have been highlighted in review

articles.[9,129] One proponent of this hypothesis suggests that " the

Melatonin Deficiency Syndrome is perhaps the basic mechanism through which

aging changes can be explained. " [129] Indeed, some believe that the data

thus far support the possibility that supplemental melatonin may be

beneficial.[130]

An experimental study found significant declines in plasma melatonin levels

in aged ring doves.[131] In addition, the capacity of the animals for

ingestion and destruction of Candida albicans and phagocytosis was reduced

by aging and restored by exogenous administration of melatonin.

Melatonin levels decline with age in humans,[132] and the nocturnal

melatonin peak is almost completely lost.[133] Because of the close

reciprocal relation of melatonin and corticoids, this loss of melatonin

rhythmicity may be responsible for the pituitary/adrenal axis disinhibition

that has been described as a characteristic of aging. The adrenals of

elderly humans are apparently hypersensitive to adrenocorticotropic hormone,

and midnight corticoid levels (low in youth) are markedly elevated in old

age.[134] The effects of melatonin on both the release of corticoids and

their peripheral effects, the pathogenic conditioning influence of corticoid

excess, and the phasic inhibitory influence of melatonin on the

pituitary/adrenal axis have been discussed. Modification of

corticoid-related phenomena could explain much of melatonin's apparent

antiaging and other beneficial actions.

Despite the evidence linking lowered levels of melatonin with aging, the

decline may not be so dramatic in reality. That is why melatonin cannot be

unequivocally recognized as a substance that delays aging, although some of

its actions may be beneficial to the process of aging.[135]

Blindness (which increases melatonin levels by virtue of effective constant

darkness) and melatonin administration both increase the life span of

rats.[130,136] However, in many cases melatonin levels are free-running, and

in one study, low doses (0.5 mg) of melatonin entrained a blind person with

free-running melatonin rhythms.[137]

Toxicology and Potential for Harm

The acute toxicity of melatonin as seen in both animal and human studies is

extremely low. Melatonin may cause minor adverse effects, such as headache,

insomnia, rash, upset stomach, and nightmares. In animals, an LD50 (lethal

dose for 50% of the subjects) could not be established. Even 800 mg/kg

bodyweight (high dose) was not lethal.[138] Studies of human subjects given

varying doses of melatonin (1-6.6 g/day) for 30-45 days, and followed with

an elaborate battery of biochemical tests to detect potential toxicity, have

concluded that, aside from drowsiness, all findings were normal at the end

of the test period.[139,140]

Animal studies suggest that melatonin can downregulate the pituitary/gonadal

axis resulting in hypogonadism and/or delayed puberty. However chronic

administration of low-dose melatonin in men did not alter blood levels of

testosterone or luteinizing hormone.[141] One case of extremely high

melatonin levels associated with delayed puberty and hypogonadism has been

reported.[142] Pubertal development and resolution of the hypogonadism

occurred spontaneously as melatonin levels declined over several years.

Recent experimental evidence demonstrates that melatonin reduces sperm

motility[143] and that long-term administration inhibits testicular

aromatase levels.[144]

Melatonin has also been suggested for use as a contraceptive for women,[145]

which might raise the question of whether melatonin damages the female

reproductive system. Notably, no side effects were reported in a report of a

phase 2 clinical trial in which 1400 women were treated with 75 mg of

melatonin nightly for 4 years.[145]

Preliminary animal studies suggest that melatonin may accelerate the

development of autoimmune conditions.[146] Melatonin transiently exacerbated

neurologic symptoms in 1 patient with multiple sclerosis.[147]

Although melatonin is a potential adjunctive agent in the treatment of

cancer and immune deficiency, poorly timed administration can produce

opposite effects. Melatonin injections given in the morning stimulate tumor

growth,[46,148] whereas the same doses in midafternoon have no effect but in

the evening have a retarding effect. And although some people with

depression may suffer from a " low melatonin syndrome, " [27] melatonin

administration that unduly prolongs the nocturnal melatonin rise, or that is

given throughout the day, may exacerbate SAD[82] and bipolar and classic

depression.[83] Finally, animal studies have shown that moderately large

doses of melatonin (equivalent in one study to about 30 mg in adult humans)

increased light-induced damage to retinal photoreceptors.[149]

There is also some concern regarding increased atherosclerosis in the aorta

in hypercholesterolemic rats caused by melatonin.[150] Moreover, in these

animals LDLs were less well recognized by LDL-receptor metabolic pathways

when melatonin was administered.

Melatonin is widely available as an over-the-counter supplement marketed by

different companies. These supplements may not be similar in dosage and/or

composition, and some of them may contain additional vitamins. Moreover,

melatonin may interact with other over-the-counter drugs, although such

interactions have not been systematically evaluated and, therefore, remain

unreported.

Clinical Evaluation of the Patient

No definitive guidelines have been formulated for clinical evaluation of

patients with low melatonin levels, in large part because a " melatonin

deficiency syndrome " has not yet been defined as an independent entity. The

secretion of melatonin is usually detected by analyzing the serum or

salivary levels.[151] The salivary levels are considered equivalent to serum

levels except in the elderly or in patients with dry mouth.[152] In the

first situation, the validity, and in the second situation, the feasibility

of salivary melatonin levels are compromised. If the treating physician

suspects that melatonin deficiency may be responsible for a patient's

symptoms, it is tempting to consider the possibility of exogenous

administration of melatonin. However, we must await more substantive

clinical evidence before any precise recommendations can be made.

Conclusion

Melatonin has the potential to be of use in a large number of disorders of

different etiologies. However, unequivocal evidence of its efficacy has been

established only for a few conditions -- jet lag, depression, and insomnia.

It has not yet been possible to effectively determine the immunomodulatory

effects of melatonin because both immunosuppression and immunoenhancement

have been observed in different settings. The oncostatic use of melatonin

may become a part of an anticancer drug regimen. An anticonvulsant effect of

melatonin has been consistently observed in animal models, but proof from

well-controlled clinical trials is still lacking.

Some evidence suggests an antioxidant role of melatonin with the

possibilities of beneficial effects in Alzheimer's disease; parkinsonism;

and cardiovascular, gastrointestinal, and renal disorders. Definite evidence

for the role of melatonin as an antiaging compound has not been obtained.

Melatonin can cause adverse effects, and long-term safety data are lacking.

Furthermore, no information is available concerning the possibility of

interactions with either prescription or nonprescription medications.

Available in many countries as a nutritional adjunct, melatonin has managed

to evade the drug-regulatory authorities. This has led to unregulated and

uncontrolled use of melatonin, which must be prevented unless and until

clear benefits are demonstrated.

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Samir Malhotra, MD, Assistant Professor, Department of Pharmacology, PGIMER,

Chandigarh, India

Girish Sawhney, MD, Senior Resident, Department of Pharmacology, PGIMER,

Chandigarh, India

Promila Pandhi, MD, Professor & Head, Department of Pharmacology, PGIMER,

Chandigarh, India

Disclosure: Samir Malhotra, MD, has no significant financial interests or

relationships to disclose.

Disclosure: Girish Sawhney, MD, has no significant financial interests or

relationships to disclose.

Disclosure: Promila Pandhi, MD, has no significant financial interests or

relationships to disclose.

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