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Newsgroups: alt.drugs
just got done typing this out..
The following is a transcript from _Drugs_And_Behavior_ (Fred Leavit, 1982)
(I apoligize for the screwed up numbers of the references, this is because the
same section of the book looks into other drugs and puts all of the references
to them in the same list, in alphabetical order)
LSD AND RELATED HALLUCINOGENS
- * Tolerance and Withdrawl
Tolerance develops rapidly to LSD, mescaline, and psilocybin, and there
is cross tolerance between them. Cross tolerance is not exhibited between
these agents and dimethyltryptamine (DMT); and little is known about the
development of tolerance to DOM (STP). There are no serious withdrawl
symptoms.
CHROMOSOME DAMAGE. One of the major concerns about LSD stems from a 1967
paper by Cohen et al. (29) that suggested that LSD damages chromosomes. Cells
with damaged chromosomes are potentially dangerous to their bearer, because
they may establish cancerous cell lines, and are dangerous to unborn children,
because chromosomes carry the genetic message across generations.
Dishotsky et al. (36) reviewed the results of 68 studies published between
1967 and 1970, that were concerned with the possibility of LSD-induced
chromosome damage. The highlights of their paper are summarized and discussed
below, but without the original references.
The study by Cohen et al., and several studies which followed it, involved
the addition of LSD to cell cultures. There are problems with this approach.
First, the process of culturing cells stimulates them to enter a reproductive
phase which is abnormal for them. Second, cells in tests tubes are extremely
susceptible to chromosome breakage; aspirin, caffeine, water, and changes in
temperature or oxygen pressure are some of the many agents which induce
breakage of the same order of magnitude as LSD. Third, the type of breakage
produced by LSD is different from that caused by known mutagenic or
carcinogenic agents. Fourth, intact organisms have evolved metabolic and
excretory systems to eliminate harmful substances, but these detoxification
mechanisms are not available to cells in test tubes. Thus, cells have
typically been exposed to very high doses for prolonged periods of time.
Only four studies investigated chromosome breakage rates in humans before
and after exposure to LSD. Only one of the studies was positive. Several
studies reported higher breakage rates in users than in nonusers but, as has
already been discussed ad nauseum, such studies do not allow for causal
interpretation. Some unknown factor(s), such as serious childhood illness,
may predispose people to chromosome damage ant to take LSD (see p. 176). One
obvious factor is that LSD users are likely to use many other drugs as well.
An additional problem is that breakage rates have been measured in white
blood cells rather than in reproductive cells.
Dishotsky et al. pointed out that chromosome damage was much more likely
to occur in users of illicit LSD than in volunteers administered known
quantities of pure LSD in laboratories. The probable explanation is that
illicit LSD contains substantial quantities of adulterants (85 and below), and
these may cause breakage. In several cases, breakage rates returned to the
normal range withing months of the last dose.
As is so disturbingly often the case, the research may tell more about
bias in science than about LSD and chromosome damage. Investigators who
reported more than one study tended to report the same findings in each.
Negative findings may have resulted from small sample size or insensitive
testing procedures; for even if LSD affects chromosomes, the effects will not
show up unless tested with proper experimental procedures. There is evidence
that the negative studies used too few subjects; thus, although only five of
fifteen studies yielded statistically significant results,* LSD users had
nonsignificant but elevated breakage rates in 10 of the studies.
- Statistical significance refers to the probability that observed differences
between two or more groups are due to chance factors. Scientists
conventionally accept research as being statistically significant if the
likelihood that differences are due to chance is less than 1 in 20. If too
few subjects are used, the results will not be statistically significant,
no matter how strong the drug effect (just as , if a two-headed coin is
flipped only four times, the flipper would not be able to conclude on
statistical grounds that the coin is biased). Conversely, if huge numbers
of subjects are used, even trivial differences will attain statistical
significance (which, remember, means only "not due to chance"), but such
results may have little scientific significance.
There have been studies since the Dishotsky et al. paper. In general,
these show no effect of LSD on chromosomes (42, 81, 111, 122).
ACUTE PANIC REACTIONS. Not all drug experiences turn out as anticipated.
Acute panic reactions, depression, paranoia, and psychotic episodes occur
with sufficient frequency to make the phrase "bad trip" and important part of
the lexicon of the drug culture. Any potentially enjoyable event may prove to
be a disappointment, as when rainy weather spoils a picnic. But the special
quality of drug-induced bad trips is that they cannot easily be terminated.
Cohen (31) reported that one of 2500 patients taking LSD during psychotherapy
committed suicide; and 0.02% of normal subjects who took LSD experimentally
experienced psychotic reactions of greater than 24 hours in duration. Louria
(82) used the suicide as reason for condemning the therapeutic use of LSD, a
position that ignores the possibility that the suicide rate of patients in
therapy and not given LSD may be higher than one in 2500.
FLASHBACKS. Flashbacks are sudden and unexpected recurrences of aspects of an
earlier drug experience. In a study of 2256 Army enlisted men, 23% reported
flashbacks from LSD (5% from amphetamine, 1% from marijuana) (132).
Flashbacks have not been shown to be dangerous and, in fact, are often self-
induced. Matefy et al. (87) quoted one user: "I just call it talking yourself
into a flashback.....It's like getting high all over again."
PROLONGED PSYCHOTIC REACTIONS. Pradhan and Hollister (103) stated that fewer
than 1 per 1000 experimental LSD subjects, and fewer than 2 per 1000 patients
who ingest LSD, suffer psychotic reactions lasting longer than 48 hours.
Approximately two-thirds of those who do suffer such reactions present a
history of psychopathology prior to drug use (11). LSD is often taken in a
last-ditch effort to solve and impending crisis which has proven refractory
to other attempts at solution (46). If the drug does not help, symptoms may
worsen, but not because of the LSD. The data do not justify arguments that
LSD is extremely dangerous "because of its capability to induce attempted or
completed homicide, attempted suicides, or even prolonged psychosis" (82, p.
254).
CEREBRAL DEFICIT. Some authors have reported permanent cerebral deficit in
LSD users. Others, however, have disputed the findings (1, 144). In any
event, there are no relevant experimental studies, but only comparisons of
users with nonusers.
Many users of LSD wax lyrical about its ability to promote insights into
everyday problems, to enhance creativity, and to provide mystical and
religious experiences. These claims are evaluated in appropriate chapters.
REFERENCES
1. Acord, L. & Barker, D. Hallucinogenic drugs and cerebral deficit. J.
Nerv. Ment. Dis., 1973, 156: 281-283.
11. Blumenfield, M. & Glickman, L. Ten months experience with LSD users
admitted to county psychiatric receiving hospital. NY State J. Med.,
1967, 67: 1849 - 1853.
29. Cohen, M., Marinello, M., & Back, N. Chromosomal damage in human leuko-
cytes induced by lysergic acid diethylamide, Science, 1967, 155: 1417 -
1419.
31. Cohen, S. Lysergic acid diethylamide: side effects and complications.
J. Nerv. Ment. Dis., 1960, 130: 30 - 40.
36. Dishotsky, N. et al. LSD and genetic damage. Science, 1971, 172: 431 -
440.
42. Fernandez, J. et al. LSD. . . an in vivo retrospective chromosome study.
Ann. Hum. Genet., 1973, 37: 81 - 91.
46. Glickman, L. & Blumenfield, M. Psychological determinants of "LSD reac-
tions." J. Nerv. Ment. Dis., 1967, 145: 79 - 83.
81. Long, S. Does LSD induce chromosomal damage and malformation? A review
of the literature. Teratology, 1972, 6: 75 - 90.
82. Louria, D. Abuse of lysergic acid diethylamide--an increasing problem. In
Wilson, C. (Ed.) Adolescent Drug Dependence. New York: Pergamon, 1968
85. Marshman, J. & Gibbins, R. The credibility gap in the illicit drug
market. Addictionsm 1969, 16: 22 - 25.
87. Matefy, R., Hayes, C., & Hirsch, J. Psychedelic drug flashbacks:
Attentional deficits? J. Abnorm. Psych., 1979, 88: 212 - 215.
95. Naditch, M. Acute adverse reactions to psychoactive drugs, drug usage,
and psychopathology. J. Abnorm. Psych., 1974, 83: 394 - 403.
103. Pradhan, S. & Hollister, L. Abuse of LSD and other hallucinogenic drugs.
In Drug Abuse: Clinical Aspects and Basic Aspects. St. Louis: Mosby,
1977.
111. Robinson, J. et al. Chromosome aberrations and LSD: A controlled study in
50 psychiatric patients. Br. J. Psychiatr., 1974, 125: 238 - 244
122. Simmons, J., Sparkes, R., & Blake, P. Lack of chromosomal damaging
effects by moderate doses of LSD in vivo. Clin. Genet., 1974, 5: 59 -
61.
125. Smith, D. & Mehl, C. An analysis of marijuana toxicity. In Smith, E.
(Ed.) The New Social Drug. Englewood Cliffs, N.J.: Prentice-Hall, 1970.
132. Stanton, M. & Bardoni, A. Drug flashbacks: Reported frequency in a
military population. Am. J. Psychiatr., 1972, 129: 751 - 755.
144. Wright, M. & Hogan, T. Repeated LSD ingestion and performance on neuro-
psychological tests. J. Nerv. Ment. Dis., 1972: 432 - 438.