Delta-9-Tetrahydrocannibinol as an Antiemetic in Cancer
Patients Receiving High-Dose Methotrexate
Prospective, Randomized Evaluation
ALFRED E. CHANG, M.D.; DAVID
J. SHILING, M.D.; RICHARD C. STILLMAN, M.D.; NELSON H. GOLDBERG, M.D.; CLAUDIA
A. SEIPP, R.N.; IVAN BAROFSKY, Ph.D.; RICHARD M. SIMON, Ph.D.; and STEVEN A.
ROSENBERG, M.D., Ph.D.; Bethesda, Maryland
From the Surgery and
Biometric Research Branches. Division of Cancer Treatment, National Cancer
Institute; the Laboratory of Clinical Psychopharmacology and Unit on
Geriatric Psychiatry, Division of Special Mental Health Research, National
Institute of Mental Health; and the Division of Research. National Institute on
Drug Abuse; National Institutes of Health; Bethesda, Maryland.
ABSTRACT: Fifteen
patients with osteogenic sarcoma receiving high-dose methotrexate chemotherapy
were studied in a randomized, double blind, placebo-controlled trial of oral
and smoked delta-9-tetrahydrocannabiriol (THC) as an antiemetic. Each patient
served as his or her own control. Fourteen of 15 patients had a reduction in
nausea and vomiting on THC as compared to placebo. Delta-9-tetrahydrocannabinol
was significantly more effective than placebo in reducing the number of
vomiting and retching episodes, degree of nausea, duration of nausea, and
volume of emesis (p < 0.001). There was a 72% incidence of nausea and
vomiting on placebo. When plasma THC concentrations measured < 5.0 ng/mL,
5.0 to 10.0 ng/mL, and > 10.0 ng/mL. The incidences of nausea and vomiting
were 44%, 21%, and 6%, respectively. Delta-9-tetrahydrocannabinol appears to
have significant antiemetic properties when compared with placebo in patients
receiving high-dose methotrexate.
(ANNALS OF INTERNAL MEDICINE. DECEMBER 1979; 91: 819-824)
Nausea and vomiting are
frequent and distressing side effects of cancer chemotherapy. The severity of
these symptoms contributes to the decreased ability of patients to undergo
long-term chemotherapy schedules and impairs their quality of life (1, 2).
Despite the magnitude of this problem, there have been few clinical reports
(3-11) investigating the effectiveness of various antiernetics in controlling
the nausea and vomiting associated with chemotherapy. Conventional antiemetics,
when tested, have been relatively ineffective in reducing these side effects.
Sallan and colleagues (7)
were able to show that oral-delta-9-tetrahydrocannabinol (THC) had significant
antiemetic properties in patients receiving various chemotherapy regimens. As
in previous antiemetic studies, nausea and vomiting were assessed solely from
subjective impressions based on patient interviews the day after each drug
trial. The purpose of our study was to examine in a randomized, double-blind,
placebo-controlled trial the efficacy of oral and smoked THC as an antiemetic.
To do this we obtained both objective and subjective data during each drug
trial. Serial blood samples were drawn during the course of each trial to
ascertain the effective plasma concentration of THC needed to obtain an
antiemetic effect.
METHODS
PATIENT POPULATION
Fifteen patients with
osteogenic sarcoma treated by the Surgery Branch of the National Cancer
Institute were studied. Ten were males and five, females; they ranged in age from
15 to 49 years (median, 24 years). All patients had undergone surgical removal
of their primary tumor (14 amputations and one chest-wall resection) and were
disease free upon entry into the study. All patients received adjuvant
high-dose methotrexate therapy with leucovorin calcium rescue at 3-week
intervals for a total of 18 months. Methotrexate was given at a constant dose
of 250 mg/kg in each patient. Before participating in the study each patient
was evaluated by a psychiatrist (D.S.) to screen out those likely to have
untoward reactions to psychoactive drugs. The study was thoroughly explained to
each patient and signed informed consent obtained. Each patient was told he or
she would "blindly" receive either placebo or "THC, a marijuana-type
compound" during the day of chemotherapy.
STUDY DESIGN
Each patient served as his
or her own control. Patients accepted into the study entered Phase I and
received THC three times and placebo three times during the six subsequent
hospital admissions for chemotherapy infusion. The order of THC and placebo
administration for these six methotrexate infusions was randomized into three
paired trials of either placebo-THC or THC-placebo. At the end of three paired
trials, which took approximately 5 to 6 months to complete, patients were
classified as "excellent, "fair," or "nonresponders"
to THC (see below) and entered Phase II. In Phase II,
"excellent" responders received eight THC trials and two placebo
trials during their next 10 courses of chemotherapy. The enriched sequence of
THC trials was designed to assess whether repeated trials of THC resulted in
continued antiemetic responses. If the patient was a "fair" responder
or "non responder" to THC. The dose was increased by one third, and
the patient re-entered Phase I to see if additional benefits could be obtained.
DRUG DOSE AND SCHEDULE
Delta-9-tetrahydrocannabinol
capsules and cigarettes were supplied by the National Institute on Drug Abuse.
The THC was suspended in sesame oil and placed in gelatin capsules. Identical-appearing
placebo capsules contained only sesame oil. Placebo cigarettes were produced by
multiple extractions of natural marijuana with ethanol. The active cigarettes
were prepared from these placebo cigarettes by injection of THC through a
spinal needle; each weighed 900 mg and contained 1.93% THC (about 17.4 mg)
(12). The odor and taste of a lit placebo cigarette were identical to those of
a marijuana cigarette.
Delta-9-tetrahydrocannabinol
was administered at a dose of 10 mg/m2 given orally every 3 h for a
total of five doses. The first dose was given at 0700 h. 2 h before the 6-h
methotrexate infusion. All patients had undergone an 8-h fast before
chemotherapy infusion to standardize pretreatment oral intake. In the event of
a vomiting episode, the patient was given a THC cigarette for the remaining
doses of that trial. Variation in the amount of smoke inhaled by each patient
was minimized by using a standard inhalation technique (12). Each patient would
hold the inhalation for 10 seconds, then exhale; after a 50 second wait the
cycle was repeated until the whole cigarette was smoked. Most patients finished
their cigarettes within 8 mm. A dose modification was made only in the event of
a dysphoric reaction, in which case all subsequent oral or smoked doses were
decreased by one third for that patient. Placebo drug administration was
handled in a similar fashion. Neither the patients nor the nursing staff was
informed which drug was being administered.
PATIENT EVALUATION AND
RESPONSE CRITERIA
Data collection for each
trial started at 0700 h and lasted until 2400 h the day of chemotherapy. A
member of the nursing staff rated the patient every hour by completing an
objective questionnaire that measured number of vomiting episodes (an event
producing > 30 mL of emesis), number of retching episodes, volume of
emesis, degree of nausea (0 to 3 point scale: 0 = none; 1 = slightly; 2 =
moderately; 3 = greatly), duration of nausea, and volume of oral intake.
Similarly, once during each wakeful hour, the patient completed a subjective
questionnaire rating the psychological "high" (0 to 3 point scale: 0
= none; 1 = slightly; 2 = moderately; 3 = greatly), degree
of nausea, degree of comfort, and other drug side effects (questionnaire
available upon request).
Four variables used to
evaluate individual responses to THC and placebo were the number of vomiting
and retching episodes, volume of emesis, degree of nausea, and duration of
nausea. The nausea and vomiting variables on all completed paired THC trials
and all placebo trials in Phase I were summed. An "excellent"
response was defined as a > 80% reduction for all four nausea and
vomiting variables on THC as compared to placebo. A "fair" response
was defined as > 30% but < 80% reduction of at least three
study variables while on THC. "No response" was defined as < 30%
reduction of at least two study variables while on THC.
THC PLASMA CONCENTRATIONS
Five-milliliter aliquots of
venous blood were drawn from a heparin lock placed in each patient the day of
chemotherapy. Blood samples were drawn immediately before each THC or placebo
dose and 1 hour later.
Within 6 h after collection
in glass tubes, plasma was drawn off heparinized blood samples and subsequently
stored at - 40 degrees Centigrade. Plasma samples were quantitatively analyzed
for THC by Battelle Laboratories, Columbus, Ohio. The analysis was done by gas
chromatography/chemical ionization-mass spectrometry (13, 14).
Deuterium-labeled THC was used as an internal standard.
STATISTICAL ANALYSIS
Statistical analyses were
restricted to Phase I of the study. The data were analyzed by three different
methods. The first method, described by Koch (15), used only data for the first
paired trial. This method tested whether the relative efficacy of THC or
placebo depended on the order of administration in the first two trials,
whether one drug was more effective than the other, and whether the
effectiveness of both drugs changed from the first trial to the second. In the
second method of analysis, for each study variable and each patient, the sum of
the values of Phase-I paired trials in which THC was administered was
subtracted from the sum of the Phase-I paired trials in which placebo was
administered. The sign of this difference was ascertained for each patient and
each variable and a sign test done. The third method of analysis consisted of a
blocked Wilcoxon test for each variable in which the 15 patients determined the
blocks. The data within each block consisted of the Phase-I paired trials for
that patient. All significance levels correspond to two-tailed tests.
Table 1. Nausea and vomiting variables in Phase I ©
|
Patient Number
|
Number of Paired Trials
|
Total and Vomiting Retching Episodes ¨ |
Total Volume of Emesis ¨ |
Total Degrees of Nausea ¨ |
Total Duration of Nausea ¨ |
Response to THC ª
|
||||
|
THC |
Placebo |
THC |
Placebo |
THC |
Placebo |
THC |
Placebo |
|||
|
numbers |
milliliters |
nausea points |
hours |
|||||||
|
1 |
2 |
15 |
23 |
790 |
2820 |
17 |
31 |
2.1 |
3.4 |
Fair |
|
2 |
2 |
26 |
50 |
1000 |
2020 |
25 |
41 |
2.9 |
6.6 |
Fair |
|
3 § |
1 |
0 |
0 |
0 |
0 |
0 |
10 |
0 |
3.3 |
Excellent |
|
4 |
3 |
0 |
99 |
0 |
1800 |
1 |
48 |
0 |
13.4 |
Excellent |
|
5 |
3 |
4 |
31 |
195 |
1730 |
8 |
82 |
1.8 |
26.1 |
Excellent |
|
6 |
1 |
2 |
21 |
75 |
690 |
2 |
21 |
0.3 |
8.6 |
Excellent |
|
7 § |
3 |
1 |
79 |
500 |
3020 |
5 |
41 |
0.2 |
10.8 |
Excellent |
|
8 |
3 |
44 |
113 |
3950 |
4095 |
45 |
62 |
4.7 |
12.5 |
Fair |
|
9 |
3 |
9 |
53 |
500 |
2605 |
5 |
33 |
0.6 |
3.0 |
Excellent |
|
10 |
2 |
0 |
0 |
0 |
0 |
3 |
0 |
0.1 |
0 |
None |
|
11 |
2 |
22 |
61 |
1100 |
1870 |
14 |
44 |
3.1 |
13.0 |
Fair |
|
12 |
2 |
11 |
18 |
475 |
1250 |
12 |
27 |
0.3 |
5.4 |
Fair |
|
13 § |
2 |
0 |
12 |
0 |
600 |
2 |
31 |
0.2 |
5.9 |
Excellent |
|
14 § |
2 |
0 |
6 |
0 |
400 |
8 |
28 |
0.5 |
3.4 |
Fair |
|
15 |
1 |
0 |
5 |
0 |
325 |
0 |
15 |
0 |
1.2 |
Excellent |
|
Patient Number |
Number of Paired Trials |
numbers |
milliliters |
nausea points |
hours |
Response to THCª |
||||
|
THC |
Placebo |
THC |
Placebo |
THC |
Placebo |
THC |
Placebo |
|||
|
Total and Vomiting Retching Episodes ¨ |
Total Volume of Emesis ¨ |
Total Degrees of Nausea ¨ |
Total Duration of Nausea ¨ |
|||||||
|
© Sixty-four trials: 32 delta-9-tetrahydrocannabinol, 32 placebo. |
|
¨ p < 0.001 (sign test and blocked Wilcoxon test). |
|
ª THC = delta-9-tetrahydrocannabinol |
|
§ No previous marijuana experience |
RESULTS
Between August 1977 and
September 1978, 19 patients with osteogenic sarcoma receiving high-dose
methotrexate were approached for entry into the study. Fifteen patients agreed
to participate. None of these patients was deemed ineligible for the study
based on psychiatric evaluations. Four of the patients were inexperienced users
marijuana before entering the study. The 15 patients completed a total of 97
drug trials in both Phase I and 11 58 THC and 39 placebo trials. A drug
administration compliance rate of 96% was maintained throughout the study.
PHASE I
Table 1 lists the results
of the 64 completed paired trials in Phase I. Each study variable represents
the sum of all responses on THC trials and placebo trials completed by each
patient. There was a reduction of nausea and vomiting in 14 of 15 patients.
Eight of the 15 patients had an "excellent" response, specifically a
> 80% reduction of all nausea and vomiting variables, while on THC. Six
of the IS patients had a "fair" response to THC, namely a > 30%
but < 80% reduction of at least three study variables. All four
inexperienced marijuana users were "excellent" responders to THC.
Using the method of Koch (15)
to analyze the first two trials, THC was found to be of statistically
significant benefit for the number of vomiting and retching episodes (p <
0.02), degree of nausea (p < 0.01), duration of nausea (p <
0.01), and volume of emesis (p < 0.01). The difference for volume of
oral intake approached, but did not achieve, statistical significance. For none
of these variables was there any indication that response to THC and placebo
changed uniformly between the first and second trials. For the degree of nausea
score, however, the relative efficacy of THC did significantly differ depending
upon the order of administration (p < 0.05). The relative efficacy of
THC in reducing the degree of nausea score was greater for Trial I than for
Trial 2. For Trial 1 alone, THC was significantly better than placebo with
regard to degree of nausea (p < 0.01). However, for Trial 2 the
difference was not statistically significant. The results of the other two
statistical tests applied were very similar to each other. With either of these
tests THC was significantly better than placebo with regard to number of
episodes of vomiting and retching, degree of nausea, duration of nausea, and
volume of emesis (p < 0.001). With both tests, the differences in
volume of oral intake between THC and placebo did not approach statistical
significance.
Plasma concentrations from
18 THC trials along with the paired placebo trials were analyzed in 14
patients. To examine plasma concentrations each trial was divided into five 3-h
time intervals beginning at each drug administration. Table 2 summarizes the
plasma concentration determinations after oral and smoked THC doses. In placebo
trials, where the plasma concentrations were 0 ng/ mL, patients experienced
nausea or vomiting, or both, in 65 of 90 time intervals, an incidence of 72%.
On THC trials, plasma concentrations of < 5.0 ng/mL, 5.0 to 10.0
ng/mL, and > 10.0 ng/mL were associated with incidences of nausea or
vomiting, or both, of 44%, 21%, and 6%, respectively. The incidence of
nausea and vomiting decreased with elevation of THC plasma concentrations.
It might be argued that the association of THC plasma concentrations to the
incidence of nausea and vomiting is not causally related to an antiemetic
effect of THC, but rather due to increased absorption of oral doses by the
gastrointestinal tract in patients experiencing less nausea and vomiting from
other causes. To address this issue, we examined plasma concentrations measured
after smoked THC and placebo doses. Patients who vomited during the course of a
trial were requested to smoke their remaining doses. The incidence of nausea
and vomiting after the administration of placebo cigarettes was 96%. Smoked THC
cigarettes resulting in plasma concentrations of < 5.0, 5.0 to 10.0 and
> 10.0 ng/mL were associated with incidences of nausea and vomiting
of 83%, 38%, and 0%, respectively. All of the patients who smoked their THC
doses were experienced cigarette smokers. We concluded that elevations of
THC plasma concentrations, achieved primarily by the inhalation route, also
resulted in a reduced incidence of nausea and vomiting.
Delta-9-Tetrahydrocannabinol (THC) Plasma
Concentrations Compared to Incidence of Nausea and Vomiting
Table 2.
|
THC Concentration § |
Time Intervals © |
Time intervals with Nausea and Vomiting Present |
Incidence of Nausea and Vomiting |
|
nanograms per milliliter |
number |
number |
percentage (%) |
|
0 ª |
90 |
65 |
72 |
|
< 5.0 |
43 |
19 |
41 |
|
5.0 - 10.0 |
29 |
6 |
21 |
|
> 10 |
18 |
1 |
6 |
|
§ Maximum THC concentration measured within 3 hours after each oral or smoked drug administration for 18 THC trials. |
|||
|
© Three-hour time interval after each drug administration. |
|||
|
ª Eighteen paired placebo trials. |
|||
Table 3. Oral Versus Delta-9-Tetrahydrocannabinol (THC)
Absorption
|
Dose Schedule |
THC Blood Concentration © |
|
|
Oral Doses (Number) |
Smoked Doses (Number) |
|
|
hour of day |
nanograms per milliliter |
nanograms per milliliter |
|
0700 |
7.1 ± 6.9 ª (18) |
None |
|
1000 |
6.4 ± 5.5 (15) |
7.8 (2) |
|
1300 |
4.3 ± 4.5 (15) |
7.5 ± 1.8 (3) |
|
1600 |
4.7 ± 6.2 (12) |
7.1 ± 5.8 (6) |
|
1900 |
4.5 ± 2.4 (10) |
4.2 ± 3.5 (6) |
|
© DeIta-9-tetrahydrocannabinol concentration measured 1 hr after administration of dose. |
||
|
ª Mean ± 1 standard deviation |
||
Despite a constant dose of
THC given for each drug administration, absorption via the oral and inhalation
routes was not uniform between patients or for individual patients. Thirty-one of
70 (44%) oral doses resulted in TI-IC plasma concentrations > 5.0 ng/mL
I h after administration, with a range of 0 to 26.6 ng/mL. Table 3 lists the
mean plasma concentrations achieved 1 h after oral and smoked doses from 18 THC
trials. Oral absorption was greatest for the first two doses, with mean 1 h
plasma concentrations of 7.1 and 6.4 ng/mL. Subsequent oral doses resulted in
mean 1 h plasma concentrations of 4.3, 4.7, and 4.5 ng/mL. Mean 3-h
plasma concentrations were consistently lower than mean 1 h values measured
after oral and smoked doses. Variable absorption is suggested by the large
standard deviations associated with each of the mean plasma concentrations. The
inhalation route was more reliable in achieving adequate blood concentrations:
12 of 17 smoked doses resulted in plasma concentrations > 5 ng/mL 1 h after
smoking, with a range of 0 to 13.6 ng/mL. In three of four scheduled doses,
smoked THC resulted in greater mean plasma concentrations than did oral THC,
with values of 7.8, 7.5, 7.1 ng/mL. There was no evidence of plasma
accumulation of THC with repeated administration every 3 h.
Table 4. Subjective "High" Compared to Incidence
of Nausea and Vomiting §
|
"High" ©
|
Time Intervals ª |
Time Intervals with Nausea and Vomiting Present |
Incidence of Nausea and Vomiting |
|
number |
number |
% |
|
|
0 - I |
81 |
37 |
46 |
|
2 |
45 |
15 |
33 |
|
3 |
34 |
6 |
18 |
|
§ Thirty-two active trials. |
|||
|
© 0 = none; 1 = slightly; 2 = moderately; 3 = greatly |
|||
|
ª Three-hour lime intervals after each drug administration |
|||
Patients were asked to rate
the magnitude of their psychological "high" on a 0-3 scale: 0 = none;
I = slightly; 2 = moderately; 3 = greatly. Using time intervals similar
to those employed to analyze the plasma concentrations, the patients'
subjective "high" rating can be compared with the incidence of nausea
or vomiting, or both. Table 4 lists the comparative results of the subjective
"high" ratings with the incidence of nausea or vomiting, or both, in
all THC trials of Phase I. In those time intervals in which patients rated
their "highs" as 0 or I, the incidence of nausea or vomiting was 46%.
For "high" ratings of 2 and 3 the incidence of nausea or vomiting
decreased to 33% and 18%, respectively. Therefore, the greater magnitude of the
subjective "high" appeared to be associated with a decreased
incidence of nausea or vomiting.
The subjective rating of
comfort was recorded by each patient during each wakeful hour of the
observation period. The patient was asked to rate comfort by choosing the
following: very comfortable (2); somewhat comfortable (1); somewhat
uncomfortable (-- I); and very uncomfortable (-- 2). By summing
the numerical scores associated with each response and dividing by the total
number of responses, a mean comfort rating could be determined for all wakeful
hours on THC and placebo trials for each patient. Figure 1 shows the mean
comfort rating for all 15 patients on placebo and THC trials. All 14 patients
who had a reduction of nausea and vomiting on THC also had an increase in their
mean comfort rating. The one nonresponder patient had a decrease in comfort on
THC compared to placebo.
[Webmaster note: Figure 1
involves more than tables and would not accurately scan into the computer with
Textbridge Pro. The caption under Figure 1 states: Mean subjective comfort
rating of 15 patients on placebo versus delta-9-tetrahydrocannabinol (D -9-THC) trials. Each line represents one patient.
All patients who had a reduction in nausea and vomiting on THC also had an
increase in their mean comfort rating. The one nonresponder patient had a
decrease in comfort rating on THC compared to placebo. See page 823 in the
original article.]
SIDE EFFECTS
A common side effect of THC
was sedation. When reviewing the patients' subjective responses during all of
the trials, 12 of 15 patients rated themselves sleepier per hour on THC than on
placebo. Short-lasting episodes of tachycardia in the range of 100 to 120
beats/mm and dizziness associated with orthostatic changes were occasionally
noted. These episodes were well tolerated and required no specific medical
intervention. Five dysphoric reactions occurred out of a total of 281 THC drug
doses (2%). These reactions occurred in four patients, three of whom were
experienced marijuana users. The reactions manifested themselves as
short-lasting episodes (about 30 minutes) of anxiety (one patient),
disorientation (one), paranoia (one), and depression (two patients). No other
intervention besides reassurance of the patient was necessary to treat these
adverse reactions.
OTHER OBSERVATIONS
Four "excellent"
responders to THC have entered Phase II of the study. In contrast to Phase I,
all four patients had only "fair" responses to repeated THC trials.
Patient 4, for example, had almost complete elimination of nausea and vomiting
while on THC during Phase I (see Table 1). In Phase II this
patient completed an additional 12 trials (10 THC, two placebo) and had a 50%
reduction in nausea and vomiting as determined by comparison of the average
values of each study variable for the THC and placebo trials. Two patients
entered Phase II of the study as "fair" responders to THC. These
patients became nonresponders to THC despite an increased dose in accordance
with the study protocol.
Five patients with
resections of soft tissue sarcomas receiving monthly adjuvant doxorubicin and cyclophosphamide
chemotherapy were also studied. Doxorubicin and cyclophosphamide were given at
a constant dose of 70 and 700 mg/m2, respectively. These patients
were studied in the same manner as patients in Phase I who received high-dose
methotrexate. Three of the patients have been nonresponders to THC and two,
"fair" responders.
DISCUSSION
We have found that a
combination of oral and smoked THC is a highly effective antiemetic compared to
placebo in patients receiving high-dose methotrexate chemotherapy. This report
confirms and extends earlier observations reported by Sallan and associates
(7), who found oral THC to be an effective antiemetic in patients receiving
various chemotherapeutic agents (7). In addition, it appears that the
antiemetic effect of THC is associated with the THC plasma concentration after
oral and smoked doses. When compared with placebo, the incidence of nausea
and vomiting was reduced to one third when THC plasma concentrations of 5.0 to
10.0 ng/mL were measured and to one tenth with THC plasma concentrations >
10.0 ng/mL. Similarly, elevations of THC plasma concentrations achieved
primarily by the inhalation route were also associated with reductions in the
incidence of nausea and vomiting. These data pertain only to patients receiving
high-dose methotrexate at a dose of 250 mg/kg. Preliminary data indicate that
the antiemetic effect of THC in patients receiving a combination of doxorubicin
and cyclophosphamide may be less effective.
In our patients, as has
previously been reported, oral doses administration of THC was associated with
variable absorption from the gastrointestinal tract (16). Oral doses administered
throughout the day resulted in a wide range of plasma concentrations between
patients as well as for individual patients. Only 44% of the oral doses
achieved plasma concentration > 5.0 ng/mL 1 h after drug
administrations. Sallan and co-workers (7) considered inadequate drug
absorption as a possible contributing factor to the lack of an antiemetic
response seen in some patients. We concur, since THC plasma concentrations
appeared to be causally related to an antiemetic response in our study. To
avoid this problem, we switched patients to the inhalation route of drug
administration when vomiting occurred. Inhaled marijuana results in the same
psychological effects as orally administered THC (17). In our patient
populations, smoked THC was more reliable than oral THC in achieving
therapeutic blood concentrations. About 71% of the inhaled doses of THC
resulted in plasma concentrations > 5.0 ng/mL I h after drug
administration. Since all of our patients who smoked THC were experienced
cigarette smokers, we could not determine whether nonsmokers would have
absorbed inhaled doses differently. Although the inhalation method of THC
administration avoids the ineffective route of oral drug administration in a
nauseated or vomiting patient, it has some drawbacks in patient acceptability.
Many patients complained of the adverse taste of smoked marijuana, which
induced nausea and vomiting in a few instances. Also, patients who are
nonsmokers may not be willing or able to smoke THC. Clearly, an alternative
parenteral drug route needs to be established if THC is to have wide clinical
acceptability.
In Phase II there was
diminished effectiveness of THC as an antiemetic with repeated drug trials.
Some reduction in THC effectiveness may be attributable to the normal variation
of nausea and vomiting responses in a patient observed for multiple courses and
to the fact that only THC responders were studied in Phase II. The very minimal
course-to-course variation observed in Phase I for "excellent"
responders would not, however, seem to account entirely for the reduced
responses. McMillan and colleagues (18) have demonstrated in animals that
infrequent doses of THC can result in tolerance, and this may account for our
observations. Another possible factor is the development of anticipatory or
conditioned nausea arid vomiting, which commonly occurs in patients receiving
repeated courses of chemotherapy. Such patients, when exposed to
treatment-related stimuli, become nauseated even before chemotherapy. The
presence of anticipatory nausea or vomiting may make a patient more refractory
to an antiemetic. Three of the six patients in Phase II developed these
anticipatory responses as determined by questionnaires completed by every
patient the day before each chemotherapy session. Our study was not designed to
assess the ability of THC to prevent or reduce anticipatory nausea or vomiting.
The sedative effect of THC
was documented in 80% of our patients. Sedation has been reported to be the
commonest side effect of phenothiazine antiemetics as well (19). Moertel and
Reitemeier (4) examined this side effect when comparing various phenothiazines
as antiemetics. In their study, a sodium pentobarbital control was not any
different from an inert placebo control in relieving nausea and vomiting
induced by fluoruracil. Although the mechanism of THC's antiemetic effect is
unknown, it would be unlikely to be due solely to its sedative properties.
Appetite stimulation has
been reported after the smoking of marijuana (20, 21). To assess appetite, oral
intake during each drug trial was measured. Oral intake on THC trials did not
differ from that on placebo trials. The concomitant infusion of a
chemotherapeutic drug may have precluded any appetite-enhancing actions of THC
in our patient population.
Nabilone, a synthetic
cannabinoid with minimal euphoriant effects capable of being administered
parenterally, has been reported to have antiemetic properties in patients
receiving chemotherapy (8, 9, 11). Unfortunately, additional data have
indicated long-term animal toxicity that may preclude its clinical usefulness
(11). At present, no available agents exist to substantially alleviate the
nausea and vomiting associated with chemotherapy. Our data show that oral or
smoked THC is an effective antiemetic in patients receiving high-dose
methotrexate chemotherapy. The antiemetic action appears to be related to THC
plasma concentrations as well as to the patient's psychological
"high." A dose schedule of 10 mg/in2 every 3 h for a total
of five doses was associated with substantial therapeutic benefit and minimal
toxicity.
Additional studies relating
to THC drug tolerance, effectiveness against nausea and vomiting produced by
other chemotherapy regimens, and comparisons with conventional antiemetics need
to be done.
ACKNOWLEDGMENTS The authors thank the nursing staff
of the National Institutes of Health Clinical Center 10 East ward for carefully
collecting the clinical data; and Dr. Roger Foltz and Mr. Bruce Hidy for doing
the delta-9-tetrahydrocannibinol plasma determinations.
Requests For reprints
should be addressed to Alfred E. Chang, M.D.; Surgery Branch, National Cancer
Institute, Building 10, Room 10N116; Bethesda, MD 20205.
Received 4 May 1979,
revision accepted 29 August 1979.
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December 1979 · Annals of Internal Medicine · Volume 91 ·
Number 6
[Webmaster's Note: Emphasis
added. Please note the more reliable blood levels with the inhaled route and
the strong correlation between blood levels and the anti-nausea effect.]
Webmaster: Rick Bayer, MD
Board Certified, American
Board of Internal Medicine