Archives of Academic Emergency Medicine. 2023; 11(1): e46

OR I G I N A L RE S E A RC H

Comparing Two Naloxone Tapering Methods in Manage-
ment of Methadone Intoxication; a Quasi-experimental
Study
Mohammad Javad Zarei1, Maral Ramezani2,3, Zahra Sahraie4, Shahin Shadnia5, Peyman Erfan Talab Evini5,
Babak Mostafazadeh5, Mitra Rahimi5∗

1. School of Medicine, Shahid Beheshti University of Medical Sciences, Tehran, Iran.

2. Department of Pharmacology, School of Medicine, Arak University of Medical Sciences, Arak, Iran.

3. Traditional and Complementary Medicine Research Center, Arak University of Medical Sciences, Arak, Iran.

4. Department of Clinical Pharmacy, Faculty of Pharmacy, Shahid Beheshti University of Medical Sciences, Tehran, Iran.

5. Toxicological Research Center, Excellence Center & Department of Clinical Toxicology, School of Medicine, Shahid Beheshti University of
Medical Sciences, Tehran, Iran.

Received: April 2023; Accepted: May 2023; Published online: 15 June 2023

Abstract: Introduction: Even though naloxone is the main treatment for methadone poisoning treatment there are controversies
about the proper method of its tapering. This study aimed to compare two methods in this regard. Methods: This
study was a prospective, single-blind pilot quasi-experimental study on non-addicted adult patients poisoned with
methadone. Patients were randomly divided into 2 groups. In one group, after stabilization of respiratory conditions
and consciousness, naloxone was tapered using the half-life of methadone and in the other group, naloxone was tapered
using the half-life of naloxone. Recurrence of symptoms and changes in venous blood gas parameters were compared
between groups as outcome. Results: 52 patients were included (51.92% female). 31 cases entered Group A (tapering
based on methadone’s half-life) and 21 cases entered Group B (tapering based on naloxone’s half-life). The two groups
were similar regarding mean age (p = 0.575), gender distribution (p = 0.535), the cause of methadone use (p = 0.599),
previous medical history (p = 0.529), previous methadone use (p = 0.654), drug use history (p = 0.444), and vital signs
on arrival to emergency department (p = 0.054). The cases of re-decreasing consciousness during tapering (52.38% vs.
25.81%; p = 0.049) and after discontinuation of naloxone (72.73% vs. 37.50%; p = 0.050) were higher in the tapering based
on naloxone half-life group. The relative risk reduction (RRR) for naloxone half-life group was -1.03 and for methadone
half-life group was 0.51. The absolute risk reduction (ARR) was 0.27 (95% confidence interval (CI) = 0.01-0.53) and the
number needed to treat (NNT) was 3.7 (95% CI= 1.87- 150.53). There was not any statistically significant difference be-
tween groups regarding pH, HCO3 , and PCO2 changes during tapering and after naloxone discontinuation (P > 0.05).
However, repeated measures analysis of variance (ANOVA), showed that in the tapering based on methadone’s half-life
group, the number of changes and stability in the normal range were better (p < 0.001). Conclusion: It seems that, by
tapering naloxone based on methadone’s half-life, not only blood acid-base disorders are treated, but they also remain
stable after discontinuation and the possibility of symptom recurrence is reduced.

Keywords: Naloxone; Methadone; Drug Users; Poisoning; Drug Tapering

Cite this article as: Zarei MJ, Ramezani M, Sahraie Z, Shadnia S, Talab Evini PE, Mostafazadeh B, Rahimi M. Comparing Two Naloxone

Tapering Methods in Management of Methadone Intoxication; a Quasi-experimental Study. Arch Acad Emerg Med. 2023; 11(1): e46.

https://doi.org/10.22037/aaem.v11i1.2047.

∗Corresponding Author: Mitra Rahimi; Toxicological Research Center, Excel-
lence Center & Department of Clinical Toxicology, Loghman Hakim Hospital,
Tehran, Iran. Email: mrahimi744@gmail.com, ORCID: https://orcid.org/0000-
0002-8785-8207.

1. Introduction

Methadone is a synthetic opioid substance that was devel-

oped in the 1940s as a pain reliever. This drug is the most

widely used treatment for opioid dependence and has been

used worldwide for more than 40 years under the name

methadone maintenance treatment (MMT)(1). Previous

studies have shown that MMT reduces the risk of crime, illicit

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MJ. Zarei et al. 2

drug use, morbidity, and mortality, and improves behaviors

in patients compared to opioid users (2-4). Methadone tox-

icity is rising among those accidentally exposed to it, which

results in increased mortality.

Methadone intoxication results in clinical manifestations

such as loss of consciousness, respiratory depression

(bradypnea/apnea), cardiovascular disturbances (hypoten-

sion, cardiac arrhythmia, and QT prolongation), nausea,

vomiting, seizures, and miosis. The duration of intoxication

with methadone is long compared to other opioid substances

(5-7).

The most widely used antidote in acute opioid poisoning

is the administration of naloxone(8-10). Pharmacologically,

naloxone is a pure opioid receptor antagonist. By a compet-

itive mechanism, it blocks the binding of opioid substances

to the receptor. After initiation, naloxone is tapered based

on the patient’s condition and subsequently discontinued.

If naloxone is administered in high doses or repeat doses

are administered too rapidly, naloxone can precipitate acute

opioid withdrawal syndrome. Signs of this syndrome in-

clude vomiting, tachycardia, shivering, sweating, and tremor

(11). Serious adverse effects can include pulmonary edema,

hypertensive emergencies, ventricular dysrhythmias, delir-

ium, seizures, and death (11-15). Even if an immediate, life-

threatening adverse event does not occur, patients with acute

opioid withdrawal are agitated and usually require sedative

drugs, putting them at risk for aspiration, and recurrent res-

piratory depression (11).

Despite the seriousness of methadone poisoning, there are

no specific recommendations in medical textbooks for how

to administer naloxone. Naloxone is accepted as a first-line

antidote, in some sources as a PRN (pro re nata) regimen, and

as a continuous intravenous infusion. The length of treat-

ment and its dosage is unknown. 12 to 18 hours, 0.25-6.25

mg/h up to 25 mcg/kg/h is recommended (16-18). On the

other hand, there is no discussion about how to taper nalox-

one after the patient’s condition is stable.

This is a dilemma in clinical toxicology. Trying to find a safer

method in this regard, this study aimed to compare tapering

based on naloxone half-life and based on methadone half-

life for treatment of methadone intoxicated patients in emer-

gency department.

2. Methods

2.1. Study design and setting

This study was a prospective, single-blind, and pilot quasi-

experimental study, which was conducted on non-addicted

patients poisoned with methadone who were referred to

Loghman Hakim Hospital, Tehran, Iran, during 2021-2022.

The study protocol was approved by the ethics committee

of Shahid Beheshti University of Medical Sciences with the

code IR.SBMU.RETECH.REC.1400.1038. Participants signed

informed written consent forms. This article was also regis-

tered in the Iranian Registry of Clinical Trials with number:

IRCT20220305054196N1.

2.2. Participants

Methadone-poisoned patients over 18 years of age, who pre-

sented with a reduced level of consciousness with or with-

out respiratory depression, didn’t have an addiction, and

were not under MMT treatment were included. Patients

with methadone poisoning with other hypnotic sedatives,

patients who were discharged against medical advice, and

patients who experienced withdrawal syndrome symptoms

after receiving naloxone or did not need naloxone were ex-

cluded from the study.

2.3. Data gathering

Methadone poisoning was confirmed by history and urine

drug tests. The patient’s addiction history was recorded

based on the information given by the patient or his/her

companions. Concomitant poisoning was diagnosed using

symptoms, history, and results of urine tests.

Upon arrival, vital signs (blood pressure, heart rate, breathing

rate, body temperature, level of consciousness, and percent-

age of oxygen saturation) were recorded and a blood sam-

ple was collected for venous blood gas (VBG) analysis. The

amount of methadone consumed was recorded. Then the

patients were treated with naloxone.

pH, PCO2 (Partial pressure of carbon dioxide), and HCO3 (Bi-

carbonate) concentrations were recorded before starting ta-

pering, during tapering, and after discontinuation of nalox-

one. The time of improvement of symptoms (Reaching the

percentage of oxygen saturation above 90%), return of con-

sciousness (patient being awake and aware of surroundings

and identity), and resolution of respiratory depression was

recorded. The final condition of the patient was checked.

The endpoint of tapering was the amount of naloxone ad-

ministered being less than 0.1 mg/hour and the stability of

the PCO2 level and the patient’s consciousness.

2.4. Intervention

Patients were allocated to the groups based on random num-

bers table. Patients were clinically evaluated without know-

ing which method was used for Naloxone tapering. In one

group, after the patient’s condition was stable, naloxone was

tapered using the half-life of naloxone (decreasing the dose

of naloxone by 50% every 3 hours), and in the other group,

naloxone was tapered using the half-life of methadone (de-

creasing the dose of administered Naloxone by 50% every

6 hours). After discontinuation of naloxone, patients were

monitored for 8 hours. Tapering methods were designed

based on the relative estimation of the half-life of naloxone

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3 Archives of Academic Emergency Medicine. 2023; 11(1): e46

and methadone, as well as the experiences of researchers in

clinical treatment.

2.5. Outcomes

Time to recovery, the re-decreasing consciousness, and

change in VBG parameters (pH, HCO3, and PCO2) during ta-

pering and after discontinue of naloxone were compared be-

tween groups as outcome.

2.6. Statistical analysis

Considering 95% confidence interval and alpha error of 5%,

the sample size was considered to be 50 cases. SPSS software

version 21 was used to analyze the information. The pop-

ulation normality was assessed using Kolmogorov-Smirnov

test, then independent and paired t-test were used for para-

metric data and chi-square for non-parametric data. P<0.05

was considered as the level of significance. Regression mod-

els were used for controlling confounding variables.

3. Results

3.1. Baseline characteristics of studied cases

52 patients were included, 27 (51.92%) were female and

25 (48.07%) were male. 31 cases entered Group A (taper-

ing based on the methadone half-life) and 21 cases entered

Group B (tapering based on the naloxone half-life). Most of

the patients (61.54%) had taken methadone due to suicide,

and had no history of illness and drug or methadone use. Six

people had a history of suicide attempts with methadone (4

people in group A and 2 people in group B).

Table 1 compares the baseline characteristics of studied pa-

tients between groups. The mean age of the patients was

28.68±10.9 years in group A, and 28.38±11.5 years in group

B (p = 0.575). There was no difference between the two

groups regarding gender distribution (p = 0.535), cause of

methadone use (p = 0.599), previous medical history (p =

0.529), previous methadone use (p = 0.654), drug use history

(p = 0.444), and vital signs on arrival to emergency depart-

ment (p = 0.045). None of the patients needed intubation.

Although all patients were candidates for admission to inten-

sive care unit (ICU), only 3 patients were treated in ICU. All

patients recovered and were discharged from the hospital.

3.2. Comparing the outcomes

Table 2 and figure 1 compare the studied outcomes between

the two groups. The cases of re-decreasing consciousness

during tapering (52.38% vs. 25.81%; p = 0.049) and after dis-

continue naloxone (72.73% vs. 37.50%; p = 0.050) were higher

in the tapering based on naloxone half-life group. The rel-

ative risk of re-decreasing of consciousness during tapering

was 0.49 and 2.03 in methadone half-life and naloxone half-

life groups, respectively. The relative risk reduction (RRR)

Figure 1: Comparing the pH, HCO3 , and PCO2 changes in the pa-

tients poisoned with methadone between the two groups of nalox-

one tapering based on methadone half-life and naloxone half-life.

was -1.03 for naloxone half-life group and 0.51for methadone

half-life group. The absolute risk reduction (ARR) was 0.27

(95% CI = 0.01-0.53) and the number needed to treat (NNT)

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MJ. Zarei et al. 4

Table 1: Comparing the baseline characteristics of studied cases between the two groups

Variable Tapering based on the half-life of P-value
Methadone (n = 31) Naloxone (n = 21)

Gender
Male 16 (51.6) 9 (42.9) 0.535
Female 15 (48.4) 12 (57.1)
Age (years)
Mean ± SD 28.7±11.0 28.4±11.5 0.575
Consumption due to suicide attempt
Yes 20 (64.5) 12 (57.1) 0.599
Medical history
Previous use of methadone 6 (19.3) 2 (9.5) 0.654
Previous disease 3 (9.7) 2 (9.5) 0.529
Drug use 6 (19.3) 4 (19.1) 0.444
Smoking 8 (25.8) 6 (28.6) 0.684
Alcohol consumption 1 (3.2) 0 (0.0)
Marijuana consumption 2 (6.4) 0 (0.0)
Taking psychotropic pills 2 (6.4) 1 (4.8)
Vital signs
Systolic BP (mmHg) 112.6±13.6 109.8±8.5 0.054
Diastolic BP (mmHg) 74.1±13.1 71±7.5 0.054
PR (Pulses/ minute) 90.93±16.5 80.11±22.06 0.65
RR (Breaths/ minute) 17.8±7.8 15.87±2.8 0.173
Glasgow coma scale 12.7±2.3 12.3±2.7 0.289
O2 saturation (%) 86.6±14.2 87±19.3 0.393
Treatment in ICU
Yes 1 (3.2) 2 (9.5) 0.339
Naloxone dose (mg)
Loading 1.97±1.4 1.28±0.7 0.067
Maintenance 1.07±0.64 0.81±0.37 0.073
VBG findings
Primary PH 7.26±0.09 7.27±0.09 0.558
Primary HCO3 23.87±5.7 25.84±3.6 0.187
Primary PCO2 (mmHg) 56.63±15.4 55.69±11.2 0.162
Data are presented as mean ± standard deviation (SD) or frequency (%). BP: blood pressure, ICU: intensive care unit,
PR: pulse rate, RR: respiratory rate, VBG: venous blood gas.

was 3.7 (95% CI= 1.87- 150.53).

There was not any statistically significant difference between

groups regarding pH, HCO3, and PCO2 changes during ta-

pering and after naloxone discontinuation (p > 0.05). How-

ever, repeated measures ANOVA, shows that in the tapering

with methadone half-life group, the number of changes and

stability in the normal range were better (p < 0.001).

4. Discussion

We found that although the recovery time of decreased con-

sciousness was not significantly different in the two meth-

ods, the return of central nervous system (CNS) depression

during dose reduction was significantly different. In patients

tapered based on half-live of naloxone, the number of cases

with re-decreasing CNS depression was higher than the other

group and this re-decreasing occurred most significantly in

time of discontinuing naloxone. The number of changes in

pH, HCO3 and PCO2 in the group tapering based on the

methadone half-life was better during dose reduction and af-

ter naloxone discontinuation.

Methadone is a synthetic opium that is used as a pain reliever

and in the maintenance treatment of addicted patients, and

its consumption is increasing (19). Accidental use or over-

dose of methadone can cause multiple organ damage in both

humans and animals (20-22). Methadone has significant tis-

sue distribution; tissue levels may exceed plasma levels. The

lipophilic nature of methadone allows for rapid absorption,

long duration of action, and slow release from tissues into the

bloodstream. This causes wide variations in the half-life, giv-

ing a range of 2 to 65 hours (23).

Opioid and methadone overdose syndrome is a true medical

emergency. Naloxone is mainly administered intravenously

at the same time as other supportive measures (24, 25).

Naloxone has a rapid onset of action, its maximum serum

concentration is reached 2 minutes after intravenous injec-

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5 Archives of Academic Emergency Medicine. 2023; 11(1): e46

Table 2: Comparing the outcomes of studied cases between groups

Outcomes Tapering based on the half-life of P-value
Methadone (n = 31) Naloxone (n = 21)

pH
During tapering 7.36±0.03 7.36±0.03 0.738
After discontinuing Naloxone 7.37±0.04 7.35±0.05 0.239
HCO3 (mmHg)
During tapering 26.47±3.6 27±3.4 0.684
After discontinuing Naloxone 27.28±4.9 28.35±2.8 0.050
PCO2 (mmHg)
During tapering 45.9±10.4 46.8±4.2 0.074
After discontinuing Naloxone 49.6±11.01 51.3±7.8 0.318
Re-decreased consciousness
During tapering 8 (25.81) 11 (52.38) 0.049
After discontinuing Naloxone 3 (37.5) 8 (72.73) 0.050
Time to recovery (day)
From respiratory depression 0.29±0.5 0.43±0.5 0.085
Final outcome
Recovery 31 (100.0) 21 (100.0) 0.596
Data are presented as mean ± standard deviation (SD) or frequency (%). The blood gas analysis is reported based on venous
sample.

tion, 10 minutes after intramuscular injection, and 15 to 30

minutes after intranasal administration (26). Naloxone is ex-

tensively metabolized in the liver, its serum half-life is about

30 to 90 minutes (27).

Although naloxone is relatively safe in naïve persons, it

should be used with caution in chronic methadone users

who experience overdose. High blood levels of naloxone can

trigger drug withdrawal symptoms in people who have previ-

ously been exposed to methadone. The onset of withdrawal

symptoms can increase an individual’s risk of relapse (28, 29).

We conducted this study on non-addicted subjects to cover

this major confounding factor and not have to discontinue

naloxone due to withdrawal syndrome.

Unfortunately, none of the studies have worked on the taper-

ing method. Given that naloxone has a much shorter half-

life than methadone (90 minutes vs. 65 hours), re-depression

of the CNS may occur due to the slow release of methadone

from the tissues into the blood after discontinuation of nalox-

one (23, 30). We observed that in the taper group based

on the half-life of naloxone, the cases of re-decreasing con-

sciousness were significantly higher (52.38%) and 72.73% of

them showed decreased consciousness after discontinuation

of naloxone. This could be due to the patient being naloxone-

free when there is still methadone in her/his body and it is

slowly released from the storage places and causes brain ef-

fects.

Dr. Yazdanbakhsh and his colleagues have conducted a study

on the comparison of two naloxone-based regimens in the

treatment of methadone overdose. They randomly divided

80 patients with methadone overdose into two groups: the

infusion and the PRN groups. The severity of deprivation

syndrome was evaluated after 30 minutes, 3 hours and 12

hours of treatment in both groups. Their results showed

that administering naloxone as PRN reduces the amount and

severity of withdrawal syndrome (31).

Dr. Khosravi et al. conducted a study, comparing two

naloxone regimens. 100 opioid-dependent patients with

signs/symptoms of methadone overdose were included in

the study. Patients were allocated to groups treated based

on Tintinalli protocol (group 1) or Goldfrank diet protocol

(group 2). Group 1 received naloxone at a dose of 0.1 mg ev-

ery two to three minutes, while group 2 received naloxone at

an initial dose of 0.04 mg, which was increased to 0.4, 2, and

10 mg every two to three minutes until respiratory depression

was reversed. They then compared them in terms of rever-

sal of toxicity and risk of complications. Finally, their results

showed that the gradual titration of naloxone with the Tinti-

nalli protocol can reduce major complications compared to

the Goldfrank regimen (32). Neither of the two studies dis-

cussed the issue of naloxone tapering.

It may seem that the gradual discontinuation of naloxone

based on the half-life of naloxone reduces the length of stay

in the hospital and the overall cost of the patient, but our re-

sults showed that firstly, there was no significant difference in

ICU admission, the initial dose of naloxone, and the mainte-

nance dose between the two groups. The risk of re-reducing

consciousness was higher in the group tapered based on the

half-life of naloxone.

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MJ. Zarei et al. 6

5. Limitations

The limitations of this study were the small number of pa-

tients in each group, the lack of equality of patients in the two

groups, the failure to examine the trend of all clinical factors

and symptoms in the two groups, and the lack of blinding of

the main investigators during the study.

6. Conclusion

It seems that, by tapering naloxone based on methadone’s

half-life, not only blood acid-base disorders are treated, but

they also remain stable after discontinuation and the possi-

bility of symptom recurrence is reduced.

7. Declarations

7.1. Acknowledgments

The authors would like to thank the Toxicological Research

Center (TRC) of Loghman Hakim Hospital, Shahid Beheshti

University of Medical Sciences, Tehran, Iran for their support,

cooperation, and assistance throughout the study. The re-

searchers also thank and appreciate the support of Professor

Latif Gachkar in the design and implementation of this re-

search.

7.2. Conflict of interest

We declare that we have no conflicts of interest.

7.3. Funding and support

Toxicological Research Center (TRC) of Loghman Hakim

Hospital, Shahid Beheshti University of Medical Sciences

7.4. Authors’ contribution

All authors made a significant contribution to the work re-

ported, whether in the conception, study design, execution,

acquisition of data, analysis and interpretation, or in all these

areas; took part in drafting, revising or critically reviewing

the article; gave final approval of the version to be published;

have agreed on the journal to which the article has been sub-

mitted; and agree to be accountable for all aspects of the

work.

7.5. Availability of data

The datasets used and/or analyzed during the current study

are available from the corresponding author on reasonable

request.

7.6. Using artificial intelligence chatbots

None.

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	Introduction
	Methods
	Results
	Discussion
	Limitations
	Conclusion
	Declarations
	References