1Departamento de Biociencias, Facultad de Veterinaria, Universidad de la República, Montevideo, Uruguay; 2Instituto Nacional de las Mujeres, Ministerio 
de Desarrollo Social, Montevideo, Uruguay; 3Instituto de Investigación Médica M. y M. Ferreyra (INIMEC-CONICET-Universidad Nacional de Córdoba) 
and Facultad de Psicología, Universidad Nacional de Córdoba, Córdoba, Argentina
*Corresponding Author’s e-mail: paulruiz@fvet.edu.uy

Change in Psychoactive Substance Consumption 
in Relation to Psychological Distress During the 

COVID-19 Pandemic in Uruguay

*Paul Ruiz,1 Florencia Semblat,2 Ricardo M. Pautassi3

Sultan Qaboos University Med J, May 2022, Vol. 22, Iss. 2, pp. 198–205, Epub. 26 May 22
Submitted 9 Dec 20
Revisions Req. 27 Jan & 5 Apr 21;  Revisions Recd. 15 Mar & 13 Apr 21
Accepted 16 May 21

This work is licensed under a Creative Commons Attribution-NoDerivatives 4.0 International License.

https://doi.org/10.18295/squmj.5.2021.106

CLINICAL & BASIC RESEARCH

abstract: Objectives: This study aimed to analyse how the health crisis associated with the COVID-19 pandemic 
affected psychoactive substance consumption in Uruguay. Methods: An online survey was answered by 1,916 
Uruguayan citizens between March and April 2020 regarding psychoactive substance use before and after the 
instauration of a recommended quarantine, increases in frequency and volume of use (during the quarantine) of the 
psychoactive substance they reported as having consumed the most in the year prior to the quarantine and psychological 
distress experienced during the last month. Results: The main substances consumed during the quarantine were 
alcohol, tobacco, marijuana and psychopharmaceuticals. Approximately 28% of respondents increased the volume 
(and 17.7%, the frequency) of use of the substance they had consumed the most the year before the instauration of the 
quarantine. Moreover, 5.7% initiated the consumption of a new psychoactive substance during the quarantine, mostly 
marijuana and psychopharmaceuticals. Psychological distress was significantly higher among women, participants 
under 30 and among those that increased the volume of their most or second preferred psychoactive substance. The 
group reporting an increase in the volume of use exhibited greater psychological distress. Conclusion: These results 
indicate an association between the instauration of the recommended quarantine in Uruguay and greater psychoactive 
substance use during the period as well as an association between increased psychoactive substance use during this 
period and levels of psychological stress. These results are relevant in terms of public health and policies. 

Keywords: COVID-19; Substance Use; Psychological Distress; Alcohol Abuse; Marijuana Use; Quarantine; Uruguay.

Advances in Knowledge
- Certain precautionary measures taken for COVID-19 such as quarantine can affect substance use.
- The psychoactive substances that showed a greater increase in consumption during the early phase of the COVID-related quarantine in 

Uruguay were alcohol, tobacco, marijuana and psychopharmaceuticals.
- An association was found between an increase in substance use and the levels of psychological distress.
- It is likely that the reported increase in the use of these substances indicates self-medicating behaviour, aimed at overcoming symptoms 

of anxiety and stress experienced during the pandemic. 

Application to Patient Care
- Psychological discomfort was greater in women and those under 30 years of age.
- Women were more likely to have increased their tobacco and psychopharmaceuticals use.
- Men were more likely to increase their marijuana and cocaine use.

Uruguay has endured several epidemics (the scarlet fever in 1836, yellow fever in 1857 and cholera in 1868) and pandemics (the flu 
in 1918); yet, research on how those events affected 
mental health is not available.1,2 The first positive 
cases of COVID-19, the disease induced by a novel 
coronavirus referred to as severe acute respiratory 
syndrome coronavirus 2 (SARS-CoV-2), were detected 
in late 2019 in Wuhan, China, although it emerged in 
Uruguay in March 2020. By mid-March, four cases had 
been detected in Uruguay and the disease had spread 
to several Latin-American countries, prompting the 
Uruguayan government to enforce a country-wide 
health emergency. The government established health 
and safety measures such as home quarantine and 

recommended non-mandatory closure of educational 
centres and public events and restriction of social 
gatherings.

Viral outbreaks, such as the one linked to SARS in 
China in the early 2000s, exert significant consequences 
on mental health. Wu et al. found that health workers 
who submitted to mandatory quarantine during the 
SARS outbreak exhibited significantly more symptoms 
of alcohol use disorders three years later than those 
who had not experienced quarantine.3 Bai et al. 
described stress-related symptoms in health workers 
from Taiwan, who underwent quarantine during the 
outbreak.4 Similarly, Hawryluck et al. studied a sample 
of Canadians exposed to quarantine measures and 
reported symptoms of posttraumatic stress disorder 

https://creativecommons.org/licenses/by-nd/4.0/


Paul Ruiz, Florencia Semblat and Ricardo M. Pautassi

Clinical and Basic Research | 199

(PTSD) and depression in 28.9% and 31.2% of the 
sample, respectively.5 Interestingly, there was a positive 
association between the length of the quarantine and 
the prevalence of PTSD symptoms.

The assessment of the effects of COVID-19 on 
mental health is still ongoing, although preliminary 
data indicate an increase in stress, anxiety, insomnia, 
depression and fear across the globe.6,7 A study 
conducted in Russia reported an increase in 
somatisation, phobias and sleep disorder symptoms 
since the beginning of the COVID-19 pandemic.8 
Moreover, a survey conducted in Italy on 2,291 
participants showed an increase in anxiety disorders 
(32.1%) and PTSD (7.6%) compared to the period 
before the COVID-19 outbreak.9 Similarly, a survey 
on 7,236 Chinese people revealed a high prevalence of 
symptoms of generalised anxiety (35.1%), depression 
(20.1%) and sleep disorders (18.2%), which mainly 
affected those ≤35 years old.10

Information focused on the use of substances 
during the pandemic is still scarce; however, research 
conducted in India shows that 25% of the sampled 
participants exhibited symptoms of severe depression, 
anxiety (28.0%) or stress (11.6%) and these scores 
were associated with problematic alcohol drinking.11 
Australia reported an increase in the frequency 
of alcohol consumption during the COVID-19 
pandemic, which was in-turn associated with high 
levels of psychological distress.12 In some cases, the 
abrupt disruption of access to the substances was 
associated with severe complications. For instance, 
India reported a significant increase in hospital 
emergencies for treating alcohol abstinence, which 
was associated with a peak in suicide reports.13,14 In 
the USA, Friedman et al. documented an increment 
of overdose-related cardiac arrests during the 
COVID-19 pandemic, as registered by emergency 
medical services.15 Reinstadler et al. showed that 
during the initial lockdown in response to the onset 
of the pandemic in Austria, caffeine and cannabis use 
increased, amphetamine and methamphetamine use 
decreased and methylenedioxymethamphetamine use 
showed no significant changes.16 Moreover, the Global 
Drug Survey reported that cannabis and alcohol were 
the most consumed psychoactive substances during 
the COVID-19 pandemic.17

In South America, a recent study has shown 
that the quarantine imposed in Argentina to 
mitigate the spread of COVID-19 was associated 
with temporal displacement of alcohol consumption 
(i.e. consumption during the weekend shifted to 
weekdays) as well as an increase in marijuana use 
among those who already consumed it before the 
pandemic.18 Overall, these results are consistent with 

McKay’s hypothesis, which postulates an increase in 
psychoactive substance use during the COVID-19 
pandemic due to overstimulation of interoceptive 
awareness and arousal as well as an increase in 
anxiety.19 These changes promote the consumption and 
potential abuse of psychoactive substances in general; 
however a specific increase in alcohol and marijuana 
use has been reported due to their rewarding and anti-
anxiety effects.

Notably, the market for addictive substances 
has been impacted during the pandemic as well.20,21 
In Uruguay, where the current research took place, 
press releases have suggested a significant (~30%) 
increase in the sale of wines; however, there is a dearth 
of scientific data on these issues. Nonetheless, it is 
known that marijuana and alcohol rank among the 
most consumed psychoactive substances in Uruguay. 
Specifically, a recent nation-wide study revealed that 
among Uruguayans aged 15–65 years, alcohol (52%) 
and tobacco (33%) were the substances with the highest 
level of habitual consumption (i.e. in the last 30 days), 
although lifetime prevalence of psychopharmaceuticals 
(27.2%), marijuana (23.3%) and cocaine (6.8%) use was 
also elevated.22 The general aim of the present study 
was to assess the potential impact of the COVID-19 
pandemic on the use of psychoactive substances in 
Uruguay. Specifically, the study investigated changes 
in frequency and quantity of such use over the period 
before and during the recommended quarantine and 
assessed factors (e.g. psychological stress) associated 
with heightened psychoactive substance use during 
and prior to the recommended quarantine. The 
differences in the occurrence of psychological stress as 
a function of age and gender were also analysed. These 
are factors that, in prior research, proved relevant in 
modulating psychological stress or to be involved in 
psychoactive substance self-administration.18,23

Methods

This cross-sectional study included Uruguayan 
citizens aged at least 18 years. An online survey 
was conducted from 26 March (13 days after the 
recommended quarantine commenced) to 5 April 
2020. The instruments used were compiled in an online 
questionnaire created using Google Forms. The link 
to the survey was distributed through email listings 
and academic and social networks such as Facebook 
(Facebook Inc., Menlo Park, California, USA), 
Instagram (Instragram Inc. Menlo Park, California, 
USA), Twitter (Twitter Inc., San Francisco, California, 
USA) and WhatsApp (WhatsApp Inc., Menlo Park, 
California, USA), among others. Thus, the sample was 
collected using convenience sampling. The invitation 



Change in Psychoactive Substance Consumption in Relation to Psychological Distress During the COVID-19 Pandemic in Uruguay

200 | SQU Medical Journal, May 2022, Volume 22, Issue 2

emphasised the anonymity and academic nature of the 
study and contained a link. Clicking the link redirected 
prospective participants to an active consent form, 
which led to the survey upon completion. There 
was no compensation for participating in the study. 
The inclusion criteria were being 18 years old or 
older, residing in Uruguay and having consumed a 
psychoactive substance during the year before the 
recommended quarantine.

Several questions were asked about biological 
gender, age, place of residence (Uruguay is divided 
into 19 departments), type of isolation during the 
recommended quarantine (total: leaving the household 
only for essentials; partial: leaving the household 
less frequently than usual), number of days spent in 
quarantine at the time of assessment, usual number of 
hours spent isolated/quarantined at home each day, 
employment status and, among those who reported 
working, weekly working hours. 

Based on the study by Pilatti et al., participants 
were asked about their use of psychoactive drugs 
during the 12-month period prior to the beginning of 
the recommended quarantine.18 Participants chose among 
nine pre-set options—alcohol, marijuana, tobacco, cocaine, 
hallucinogens, ectasis, stimulants, ‘pasta’ (an inter- 
mediate substance that is obtained during the manufac- 
turing of cocaine hydrochloride and is somewhat popular 
in Uruguay) or psychopharmaceutical substances 
without medical prescription such as benzodiazepines 
and an ‘other’ option. Participants could answer ‘yes’ 
to several of those options. They were then asked 
which of those substances they had used the most 
during the last year. With respect to that psychoactive 
substance (i.e. their individually preferred or ‘first-
choice’ drug), they were asked about the frequency 
of use in the 12 months before the recommended 
quarantine (providing 10 options, ranging from daily 
to just once in the year) and during the recommended 
quarantine. Following this, respondents were asked 
about their perception (yes/no) of heightened quantity 
of consumption (i.e. during the quarantine with 
respect to the year prior to the quarantine) of the 
psychoactive substance they had reported to use the 
most during the last year. In more detail, the specific 
question was ‘With regard to the drug that you used 
the most during the last year, did you notice that 
the volume of consumption increased during the 
recommended quarantine compared to the previous 
year (i.e. if it was alcohol, did you drink more glasses or 
litres; if it was tobacco, did you smoke more cigarettes; 
if it was marijuana, did you use more joints, etc.)?’. The 
answers to the question on individually preferred or 
first-choice psychoactive substance (during the last 
year) given by the different participants were obviously 

dissimilar. Questions assessing the initiation of use 
of psychoactive substances during the quarantine 
(indicating that it had never been tried before) were 
also included.

Psychological distress was assessed via the 
Kessler scale. This scale has 10 items in a five point 
Likert-scale-type format. Scores ranged from 10 
to 50 (where higher values indicate higher levels of 
psychological distress) and provided information 
on unspecific psychological distress (anxiety or 
depression symptoms) suffered during the last 
month.24 A score under 20 indicates a normal level of 
psychological distress and those scoring 20–24, 25–29 
and 30 or more exhibit mild, moderate or severe levels 
of psychological distress, respectively.25 In this study, 
the reliability (calculated via Cronbach’s alpha) of the 
scores of the scale was adequate (α = 0.88) and similar 
to that reported in another study, in which the scale 
was applied to a different Uruguayan sample.23

All the data were analysed using Statistica 8.0 
(StatSoft Inc., Tulsa, USA). Descriptive analyses of 
variables measuring psychoactive substance use 
(i.e. type of drug), time spent in quarantine and 
psychological distress were conducted separately 
based on gender (male, female), area of residence 
(the capital Montevideo, rest of the country) and 
age (under or over 30 years). An analysis of variance 
(ANOVA) using age and gender as between-groups 
factors was conducted on Kessler scores. A one-way 
ANOVA analysed whether the levels of psychological 
distress differed as a function of frequency of drug 
use (daily drug use, weekly drug use, some days of the 
week or no drug use) during the quarantine. Separate 
ANOVAs analysed whether those who reported to 
begin the use of new drugs or increased the volume 
of their main or second drug of choice during the 
quarantine manifested significantly higher levels of 
psychological distress than those who did not report 
those behaviours. A type I error was set at 0.05. 

One of the purposes of the study was to find factors 
associated with heightened psychoactive substance 
use during and prior to the recommended quarantine. 
As indicated, each participant identified the substance 
they had used the most during the year before the 
quarantine (i.e. the ‘preferred’ psychoactive substance) 
and then answered if they had increased the volume 
of use of that substance during the recommended 
quarantine. A binary logistic regression model on this 
dichotomous outcome (yes/no, as asked concerning 
increased volume of use of the ‘preferred’ psychoactive 
substance during the quarantine) was conducted. 
Biological gender, age in years, type of quarantine 
(partial or total), region of residence (Montevideo or 
other departments), psychoactive substance of choice 



Paul Ruiz, Florencia Semblat and Ricardo M. Pautassi

Clinical and Basic Research | 201

(i.e. most used substance) during the year before the 
quarantine and absolute Kessler scores were variables 
used altogether to differentiate participants who had 
increased the volume of use from those who had not. 

A separate binary regression forecasted membership 
in the group that had showed a self-reported increase 
in the frequency of use of the preferred psychoactive 
substance using the predictor variables described 
above. For both logistic regressions and due to the 
low number of subjects exhibiting certain categories 
of response, the first-choice psychoactive substances 
were re-categorised as follows: tobacco (0, i.e. reference 
category against which odds ratios [ORs] for the other 
substance were computed), alcohol (1), marijuana (2) 
and others (3).

This study was designed and conducted in adherence 
to the indications of the Declaration of Helsinki. Privacy 
and data confidentiality were maintained throughout 
the process. A specific ethical agreement is not needed 
in Uruguay for the type of survey employed. 

Results

The survey was completed by 1,916 participants. 
A total of 53 cases were dismissed due to response 
inconsistencies; thus, the final sample was 1,863. 
Uruguay’s population (~3.5 million) has slightly 
more women (51.6%) than men, and close to 40% of 
the population lives in Montevideo. The country’s 
median age is 32.8 years.26 The sample consisted of 
approximately 66% women (mean age = 31.3 ± 0.3 
years; 72.7% resided in Montevideo) [Table 1].

Nearly 40% of the sample was in partial isolation 
(i.e. leaving the household less frequently than usual) 
at the time of the survey, whereas the remaining 61.4% 
was in total isolation (i.e. leaving the household only 
for buying essential goods or emergency essentials). 
At the time of the survey, participants had spent a 
mean of 13 ± 3.9 days in isolation. Slightly less than 
half of the sample (44%) exhibited normal distress 
scores, whereas 19.3%, 17.9% and 18.7% exhibited 
mild, moderate and high levels of distress, respectively 
[Tables 2 and 3]. 

Approximately, one third of the participants (30.3%) 
reported daily use of the psychoactive substance of 
choice during the quarantine, whereas 23.9% reported 
using psychoactive substances several days a week 
and 9.1% once a week. A portion (28%) of the sample 
reported having increased the volume of the psycho- 
active substance of choice during isolation and 17.7% 
reported an increase in the frequency of use. A minority 
(5.7%) reported having initiated the use of new psycho- 
active substances, mainly marijuana or psychopharma- 

ceuticals, during the quarantine [Table 3]. 
Prevalence of psychoactive substance use during 

the year before the quarantine was 89.7% (alcohol), 
55.8% (marijuana), 40.9% (tobacco), 20.8% (psycho- 
pharmaceuticals), 17.4% (hallucinogens), 14.1% (ecstasy), 
10.8% (cocaine), 4.7% (stimulants), 1.3% (ketamine) and 
0.4% (pasta). When asked about the most consumed 
psychoactive substance (i.e. the psychoactive substance 
of choice) during the past year, the majority indicated 
alcohol (54.7%), followed by tobacco and marijuana 
(19.2% and 16.7%, respectively), psychopharmaceuticals 
(6.9%) and cocaine (0.9%) [Table 4].

The ANOVA on Kessler total scores indicated 
significantly higher levels of psychological distress in 
those aged ≤30 (F1,1859 = 52.1; P <0.001) and in women 
(F1,1861 = 104.1; P <0.001). The interaction between 
age and gender was not significant. The levels of 
psychological distress were affected by the frequency 
of psychoactive substance use during the quarantine 
(F5,1397 = 5.2; P <0.001). Least significant difference 
post-hoc tests indicated that participants reporting 
daily psychoactive substance use during the quarantine 
exhibited significantly higher levels of psychological 
distress (22.89 ± 0.33) than those who reported using 
psychoactive substances on a weekly basis (21.02 ± 0.51) 
or only during some days of the week (21.4 ± 0.34; P 
<0.05). Similarly, those who used new psychoactive 
substances (F1,1850 = 38.5; P <0.001) or increased 
the volume of their preferred psychoactive substance 
(i.e. that substance used the most during the year 

Table 1: Gender-wise distribution of socio-demographic 
data of Uruguayan citizens including information regarding 
age, geographical area and type of isolation during the 
COVID-19 pandemic (N = 1,863)

Characteristic n (%)

Male 
(n = 636) 

Female 
(n = 1,227)

Age* in years

Mean 32.7 ± 0.4 31.3 ± 0.3

<30 290 (45.6) 697 (56.8)

>30 345 (54.3) 529 (43.1)

Geographic area

Montevideo 472 (74.2) 892 (72.7)

Rest of the country 164 (25.8) 335 (27.3)

Type of isolation 

Total† 349 (54.9) 795 (64.8)

Partial‡ 287 (45.1) 432 (35.2)

*Two participants did not provide their age in the survey.
†Total: leaving the household only for essentials.
‡Partial: leaving the household less frequently than usual.



Change in Psychoactive Substance Consumption in Relation to Psychological Distress During the COVID-19 Pandemic in Uruguay

202 | SQU Medical Journal, May 2022, Volume 22, Issue 2

Table 4: Frequency distribution of participants that selected a given psychoactive substance as their individually preferred 
or ‘first-choice’ drug during the year prior to the current survey among Uruguayan citizens (N = 1,863)

Characteristic Total n (%)

Alcohol Tobacco Marijuana Psychopharmaceuticals Cocaine *Other drugs

Gender

Male 636 345 (54.2) 102 (16.0) 146 (23.0) 23 (3.6) 10 (1.6) 10 (1.6)

Female 1,227 674 (54.9) 255 (20.8) 165 (13.4) 106 (8.6) 7 (0.6) 20 (1.6)

Geographic area

Montevideo 1,364 753 (55.2) 254 (18.6) 230 (16.9) 93 (6.8) 11 (0.8) 23 (1.7)

Rest of the 
country

499 266 (53.3) 103 (20.6) 81 (16.2) 36 (7.2) 6 (1.2) 7 (1.4)

Age group† in years

<30 987 547 (55.4) 158 (16.0) 207 (21.0) 53 (5.4) 6 (0.6) 16 (1.6)

>30 874 470 (53.8) 199 (22.8) 104 (11.9) 76 (8.7) 11 (1.3) 14 (1.6)

Type of isolation

Total‡ 1,144 630 (55.1) 217 (19.0) 187 (16.3) 85 (7.4) 7 (0.6) 18 (1.6)

Partial§ 719 389 (54.1) 140 (19.5) 124 (17.2) 44 (6.1) 10 (1.4) 12 (1.7)

*Drugs such as lysergic acid diethylamide, ecstasy, ketamine and others.
†Two participants did not provide their age in the survey.
‡Total: leaving the household only for essentials.
§Partial: leaving the household less frequently than usual.

Table 2: Socio-demographic data of Uruguayan citizens 
including information regarding participants’ employment 
hours and isolation during COVID-19 (N = 1,863)

Characteristic Mean ± SD

Number 
of days 

in 
isolation

Number 
of hours 
a day in 
isolation

Number 
of working 
hours per 

week

Gender

Male 12.9 ± 0.2 19 ± 0.2 25.9 ± 0.8

Female 13 ± 0.1 19 ± 0.2 21 ± 0.5

Geographic area

Montevideo 12.9 ± 0.1 19.1 ± 0.2 24.3 ± 0.5

Rest of the 
country

13.2 ± 0.2 18.7 ± 0.2 18.3 ± 0.8

Age group in years

<30 12.9 ± 0.1 19.2 ± 0.2 17.9 ± 0.6

>30 13.1 ± 0.1 18.7 ± 0.2 28.1 ± 0.6

Type of isolation

Total* 13.2 ± 0.1 20.4 ± 0.2 20.7 ± 0.6

Partial† 12.7 ± 0.1 16.8 ± 0.2 25.8 ± 0.7

SD = standard deviation.
*Total: leaving the household only for essentials.
†Partial: leaving the household less frequently than usual.

Table 3: Self-reported initiation of a new drug use during 
the recommended quarantine and psychological distress 
scores (based on the Kessler psychological distress scale) 
as a function of gender, geographic area, age group and 
type of isolation during COVID-19 among Uruguayan 
citizens (N = 1,863)

Characteristic Total Initiation of 
a new drug

Psychological 
distress

n (%) Mean ± SD

Gender

Male 636 33 (5.2) 19.4 ± 0.2

Female 1,227 73 (6.0) 23 ± 0.2

Geographic Area

Montevideo 1,364 84 (6.2) 21.9 ± 0.2

Rest of the 
country

499 22 (4.4) 21.5 ± 0.3

Age group* in years

<30 987 62 (6.3) 22.9 ± 0.2

>30 874 44 (5.0) 20.5 ± 0.2

Type of isolation

Total† 1,144 55 (4.8) 21.8 ± 0.2

Partial‡ 719 51 (7.1) 21.7 ± 0.2

SD = standard deviation.
*Two participants did not provide their age in the survey;  †Total: 
leaving the household only for essentials;  ‡Partial: leaving the 
household less frequently than usual. 



Paul Ruiz, Florencia Semblat and Ricardo M. Pautassi

Clinical and Basic Research | 203

before the quarantine; F1,1872 = 44.2; P <0.001) or 
the volume but not the frequency of their second 
most preferred psychoactive substance (F1,1247 = 
9.5; P <0.01), manifested significantly higher levels of 
psychological distress than those who did not report 
those behaviours.

The logistic regression model was statistically 
significant (χ2 = 162.05; P <0.001). The model 
(Nagelkerke’s R2) explained 12% of the variance and 
the Hosmer–Lemeshow test was not significant (χ2 = 
4.25; P >0.80), corroborating the good fit. Overall, the 
correct classification of cases was 72.4%, although the 
sensitivity of the model was low. Specifically, sensitivity 
and specificity were 16.1% and 94.7%, respectively. In 
other words, the model’s ability to correctly forecast 
membership in the group that reported increased 
volume of the preferred psychoactive substance (i.e. 
that which was used the most during the year before 
the quarantine) was rather low. Only two factors 
achieved statistical significance: psychological distress 
and the preferred psychoactive substance. Higher 
distress scores were associated with a significantly 
higher probability of membership in the group that 
increased the volume of use of the substance of first 
choice (OR = 1.05; 95% confidence interval [CI]: 
1.03–1.06; P <0.001). Moreover, those who reported 
using alcohol (OR = 3.28, 95% CI: 2.15–5.00; P <0.001) 
or the ‘other’ category item (which included cocaine 
and psychopharmaceuticals [OR = 2.97, 95% CI: 
1.92–4.60; P <0.001]) as their drug of first choice were 
significantly more likely to be included in the group of 
increased volume of use than those using the reference 
category item (tobacco).

The model was statistically significant (χ2 = 63.56; 
P <0.001), but the amount of variance explained was 
very low (Nagelkerke’s R2= 0.06) and the Hosmer–
Lemeshow test was also significant (χ2 = 37.06; P 
<0.001). Altogether, it can be said that the model 
did not exhibit a good fit. This result was further 
corroborated by the positive and negative prediction 
values, which revealed the lack of proper classification 
(i.e. sensitivity and specificity were 0.0% and 100.0%, 
respectively). 

Discussion

This study presents relevant information on how the 
measures instituted to prevent the dissemination of the 
COVID-19 pandemic affected psychoactive substance 
use in Uruguay. The objective was to analyse differences 
in the occurrence of psychological stress in terms of 
factors such as age and gender that, in prior research, 
proved to be relevant in modulating psychological 
stress or involved in psychoactive substance self-

administration. Traditionally, men exhibit greater 
psychoactive substance use than women, although the 
latter progress more rapidly to problematic alcohol 
consumption than the former and psychological 
distress tends to be greater in women than in men.18,24,26 
Involvement in psychoactive substance use during the 
recommended home quarantine was also analysed 
and found to be associated with levels of psychological 
stress, among other variables. Previously, it was 
reported that psychological distress was associated 
with negative, alcohol-related consequences in 
Uruguayans aged 18–60 years.23

A sizable portion of the sample (18.7%) exhibited 
a high level of distress during the recommended 
quarantine. This report is troublesome, as prolonged 
exposure to psychological distress increases the 
likelihood of suffering from anxiety and depression. 
This finding implies that the health system in Uruguay, 
and likely across the region, will probably have to face 
the challenge of a second wave of COVID-19-related 
disabilities, involving alterations in mental health. 
Moreover, it was found that psychological distress was 
associated with an increase in the volume of use of 
the individual’s psychoactive substance of choice and 
that those who reported daily use of this psychoactive 
substance or began to use a new psychoactive 
substance during the quarantine, exhibited higher 
levels of psychological distress than those who did not. 
These findings are consistent with previous reports 
from Brazil and Uruguay, indicating an association 
between psychological distress and psychoactive 
substance consumption.27,28

A previous study from the same authors as the 
current study, conducted years before the COVID-19 
outbreak, also linked the level of psychological distress 
to alcohol-related consequences in Uruguayan youth.23 
In the current study, the authors also found that levels 
of psychological stress were significantly higher in 
women than in men.

Close to a quarter of the sample reported an 
increase in the quantity of their preferred psychoactive 
substance use during the recommended quarantine. 
Almost 20% of the sample showed an increase in the 
frequency of use of their preferred drug of choice and 
a sizable 30% exhibited daily psychoactive substance 
use. As was found in other countries, alcohol was 
the substance most used during the quarantine.29,30 
Alcohol and marijuana use are strongly driven by 
the need to reduce ongoing or anticipated negative 
effects related to psychological distress.31,32 Thus, 
it is likely that the reported increase in the use of 
these substances indicates self-medicating behaviour, 
aimed at overcoming symptoms of anxiety and stress. 
Consistent with this hypothesis, it was found that 



Change in Psychoactive Substance Consumption in Relation to Psychological Distress During the COVID-19 Pandemic in Uruguay

204 | SQU Medical Journal, May 2022, Volume 22, Issue 2

Kessler scores in those reporting daily psychoactive 
substance use during the quarantine were significantly 
higher than those observed in participants that 
consumed psychoactive substances either weekly 
or during some days of the week or that did not use 
psychoactive substances during the period. 

The results of the binary regression analyses were 
also consistent with the hypothesis that the increase 
in substance use during the recommended quarantine 
was driven by the need to reduce negative effects. 
Specifically, membership in the target group (i.e. 
participants who reported an increase in the volume 
of use of the preferred psychoactive substance) was 
associated with greater psychological distress scores. 
Notably, the likelihood of exhibiting such increase 
in volume was approximately three times higher in 
participants whose drug of first choice (during the 
year before the quarantine) was alcohol or drugs such 
as cocaine, psychopharmaceuticals or analgesics than 
in participants whose preferred drug was tobacco. 
The separate binary regression analysing factors 
associated with an increase in the frequency of use of 
the preferred psychoactive substance did not provide 
meaningful information. 

It should be noted, however, that the psychological 
distress scale used in the current study lacks validation 
in Uruguay, which detracts from the validity of these 
findings. Another limitation is that only two types 
of self-isolation (partial and total) were inquired 
about. Future studies should further dissect the type 
of experiences that define isolation in the context of 
COVID-19-related or other quarantines. 

Conclusion

This study presented the novel finding that during the 
first stage of the COVID-19 pandemic, psychological 
distress levels were relatively high in the Uruguayan 
population, particularly among women and those 
under 30 years of age. Moreover, 28.3% of the 
participants increased the volume of use of the 
psychoactive substance they had reported using the 
most in the year before the quarantine and 17.7% 
increased the frequency of such use. Those who 
reported such an increase in volume also reported 
higher levels of psychological distress than those who 
did not. These results indicate an association between 
the instauration of the recommended quarantine 
in Uruguay and greater psychoactive substance use 
during the period. The findings from this study are 
relevant in context of its implications in the creation 
of more robust public health policies that can cater 
to the well-being of this psychologically vulnerable 
population.

c o n f l i c t o f i n t e r e s t 
The authors declare no conflicts of interest. 

f u n d i n g 
No funding was received for this study.

a u t h o r s’ c o n t r i b u t i o n
PR and FS conceptualised the study. All authors were 
involved in project administration. PR and RMP 
contributed to the visualisation, while FS and RMP 
performed the investigation. All authors collected 
the data and RMP analysed the data. All authors 
were involved in drafting the manuscript. All authors 
approved the final version of the manuscript.

References
1. Burgues S. La pandemia de gripe en Uruguay (1918–1919). 

Americanía. Rev Eur Estud Latinoam 2017; 6:167–206.

2. Pollero R. Similitudes y diferencias entre las epidemias del pasado 
y la pandemia actual de COVID-19 en Uruguay. Claves. Rev 
Historia 2020; 6:317–26. https://doi.org/10.25032/crh.v6i10.17. 

3. Wu P, Liu X, Fang Y, Fan B, Fuller C, Guan Z, et al. Alcohol 
abuse/dependence symptoms among hospital employees 
exposed to a SARS outbreak. Alcohol Alcohol 2008; 43:706–12. 
https://doi.org/10.1093/alcalc/agn073. 

4. Bai Y, Lin C, Lin C, Chen J, Chue C, Chou P. Survey of stress 
reactions among health care workers involved with the 
SARS outbreak. Psychiatr Serv 2004; 55:1055–7. https://doi.
org/10.1176/appi.ps.55.9.1055. 

5. Hawryluck L, Gold W, Robinson S, Pogorski S, Galea S, Styra R. 
SARS control and psychological effects of quarantine, Toronto, 
Canada. Emerg Infect Dis 2004; 10:1206–12. https://doi.org/10.3 
201/eid1007.030703. 

6. Jiang X, Deng L, Zhu Y, Ji H, Tao L, Liu L, et al. Psychological crisis 
intervention during the outbreak period of new coronavirus 
pneumonia from experience in Shanghai. Psychiatr Res 2020; 
286:112903. https://doi.org/10.1016/j.psychres.2020.112903. 

7. Torales J, O’Higgins M, Castaldelli-Maia J, Ventriglio A. The 
outbreak of COVID-19 coronavirus and its impact on global 
mental health. Int J Soc Psychiatry 2020; 66:317–20. https://doi.
org/10.1177/0020764020915212. 

8. Enikolopov SN, Boyko OM, Medvedeva TI, Vorontsova OU, 
Kazmina OY. Dynamics of psychological reactions at the 
start of the pandemic of COVID-19. Psychol-Educ Stud 2020; 
12:108–26. https://doi.org/10.17759/psyedu.2020120207. 

9. Casagrande M, Favieri F, Tambelli R, Forte G. The enemy who sealed 
the world: Effects quarantine due to the COVID-19 on sleep 
quality, anxiety, and psychological distress in the Italian population. 
Sleep Med 2020; 75:12–20. https://doi.org/10.1016/j.sleep.2020. 
05.011. 

10. Huang Y, Zhao N. Generalized anxiety disorder, depressive 
symptoms, and sleep quality during the COVID-19 outbreak 
in China: A web-based cross-sectional survey. Psychiatry Res 
2020; 288:1–6. https://doi.org/10.1016/j.psychres.2020.112954. 

11. Verma S, Mishra A. Depression, anxiety, and stress and socio-
demographic correlates among the general Indian public during 
COVID-19. Int J Soc Psychiatry 2020; 66:756–62. https://doi.
org/10.1177/0020764020934508.

https://doi.org/10.25032/crh.v6i10.17
https://doi.org/10.1093/alcalc/agn073
https://doi.org/10.1176/appi.ps.55.9.1055
https://doi.org/10.1176/appi.ps.55.9.1055
https://doi.org/10.3201/eid1007.030703
https://doi.org/10.3201/eid1007.030703
https://doi.org/10.1016/j.psychres.2020.112903
https://doi.org/10.1177/0020764020915212
https://doi.org/10.1177/0020764020915212
https://doi.org/10.17759/psyedu.2020120207
https://doi.org/10.1016/j.sleep.2020.05.011
https://doi.org/10.1016/j.sleep.2020.05.011
https://doi.org/10.1016/j.psychres.2020.112954
https://doi.org/10.1177/0020764020934508
https://doi.org/10.1177/0020764020934508


Paul Ruiz, Florencia Semblat and Ricardo M. Pautassi

Clinical and Basic Research | 205

12. Biddle N, Edwards B, Gray M, Sollis K. Alcohol consumption during 
the COVID-19 period: May 2020. Centre for Social Research & 
Methods, Australian National University. From: https://csrm.
cass.anu.edu.au/research/publications/alcohol-consumption-
during-covid-19-period-may-2020  Accessed: Apr 2021.

13. Narasimha V, Shukla L, Mukherjee D, Menon J, Huddar S, Panda U, 
et al. Complicated alcohol withdrawal—An unintended conseq- 
uence of COVID-19 lockdown. Alcohol Alcohol 2020; 55:350–3. 
https://doi.org/10.1093/alcalc/agaa042. 

14. Ahmed S, Khaium M, Tazmeem F. COVID-19 lockdown in 
India triggers a rapid rise in suicides due to the alcohol withdrawal 
symptoms: Evidence from media reports. Int J Soc Psychiatry 
2020; 66:827–9. https://doi.org/10.1177/0020764020938809.

15. Friedman J, Beletsky L, Schriger D. Overdose-related cardiac 
arrests observed by emergency medical services during the 
US COVID-19 epidemic. JAMA Psychiatry 2021; 78:562–4. 
https://doi.org/10.1001/jamapsychiatry.2020.4218. 

16. Reinstadler V, Ausweger V, Grabher A, Kreidl M, Huber S, 
Grander J, et al. Monitoring drug consumption in Innsbruck 
during coronavirus disease 2019 (COVID-19) lockdown by 
wastewater analysis. Sci Total Environ 2021; 757:1–11. https://
doi.org/10.1016/j.scitotenv.2020.144006. 

17. Grebely J, Cerdá M, Rhodes T. COVID-19 and the health of 
people who use drugs: What is and what could be? Int J 
Drug Policy 2020; 83:1–10. https://doi.org/10.1016/j.drugpo.20 
20.102958. 

18. Pilatti A, Read J, Pautassi R. ELSA 2016 Cohort: Alcohol, tobacco, 
and marijuana use and their association with age of drug use 
onset, risk perception, and social norms in Argentinean college 
freshmen. Front Psychol 2017; 8:1452. https://doi.org/10.3389/
fpsyg.2017.01452.

19. McKay D. COVID-19 stress and substance use: Current issues 
and future preparations. J Anxiety Disord 2020; 74:102274. 
https://doi.org/10.1016/j.janxdis.2020.102274. 

20. Di Trana A, Carlier J, Berretta P, Zaami S, Ricci G. Consequences 
of COVID-19 lockdown on the misuse and marketing of addictive 
substances and new psychoactive substances. Front Psychiatry 
2020; 11:1–4. https://doi.org/10.3389/fpsyt.2020.584462.

21. European Monitoring Centre for Drugs and Drug Addiction 
(EMCDDA). Impact of COVID-19 on drug markets, drug 
use, drug-related harms and responses in south European 
Neighbourhood Policy countries. From: https://www.emcdda.
e uropa .e u/public ations/ad-ho c- public ation/impact-of-
covid-19-on-drug-markets-drug-use-drug-related-harms-
and-responses-in-south-european-neighbourhood-policy-
countries_en  Accessed: Apr 2021.

22. Junta Nacional de Drogas. VI Encuesta Nacional de Hogares 
sobre el Consumo de drogas. Informe de investigación. From: 
https ://w w w.gub.uy/junta-nacional-droga s/sites/junta-
nacional-drogas/files/2018-01/OUD_4ta_encuesta_drogas_
Uruguay_hogares_2006.pdf  Accessed: Apr 2021.

23. Ruiz P, Pilatti A, Pautassi R. Consequences of alcohol use, and its 
association with psychological distress, sensitivity to emotional 
contagion, and age of onset of alcohol use, in Uruguayan youth 
with or without a college degree. Alcohol 2020; 82:91–101. 
https://doi.org/10.1016/j.alcohol.2019.09.001. 

24. Kessler R, Andrews G, Colpe L, Hiripi E, Mroczek D, Normand S, 
et al. Short screening scales to monitor population prevalences 
and trends in non-specific psychological distress. Psychol Med 
2002; 32:959–76. https://doi.org/10.1017/s0033291702006074. 

25. Andrews G, Slade T. Interpreting scores on the Kessler 
Psychological Distress Scale (k10). Aust N Z J Public Health 
2001; 25:494–7. https://doi.org/10.1111/j.1467-842x.2001.tb00310.x. 

26. Randall C, Roberts J, Del Boca F, Carroll K, Connors G, Mattson M. 
Telescoping of landmark events associated with drinking: A 
gender comparison. J Stud Alcohol 1999; 60:252–60. https://
doi.org/10.15288/jsa.1999.60.252. 

27. Merchán-Hamann E, Leal E, Basso M, García E, Reid P, 
Kulakova O, et al. Comorbilidad entre abuso/dependencia de 
drogas y el distrés psicológico en siete países de Latinoamérica 
y uno del Caribe. Texto & Contexto—Enfermagem 2012; 
21:87–95. https://doi.org/10.1590/S0104-07072012000500012. 

28. Domenech D, Mann R, Strike C, Brands B, Khenti A. Estudio de 
la prevalencia de la comorbilidad entre el distrés psicológico y el 
abuso de drogas en usuarios del Portal Amarillo, Montevideo—
Uruguay. Texto & Contexto—Enfermagem 2012; 21:174–84. 
https://doi.org/10.1590/S0104-07072012000500022.

29. Stanton R, To Q, Khalesi S, Williams S, Alley S, Thwaite T, et al. 
Depression, anxiety, and stress during COVID-19: Associations 
with changes in physical activity, sleep, tobacco, and alcohol 
use in Australian adults. Int J Environ Res Public Health 2020; 
17:4065. https://doi.org/10.3390/ijerph17114065. 

30. Wardell J, Kempe T, Rapinda K, Single A, Bilevicius E, Frohlich J, 
et al. Drinking to cope during the COVID-19 pandemic: The 
role of external and internal stress-related factors in coping 
motive pathways to alcohol use, solitary drinking, and alcohol 
problems. Alcohol Clin Exp Res 2020; 44:2073–83. https://doi.
org/10.1111/acer.14425. 

31. Bravo A, Sotelo M, Pilatti A, Mezquita L, Read J. Depressive 
symptoms, ruminative thinking, marijuana use motives, and 
marijuana outcomes: A multiple mediation model among 
college students in five countries. Drug Alcohol Depend 2019; 
204:107558. https://doi.org/10.1016/j.drugalcdep.2019.107558. 

32. Leeies M, Pagura J, Sareen J, Bolton J. The use of alcohol and 
drugs to self-medicate symptoms of posttraumatic stress disorder. 
Depress Anxiety 2010; 27:731–6. https://doi.org/10.1002/da.20677.

https://doi.org/10.1093/alcalc/agaa042
https://doi.org/10.1177/0020764020938809
https://doi.org/10.1001/jamapsychiatry.2020.4218
https://doi.org/10.1016/j.scitotenv.2020.144006
https://doi.org/10.1016/j.scitotenv.2020.144006
https://doi.org/10.1016/j.drugpo.2020.102958
https://doi.org/10.1016/j.drugpo.2020.102958
https://doi.org/10.3389/fpsyg.2017.01452
https://doi.org/10.3389/fpsyg.2017.01452
https://doi.org/10.1016/j.janxdis.2020.102274
https://doi.org/10.3389/fpsyt.2020.584462
https://doi.org/10.1016/j.alcohol.2019.09.001
https://doi.org/10.1017/s0033291702006074
https://doi.org/10.1111/j.1467-842x.2001.tb00310.x
https://doi.org/10.15288/jsa.1999.60.252
https://doi.org/10.15288/jsa.1999.60.252
https://doi.org/10.1590/S0104-07072012000500012
https://doi.org/10.1590/S0104-07072012000500022
https://doi.org/10.3390/ijerph17114065
https://doi.org/10.1111/acer.14425
https://doi.org/10.1111/acer.14425
https://doi.org/10.1016/j.drugalcdep.2019.107558
https://doi.org/10.1002/da.20677