This was an analytical cross-sectional study based on surveys applied to students from a private university in Lima, Peru. The surveys were carried out from 9 to 19 November 2018.

The target population was medical students from a health sciences faculty of a private Peruvian university. We surveyed all medical students from second to fourth year who met the inclusion criteria: being over 18 years old, enrolled in the cycle and present when the survey was applied.

As a census was conducted, a sample size calculation was not strictly necessary.

The exclusion criteria were refusal to give informed consent and an incomplete survey, i.e. those that did not include the outcome, gender or age.

HA was considered the primary dependent variable of the study, and was defined as the state of excessive, unrealistic and persistent worry about suffering from a disease in the last six months. The Short Health Anxiety Inventory (SHAI)5 was used to measure this variable and consists of 18 questions divided into two sections, with 14 questions in the main section and four in the negative consequences section. Each question has four options, scoring from 0 to 3 points, for a total score between 0 and 54 (from 0 to 42 for the main section and 0–12 for the negative consequences section). This instrument has versions validated in Spanish27,28 and for this study we used the version adapted and validated in a South American country (Vallejo-Medina P, 2018, unpublished). A confirmatory factor analysis was performed in Colombia and adequate construct validity was reported. Cronbach’s alpha index was used to estimate reliability, with a total scale reliability of 0.82 and good internal consistency.

To complete the analysis, HA was categorised. We used a threshold of 27 points or above in the SHAI to identify students who reported scores compatible with hypochondria. We chose this cut-off point because it provided the best balance between sensitivity and specificity.5

The covariates studied were: gender; year of studies (from second to sixth year); age in years; place of birth (Lima, the provinces or another country); smoking (regular smoker, occasional smoker, passive smoker or non-smoker); and history of first-degree relative doctor or healthcare worker.

The potential number of students who met the inclusion criteria for the survey was calculated. We then asked for authorisation to enter the classrooms five minutes before the end of classes in order to apply the surveys. Part of the time was spent reading the informed consent form, and they then went ahead with the survey. Students who did not give informed consent were excluded, and incomplete surveys were not entered into the database.

Once the data collection was completed, the data was double entered in MS Excel, each database was reviewed separately, and then the two databases were compared. After that the information was exported to the STATA 15.0 program for Windows (Stata Corp., United States) for the corresponding analysis. For univariate analysis, the median [interquartile range] was used for the quantitative variables age and SHAI score (total, main section and negative consequences). We also calculated the mean ± standard deviation of the SHAI scores. We used frequencies and percentages for the categorical variables gender, place of birth, year of studies, first-degree relative healthcare worker or doctor, and smoking.

For the bivariate analysis of HA levels, three statistical tests were used. The Mann–Whitney U test was used to cross-match the SHAI scores with gender and first-degree relative healthcare worker or doctor. The Kruskal–Wallis test was used to cross-match the SHAI scores with place of birth, year of studies and smoking, after which a post-hoc analysis was performed using the kwallis2 command in Stata. The Spearman correlation was used to cross-match the SHAI scores with age. Lastly, for the analysis of multiple variables, linear regression was used to calculate the betas and their 95% confidence intervals (95% CI). The crude model was calculated as part of the analysis, before adjusting the model for the other variables (using bivariate linear regression initially y = β0 +  β1 × 1). To select the variables to enter into the adjusted model, we used the epidemiological criterion, i.e. we took into account the sociodemographic variables and the relevant previous history, as reported by previous studies. Linear regression assumptions were tested through residual analysis. Collinearity was assessed using the variance inflation factor (VIF).

This study was approved by the ethics committee of the Universidad Peruana de Ciencias Aplicadas [Peruvian University of Applied Sciences]. In addition, the participants gave their informed consent after the purpose of the study and the type of questions they would be asked in the survey were explained to them. This study did not involve any risks for the respondents, as they were only required to complete a survey anonymously. Respondents freely chose to take part and were given the option to stop the survey if they felt it was necessary. After application of the survey, they were provided with pamphlets with information on the subject and contact numbers.

A total of 674 medical students (88.2% of the total potential surveys based on matriculations) met the inclusion criteria and completed the survey. We excluded 17 surveys from the analysis because one or more variables of interest were incomplete. In the end, 657 surveys were analysed (86.0% of the total potential surveys and 97.5% of the total number of students present in the classroom at the time of the survey), 26.2% from second-year students, 20.2% third-year, 28.5% fourth-year, 11.1% fifth-year and 14.0% sixth-year (Fig. 1).

Fig. 1.

Flow chart of the participants.

(0.16MB).

Of all the surveys analysed, 60.3% corresponded to female students. The median age of the participants was 21 [20–23] and more than half (63.8%) stated Lima as their place of birth (Table 1).

A majority 73.7% of the participants stated they did not have a first-degree relative doctor, and 43.7% did not have a first-degree relative healthcare worker. As regards smoking, the majority reported being passive smokers (41.6%) or non-smokers (36.8%) (Table 1).

Analysis of the HA score obtained from the SHAI showed a median of 13 [9–18] and a mean of 14.0 ± 6.7. In addition, 29 participants (4.41%) reported levels compatible with hypochondriasis (information not reported in the tables).

A weak negative correlation was found between HA measured by the SHAI and age (ρ = –0.15; p < 0.001); an association was also found with smoking (p = 0.02) where, according to the post-hoc analysis (not shown in the tables), the difference between occasional smokers and non-smokers was significant (p < 0.001). An association was also found with the year of studies (p < 0.001); second year had the highest score and, according to the post-hoc analysis (not shown in the tables), the differences were significant between second and fifth (p < 0.001) and sixth year (p < 0.001); between third and fifth year (p < 0.001), and between fourth and fifth year (p < 0.001). No association was found with gender, place of birth, first-degree relative doctor or first-degree relative healthcare worker (p > 0.05) (Table 2).

In the scores for the main section of the SHAI, a weak negative correlation was found with age (ρ = –0.15; p < 0.001); an association was also found with the year of studies (p < 0.001); second year had the highest, and the differences were significant between second and fourth (p = 0.002), fifth (p < 0.001) and sixth year (p < 0.001), between third and fifth year (p < 0.001) and between fourth and fifth year (p < 0.001). No association was found with gender, place of birth, first-degree relative doctor, first-degree relative healthcare worker or smoking (p > 0.05) (Table 2).

In the scores for the negative consequences section of the SHAI, the only association found was with the year of studies (p = 0.01). According to the post-hoc analysis (not shown in the tables), the difference was significant between second and fifth year (p < 0.001) and between fourth and fifth year (p = 0.002). No association was found with gender, age, place of birth, first-degree relative doctor, first-degree relative healthcare worker or smoking (p > 0.05) (Table 2).

In the multiple variables model (adjusted for gender, place of birth, year of studies, first-degree relative doctor and smoking), an association was found between HA measured by the SHAI and the year of studies, and there was a significant difference between the occasional smoker and the non-smoker. These associations were also found with the main section of the SHAI and the negative consequences section separately. No association was found with gender, place of birth, or first-degree relative doctor (p > 0.05) in any of the cases (Tables 3 and 4).

In the total SHAI scores, the third-year students had an average of 2 points less than the second-years (p = 0.01); the fourth-years 1.6 points less than the second-years (p = 0.03); the fifth-years 5.2 points less than the second-years (p < 0.001); and the sixth-years 3 points less than the second-years (p = 0.001). In addition, it was found that non-smokers had an average of 2.3 points less than occasional smokers (p = 0.002) (information not shown in the tables) (Table 3).

On the main section of the SHAI, third-year students had an average of 1.7 points less than second-year students (p = 0.01); the fourth-years 1.5 points less than the second-years (p = 0.01); the fifth-years 4.3 points less than the second-years (p < 0.001), and the sixth-years 2.9 points less than the second-years (p < 0.001). In addition, it was found that non-smokers had an average of 1.8 points less than occasional smokers (p = 0.003) (information not shown in the tables) (Table 4).

In the negative consequences section of the SHAI, it was found that fifth-year students had an average of 0.9 points less than second-year students (p = 0.002). In addition, a significant difference was found between being an occasional smoker and being a non-smoker. Non-smokers had an average of 0.5 points less than occasional smokers (p = 0.04) (information not shown in the tables) (Table 4).

The median of HA measured by the SHAI was 13 points, with a mean of 14. HA at levels compatible with hypochondriasis affected 4.41% of the population.

This study reports an association between HA measured through the SHAI and the year of studies; the second year shows the highest scores in both the main section and the negative consequences section. In addition, it highlights the association between HA and smoking, with higher values in occasional smokers, as well as a weak negative correlation with age. No association was found with gender, place of birth, or having a first-degree relative doctor or first-degree relative healthcare worker.

A systematic review of the SHAI reported average HA of 12.4 ± 6.8 points in the non-clinical population and 32.5 ± 9.6 in the hypochondriac population.5 In another later study carried out on Spanish adolescents,27 a mean HA level of 10.5 ± 5.7 points was reported. In studies carried out on university Psychology students, the averages recorded ranged from 10.8 ± 6.4 in students in the United States6 to 13.4 ± 5.3 points in Canadian students.9 This data is comparable to our study’s data, where we had an average of 14.0 ± 6.7 points. This suggests the average level of HA varies according to the population studied, and is higher in students of Psychology and Medicine than in the general population, and higher in students of Medicine than those of Psychology. This difference in the averages is probably due to the fact that medical students start perceiving symptoms as medical signs when they learn about new illnesses, a phenomenon considered to be a form of transient hypochondriasis.14

In the general population, no gender differences are reported.10 Studies carried out on university students in the United States29 and an English occupational sample30 also reported no gender differences in HA, in line with our study. However, a study in Spanish adolescents27 found that females had higher levels of HA than males, a finding similar to that reported in another study on patients with anxiety disorders.31 This may be based on the theory that women are more likely to have an anxiety disorder than men.32 The greater susceptibility of females to stress-related neuropsychiatric diseases is due to hyperactivity of the extrahypothalamic corticotropin-releasing factor circuits, which doubles the chances of having an anxiety disorder.33 We would therefore have expected to find gender differences in our study. However, that was not the case.

Regarding the association between HA and the year of studies, specifically concerning second-year Medicine, where the highest levels of HA were reported, a study in Medical Students in Pakistan found that second-year students had the highest HA levels and fifth-years, the lowest.12 This was in line with our results, although their differences were not significant (p > 0.05). It has also been reported that, because of the curriculum, students have subjects like pathophysiology and pathology at intermediate levels, providing them with information about the many diseases, and this can be a trigger factor for them to suffer greater concerns about their health at that point in their academic training.34 Therefore, having not yet reached the field of pre-professional practice, their HA levels increase, as the most common diseases tend not to be the most serious, which are the main concern of students.34 However, in our study, HA levels were lower on average in the more advanced years and higher in the less advanced years, despite having courses like pathology between third and fourth year without having reached the field of pre-professional practice.

The theory has been proposed in the literature that people smoke to relieve psychiatric symptoms.35,36 As far as HA and smoking is concerned, the above association was reaffirmed in an Australian study suggesting that current smokers have twice the level of HA as people who have never smoked.10 In our study, occasional smokers scored an average of 2.3 points higher for HA than non-smokers. It therefore seems that there are differences in HA levels determined by smoking, although the association is not reported as significant with all categories of smokers. We should point out that there is an alternative hypothesis that long-term smoking increases susceptibility to disorders such as anxiety and depression.37,38 One systematic review reported general disagreement on whether smoking leads to anxiety, anxiety leads to smoking or increases smoking behaviour, or the relationship is two-way.39 Based on the above, there is an obvious need for further study into smoking and HA, analysing which comes first, the various categories of smoker and other variables involved, to obtain more consistent results in this area.

The importance of preventing the consequences of HA needs to be underlined. If not diagnosed or adequately treated with cognitive-behavioural therapy, it can lead to serious repercussions.21,22 The average of the hypochondriac population is well above the average obtained by all other populations,5,27 including the medical students assessed in this study. The population with the actual diagnosis is the only group with an average above the cut-off point compatible with hypochondriasis.5 This group will definitely require timely and appropriate follow-up and treatment by a specialist. However, that does not mean that other studied populations reporting high levels compared to the general population, as in this study, do not require timely follow-up, simply that, with the average values obtained, their risk of suffering the negative consequences of hypochondriasis should not be much higher than the general population.23,26 We believe that all those with values at or above the cut-off point should be identified, as with the 4.41% of our population that scored ≥27, and provided with all the necessary measures for adequate diagnosis and treatment.

Because the questionnaire is self-administered, we need to consider the possibility of a social desirability bias. To try to make the information as reliable as possible, we stressed that there was no wrong answer and that the information would be treated anonymously. The tool used to measure health anxiety, the SHAI, is adapted for the Colombian population, which means there could be terms that make it difficult to fully understand. However, the instrument was carefully reviewed before use and was found to be understandable and applicable to the study population. We carried out an exploratory factor analysis with the basis obtained, and the internal consistency was evaluated, with good results. To estimate reliability, Cronbach’s alpha index was calculated, with a total scale reliability of 0.85; with 0.83 and 0.72 for the main section and the negative consequences section respectively.

We should point out that this study, unlike others, did not include the suffering of any non-psychiatric illness by the students themselves or a close relative among its variables, so information on the association of HA with these variables could have been lost. Personal history of a psychiatric disorder or illness is another variable that would be relevant to consider, but it was not included in this study due to a possible overlap with HA.

It is important to emphasise that the SHAI was used to assess HA in the respondents. No diagnosis was made and the results were not a substitute for a medical consultation; and we kept this at the forefront throughout the investigation.

The strengths of the study include the fact that the information is novel, as this is the first study to analyse HA in students at a Peruvian university, and one of the few to have been carried out in Latin America.