|Year : 2016 | Volume
| Issue : 1 | Page : 25-35
Axis-I psychiatric morbidity in a sample of Egyptian competitive athletes
Doaa H Hewedi, Heba F Hendawy, Walaa M Sabry, David A Baron, Ahmed A Abdel Gawad, Haytham M Hassan
Department of Psychiatry, Ain Shams University Hospitals, Cairo, Egypt
|Date of Submission||12-Nov-2015|
|Date of Acceptance||10-Nov-2015|
|Date of Web Publication||13-Apr-2016|
Walaa M Sabry
Lecturer of Psychiatry, MD in Psychiatry, Faculty of Medicine, Ain Shams University, Cairo
Source of Support: None, Conflict of Interest: None
Competitive sport environment puts athletes under a significant amount of psychological burden and stress. Despite the great effort and recent interest in athletic achievements, studies on the prevalence of mental health disorders in athletes are still lacking.
This study aimed to provide an insight into the prevalence of different psychiatric morbidities in a sample of Egyptian competitive athletes and to identify the association of psychiatric morbidity prevalence with the athlete's sex, weekly training hours, sport type, and sport injury as a unique experience facing the athletes.
Participants and methods
A total of 101 competitive athletes were recruited from some of the sporting clubs in Cairo and Giza by using a stratified random sampling method. They were interviewed using the Structured Clinical Interview for DSM-IV (SCID-I) diagnoses.
SCID-I showed that 31.6% of the participants had current Axis-I psychiatric diagnosis, whereas 34.7% of them reported a history of past psychiatric morbidity. Phobic and adjustment disorders were the most common current psychiatric disorders among athletes. Depressive disorder not otherwise specified and dysthymia were encountered more in female athletes, and substance use was more common in their male counterparts. Combat players had the highest rate of adjustment disorder (48%), whereas the power games athletes had the highest rate of drug abuse (12%). Significant physical injury during the past year was associated with high rates of dysthymia, post-traumatic stress disorder, and social phobia.
Athletes in Egypt showed among them a high rate of Axis-I psychiatric diagnoses, which could not be ignored and necessitates professional mental health attention for early detection and intervention.
Keywords: Axis-I, competitive athletes, morbidity, SCID-I
|How to cite this article:|
Hewedi DH, Hendawy HF, Sabry WM, Baron DA, Abdel Gawad AA, Hassan HM. Axis-I psychiatric morbidity in a sample of Egyptian competitive athletes. Egypt J Psychiatr 2016;37:25-35
|How to cite this URL:|
Hewedi DH, Hendawy HF, Sabry WM, Baron DA, Abdel Gawad AA, Hassan HM. Axis-I psychiatric morbidity in a sample of Egyptian competitive athletes. Egypt J Psychiatr [serial online] 2016 [cited 2023 Nov 30];37:25-35. Available from: https://new.ejpsy.eg.net//text.asp?2016/37/1/25/180267
| Introduction|| |
Studies researching into the relationship between sport participation and mental health has yielded conflicting results (Storch et al., 2005; Proctor and Boan-Lenzo, 2010). A number of studies have suggested that participation in sport is associated with psychological privileges and that it acts as a buffer against various sources of stress (Proctor and Boan-Lenzo, 2010).
In contrast to these findings, a growing body of research has provided evidence that competitive athletes are not immune to struggle with their mental well-being (Glick and Horsfall, 2001; Storch et al., 2005; Gill, 2008). They often encounter unique stressors that the general population does not have to deal with, such as time demands, relationships with coaches, missed scheduled classes, stress of competitions, pressures of meeting expectations and pleasing those around them, negotiating relationships, retirement from sport, and performance anxiety (Storch et al., 2005; Yang et al., 2007; Proctor and Boan-Lenzo, 2010). In addition, student-athletes usually play different identity roles as they are expected to meet the demands of being a student as well (Storch et al., 2005; Yang et al., 2007). Balancing different identity roles can be a significant challenge for the collegiate athlete and this role conflict or interference has been found to negatively affect their mental health (Settles et al., 2002; Killeya-Jones, 2005).
Studies have showed that competitive athletes might experience a wide range of psychiatric and psychological problems (Glick and Horsfall, 2005). Yet, they are hesitant in consulting a psychiatrist for the fear of getting stigmatized (Glick and Horsfall, 2001). Athletes could present with mood, anxiety, and other neurotic disorders (Anderson et al., 1994; Cogan, 1998). Furthermore, substance abuse and antisocial behavior are not uncommon in sports (Martin and Thrasher, 1998). In spite of these rising researches in the field of sports psychiatry, epidemiological studies on psychiatric disorders in athletes are still lacking (Broshek and Freeman, 2005; Reardon and Factor, 2010). Four possible associations between competitive sport activity and psychiatric disorders have been described:
- Athletes may be higher achievers in spite of a coexistent primary psychiatric disorder;
- Athletic pursuits could be their way of coping with a disorder; or
- The sport itself causes worsening of the already existing psychiatric illness;
- Moreover, injury, competitive failure, aging, retirement from sport, and other psychosocial stressors could precipitate mental disorder in athletes (Baum, 2000, 2003).
The lack of data on the mental health status of athletes makes it difficult to develop suitable mental health interventions (Yang et al., 2007). Thus, through this study we aimed to shed light on the prevalence of the common psychiatric morbidities in Egyptian competitive athletes and to identify the possible relationship between psychiatric morbidity with the type of practised sport, amount of weekly training hours, sex difference, and unique experiences facing the athletes such as sport trauma.
We hypothesized that the prevalence of psychiatric morbidity among competitive athletes would be higher than that of the general population and that there would be unique factors associated with high prevalence rate, like specific sex, certain sport types, higher weekly training hours, and unhealed sport physical injury.
| Participants and methods|| |
The current study was cross-sectional in nature, and was conducted on a sample of Egyptian competitive athletes.
Site of the study
The participants were selected from the Egyptian sporting clubs that compete in national championships in Cairo and Giza.
Selection of participants
Participants were selected using the stratified random sampling method. The original sample consisted of 104 athletes. We included Egyptian competitive athletes who were 18 years old or more, could read and write, were still participating in national competitions, and who agreed to give an informed consent; athletes of both sexes were included in the study. The only cause for exclusion was the refusal of the athlete to participate in the study and sign for the study consent. Two athletes withdrew their consent just before the start of the study, without giving specific explanation, and another participant left his club and changed his contact details. Thus, we were left with 101 athletes, all of whom participated in the study.
The participants were further divided into four groups according to the type of their sports: combat sports (karate and judo), individual power sports (running, discus throw, shot put, and jumping), team sports (basket, hand, and volleyball), and other individual sports (tennis, badminton, and parachuting).
The competitive athlete has been described as one who participates in an organized team or individual sport requiring systematic training and regular competition against others while placing a high premium on athletic excellence and achievement (Maron and Mitchell, 1994).
Different levels of competitions were identified, ranging from national (at the level of governorates or the whole country), regional (at the level of Arab, Mediterranean, or African countries), and international competitions (including the World Cup, Olympic, and other official international championships). In this study, the competitive athletes were chosen from those who were at least participating in national competitions.
Ethical considerations and approvals
Ethical approval for the study was granted by the Ain Shams University Ethical and Research Committee. The authors also received the approval of the National Sports Council before starting the study procedure and got their recommendation letters to the suggested clubs, as well as the approval of the club managers.
In addition, a written informed consent was taken from each athlete to whom we explained the full procedure and the aim of the study. All the participants had the right to withdraw from the research at any time without giving reasons, and without any negative consequences.
- A designed questionnaire was used to gather data about the athletes' sex, age, type of sport, number of sports that they regularly played, training hours, level of competition, and history of significant physical injury that prevented them from practicing their sport the year before the study.
- Structured Clinical Interview for DSM-IV-Clinician Version (SCID-CV) (First et al., 1997) Arabic version (El Missiry et al., 2004). It contains seven diagnostic modules, focused on different diagnostic groups: mood, psychotic, substance abuse, anxiety, somatoform, eating, and adjustment disorders. Arabic version of SCID-I-CV was translated by El Missiry et al. (2004) and was validated through its use in numerous studies conducted in research centers in Egypt. We used the clinical version for a relatively easier administration in clinical setting.
For the purpose of confidentiality, we chose to make appointments with the athletes before or after the training time and conducted the interview away from other team members and coaches. The study was carried out over a 15-month period. Participants found to be suffering from any psychiatric disorder were informed about their condition and referred for further assessment and management. The fear of stigma was the main reason behind participants' refusal to involve their coaches and family members to get collateral information.
Data were organized, tabulated, and transferred on the statistical package for the social sciences (SPSS, version 17; SPSS Inc., Chicago, Illinois, USA), using a personal computer; all the suitable statistical parameters were used. Student's t-test was used for comparison between means of two groups of participants. The Pearson c2 -test was used to test for significant association between different categorical variables. A statistical level of significance was set at 0.05.
| Results|| |
Sociodemographic and sport data of the study participants
A total of 101 athletes were enrolled into this study. Athletes of both sexes were included with an equal distribution. The mean age of the participants was 21.8 ± 3.4 years. In terms of the type of sport, participants were equally distributed into the four types of the studied sports (combat, individual power, team, others). Results showed that 44.6% of the participants were receiving 11-18 h of weekly training (the mean for weekly training hours was 14.38 ± 6.66) and that 12% of the study athletes were playing more than one game. Detailed data are shown in [Table 1].
Prevalence of psychiatric disorders among study participants
We used SCID-I-CV to detect Axis-I DSM-IV diagnoses. The athletes who reported having symptoms were categorized according to the time of the attack as follows:
- Never: the participant never had symptoms amounting to Axis-I diagnosis, neither currently nor in the past;
- Past: had clinical diagnosis in the past; and (iii) current: this was either the first time to have Axis-I diagnosis and he/she had symptoms at time of the interview. For substance use disorders (SUDs), the term occasional use describes a sporadic use of substance not fulfilling the criteria for any of the SUD categories.
As shown in [Figure 1], 31.6% of the participants had current psychiatric morbidity (one or comorbid psychiatric disorders), whereas 34.7% of them had a past history of psychiatric diagnosis (one or comorbid diagnoses). Thus, 66.3% of the participants had an Axis-I DSM-IV diagnosis at some point in their life (past, current).
None of the study participants were having past or current history of bipolar I disorder, psychotic disorders, hypochondriasis, or bulimia disorders.
Specific phobia was found by far to be the most common current Axis-I diagnosis (15.8%) in athletes, and then adjustment disorder (11.9%), followed by dysthymia (6.9%) ([Table 2]). The percentage of current specific diagnoses (58.4%) exceeded the overall percentage of the current SCID-I diagnoses (31.6%) because of the presence of comorbid disorders, as 27 (26.7%) athletes were found to have comorbid anxiety and depressive disorders.
|Table 2 Prevalence of current and past psychiatric morbidity among athletes|
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The most common past diagnoses among participants were specific phobia (18.8%), followed by adjustment disorder (11.9%), and then social phobia (10.9%) ([Table 2]). Participants reported that they did not seek any psychiatric advice or received any medications for their past psychiatric symptoms. The percentage of past specific diagnoses (85.4%) exceeded the overall percentage of the past SCID-I diagnoses (34.7%) because of the presence of comorbid disorders, as 51 (50.7%) athletes were found to have either one or two comorbid disorders.
Mood and anxiety disorders represented the most common current Axis-I diagnosis in the study sample. Depressive disorder was collectively found in 19.9% of the participants at the time of interview, as 4% had current major depression, 5% had depressive disorder not otherwise specified (NOS), and 6.9% had dysthymia. Overall, 2% had bipolar affective disorder (BAD) II disorder and 2% had BAD NOS. Whereas current anxiety disorder (panic, social phobia, specific phobia, obsessive compulsive disorder (OCD)) was found in 22.8% of the participants ([Table 2]).
With regard to illicit substances used by the participants, three (3%) athletes reported past use of substance, mainly cannabis (3%); all athletes denied any current use of substance ([Table 2]).
Four (4%) athletes reported occasional use of two or more substances as follows: two players used cannabis and alcohol, one used cannabis and opiates (tramadol), and one used cannabis and benzodiazepines. Thus, cannabis (4%) was the most frequently used substance, followed by alcohol (2%), opiates, and benzodiazepine (each 1%). The main reasons reported by these athletes for using these substances were out of desire to seek novel experiences and to share it with his/her peers. The one who used tramadol was a long distance runner, and admitted that he used it to increase his workout.
A total of 47 (46.5%) athletes reported using supplements at the time of the study. All of them denied the use of anabolic steroids and mentioned using amino acids, vitamins, iron, etc. They used them without medical prescription, depending on their coaches' and peers' experience or their own trials. They used it for the purpose of doping in an attempt to enhance their performance and gain competitive advantage.
Sex differences in the prevalence of psychiatric morbidity among athletes
Comparisons between male and female participants in the study were made regarding the overall prevalence of past and current psychiatric morbidity using SCID-I. Having a psychiatric disorder in general did not differ significantly between male and female athletes. Whereas the results revealed that more females than males displayed the diagnoses of depression NOS and dysthymia (P = 0.019 and 0.023, respectively). In contrast, males had the SUD diagnoses more than did females (P = 0.025) ([Table 3]).
|Table 3 Sex difference in the prevalence of psychiatric morbidity among athletes|
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Psychiatric morbidity in relation to amount of training hours
Results showed that no significant association between any of the Axis-I psychiatric morbidities and various amounts of training hours ([Table 4]).
|Table 4 Relation between psychiatric morbidity and amount of training hours/week|
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Psychiatric morbidity in relation to the sport type
The sports groups were compared as regards the results of SCID-I, with no significant difference found on the rate of presence of different Axis-I diagnoses except for adjustment disorder and SUD. Combat players were found to have the highest rate of adjustment disorder (12 athletes, P = 0.011), whereas power games athletes had the highest rate of drug abuse (three athletes, P = 0.017) ([Table 5]).
|Table 5 Psychiatric morbidity among athletes in relation to the type of sport|
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Relation between significant last year physical injury and psychiatric morbidity among athletes
SCID-I results demonstrated statistical difference between injured and noninjured groups of athletes. The differences were in the presence of Axis-I disorder in general (P = 0.033). More specifically, dysthymia, post traumatic stress disorder (PTSD), and social phobia were the most prevalent disorders in injured athletes (who had significant physical injury affecting their participation in competitions during the year preceding the interview) ([Table 6]).
|Table 6 Correlation between current Axis-I diagnosis and rate of unhealed physical injury during the last year|
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| Discussion|| |
Studies on the prevalence of psychiatric disorders among athletes are scarce. The fear of stigma and widespread assumption that only psychiatrically free athletes are able to compete at the highly professional level are the main reasons behind the deficiency of psychiatric research in this field (Linder et al., 1991). Athletes themselves have a high tendency to minimize apparent signs of weakness. Moreover, athletic behaviors sometimes resemble symptoms of mental disorders (e.g. meticulous attention to diet, relative hyperactivity), thereby confounding recognition of illness (Reardon and Factor, 2010). But available research data about the prevalence of mental disorders in this area alarmed mental health professionals that this hypothesis needs to be revised. There have been few studies looking at the prevalence of some psychiatric disorders in various athlete populations. Eating disorders and substance abuse are the most studied of these disorders and appear to be common problems in athletes (Reardon and Factor, 2010). However, to provide evidence-based understanding and treatment for this population group, we especially need more researches on the prevalence of other different psychiatric disorders and their associated risk factors. Thus, the aim of the current study was to detect the prevalence of psychiatric morbidity among a sample of Egyptian competitive athletes.
We used the SCID-I psychiatric interview to detect the psychiatric morbidity among athletes, both currently and in the past. Results illustrated that 31.6% of the participants had current Axis-I psychiatric diagnosis. To the best of our knowledge, no studies were found on the prevalence of each and different psychiatric disorders in athletes. Yet, several studies proposed that athletes experience psychiatric disorders, including mood disorders, at the same rate as does the general population (Burton, 2000; Reardon and Factor, 2010). Whereas trying to compare our findings with the results of the Egyptian national survey by Ghanem et al. (2009), we found that the findings of the current study revealed a higher prevalence (31.6%) of Axis-I diagnoses than did the Egyptian general population (16.93%). The difference could be explained by different methodological issues, like different tools of assessment, different age groups (being younger in the current study), and different sample size (being smaller in our study).
As regards classification of psychiatric morbidity among athletes using SCID-I, results displayed that mood and anxiety disorders were the most common disorders (19.9 and 22.8%, respectively). These results are different than that reported for a similar age group in the national Egyptian survey by Ghanem et al. (2009), although they found that depressive and mood disorders were the most common among their sample, but their rates were much lower than our results (6.4% for mood disorder, 4.75% for anxiety disorders). A systematic review on some epidemiological studies on Egypt by Khalil et al. (2009) revealed that the prevalence of depressive disorder ranged between 8 and 10%. Another Egyptian study on the prevalence of depressive disorders among adolescent secondary school students revealed a prevalence rate of 13.3% for depressive disorders (Khalil et al., 2010). Variation in results may be due to different sample size, tools used for assessment, and the age of the participants.
However, our findings are in agreement with that of a study by Yang et al. (2007), who found that more than 20% of the athletes had depressive symptoms, and by Markser (2011), who concluded that depression was the most common mental disorder affecting athletes. Other studies disagree with our findings, such as that by Oler et al. (1994), who reported that athletic participation was a marker for a decreased likelihood of depression and suicidal ideation, and a study by Donohue et al. (2004), who compared 72 National Collegiate Athletic Association (NCAA) athletes and 64 recreational athletes at one university with data previously collected on 435 control students at another university. They found no difference in psychiatric symptoms, including those of depression, between the recreational and NCAA athletes, and between all athletes and controls.
Surprisingly, none of the study athletes had received the diagnosis of bulimia disorder, and the diagnosis of anorexia nervosa among the study sample was as low as 1%, which is nearly similar to the rate of general population (Qian et al., 2013). This finding is in contrast to the findings of several other studies, which found that the rate of anorexia or bulimia among athletes might range from 13 to 15% (Byrne and McLean, 2001; Black et al., 2003; Sundgot-Borgen and Torstveit, 2004). This could be explained by the fact that the high figures in these previous studies were related mainly to the type of practiced sports. These previous studies involved sports that usually emphasize the importance of thinness, in which the body weight could affect the performance outcome, such as esthetic sports (ballet-figure skating), sports with body weight classes, and those sports in which body weight could give an advantage, such as marathon running. The current study did not include such types of sports. This contributed to the low rates of eating disorders in the current study.
Our results pointed out that 34.7% of the athletes had past psychiatric disorder (one or more comorbid disorder) to which they did not seek or received any help. This could reflect the magnitude of unnoticed mental health problems among this population.
With regard to the prevalence of substance abuse among the studied sample, the current study detected a past history of abuse in 3% of the athletes, whereas in 4% only occasional use was reported. Cannabis was the most frequently used substance (4%), followed by alcohol (2%), opiates, and benzodiazepine (1% each). All athletes denied any current use of substance. Our results are similar to the results of the Egyptian survey by Ghanem et al. (2009), who found that alcohol and drug dependence/abuse were the least prevalent in their study (0.03 and 0.13, respectively) and that cannabis was the most commonly used substance. A systematic review on some epidemiological studies in Egypt by Khalil et al. (2009) revealed that cannabis was the most common substance used among Egyptians in the majority of studies on substance abuse; however, a wide range for abuse/dependence rate (3.9-39.3%) was reported in this systemic review.
In contrast, our results were markedly lower compared with the international large scale studies where alcohol use among college athletes has been reported to be as high as 75-93% for men athletes and 71-93% for women athletes (Johnson et al., 2004), and with a study by Green et al. (2001), who found that alcohol was the most widely used drug in the past year in 80.5% of the athletes, followed by marijuana at 28.4%, and smokeless tobacco at 22.5%. The difference in results could be explained by several factors; the current study used only diagnostic interviewing tests, with no other sources of collateral information or laboratory investigations. In addition, the participants met the interviewer for the first time and that hindered them from being spontaneous and from openly answering such questions; this may be the cause that even those who reported their abuse, mentioned it was in the past. Cultural and religious influence should be taken in consideration with regard to the type of abused substance. The current study showed that alcohol abuse was reported to be less frequent than cannabis abuse, which is very common in the Arabic Islamic world. Alcohol is culturally and religiously unaccepted compared with cannabis, which is seen differently, as a sign of manhood (Okasha, 1999). The current study showed that the males reported the use of a substance more than did females, which could be related to certain cultural constructs, especially in the Arab world, that accept the use of certain types of substances among males and strongly reject them for females.
Moreover, in the current study, 46.5% of the athletes reported use of supplements with an intention for enhancing their athletic performance, including amino acids, iron, vitamins, etc, and all athletes denied using androgen anabolic steroids (AASs). They reported getting their supplement through their coaches and peers. In a repeated survey into the frequency of doping among German professional athletes undertaken in 2009, it was estimated that 35% of them had consciously taken illegal performance-enhancing substances at least once during their sporting careers (Markser, 2011). AAS use was reported at 1.1% overall rate in other studies (Green et al., 2001). In Jordan, 26% of the body-building athletes were found to be current users of AAS, and like Egyptian athletes, they reported receiving their supplements through their peers and coaches (Tahtamouni et al., 2008).
Studying sex differences in the prevalence of psychiatric disorders among athletes has received scant research attention. In the current study, females displayed more depressive symptoms than did male athletes, specifically depression NOS and dysthymia disorders. This result agrees with the results of a study by Yang et al. (2007). It is still unclear why female athletes experience more symptoms of depression. But previous studies have reported a greater incidence of depression among female athletes compared with males (Donohue et al., 2004; Storch et al., 2005; Yang et al., 2007). Various theories have been suggested to explain the reported sex difference in the prevalence of depression. Typically, these theories have pointed to potential hormonal or cognitive differences (LaFrance and Stoppard, 2006) and sex role socialization with different rearing environments, different social roles, and different societal attention toward female sports in general (Altemus, 2006). Another possible explanation for the results of this study is that women are generally more willing than men to seek help and thus report their symptoms (Yang et al., 2007).
Surprisingly, results of the current study revealed that there was no significant relation between psychiatric morbidity and weekly training hours. We had expected to detect an increase in Axis-I diagnoses, especially mood disorders, among athletes with higher weekly training hours, as an indicator for extensive exercise. This is in contrast to the findings of several studies, like that by Morgan et al. (1987), who studied 400 competitive collegiate swimmers over 11 years and found that mood-state disturbance increased in a dose-response manner as the training stimulus increased during the season, and then fell to baseline with a reduction in training load. Other studies showed the incidence of depressive mood related to excessive training hours is estimated to be 7-20% per training season (Alves et al., 2006), and this prevalence is believed to be even higher in the case of endurance sports (Mackinnon, 2000) and among elite athletes secondary to their extensive training program (Peluso and Andrade, 2005). Variability in results might be due to the fact that the smallest percentage (22%) of the study sample had an excessive training hours (>18 h), and a high proportion of the study sample (45%) had 11-18 training hours weekly and 33% of the study athletes were being trained less than 11 h weekly.
In terms of association of specific sport type with certain psychiatric morbidity, the difference between groups in certain Axis-1 diagnoses was found in adjustment disorder where the combat athletes showed the highest morbidity, as there is high competition level among the combat athletes. They usually focused on the individual differences between them and their competitors, who come into immediate contact with them; this in turn lead to heightened precompetition anxiety levels, which lead to frustration and depressive symptoms in cases of loss. SUD was the most common among the power sports group; this could be attributed to the nature of such sports that requires unique quality of performance regarding speed, power, and accuracy (Nia and Besharat, 2010).
Reporting physical injury during the past year was associated with the presence of SCID-CV positive diagnosis in the current study, particularly dysthymia, PTSD, and social phobia. This can be understood in the light of mutual relation and association between physical injury with mood and anxiety symptoms among athletes. This data have been confirmed in several previous studies (Wiese-Bjornstal et al., 1995; Lavallee and Flint, 1996; Johnson, 1997; Wiese-Bjornstal et al., 1998; Junge, 2000; Putukian and Echemendia, 2003; Broshek and Freeman, 2005; Galambos et al., 2005; Walker et al., 2007; Nippert and Smith, 2008; Lockhart, 2010). These studies added that physical injury could be caused by an increased level of anxiety, especially performance anxiety, and depressive symptoms. In addition, depressive and anxiety symptoms could develop as a response to physical injury itself and includes frustration, tension, grief, depression, low self-esteem, loss of identity, and anxiety from reinjury. Because psychological variables influence injury onset, duration, and recovery, many researchers have concluded that 'rehabilitation from sport injury should involve not only physical, but psychological considerations' (Crossman, 1997).
| Conclusion|| |
This study added to the limited research on the area of sport psychiatry. High prevalence of Axis-I disorders among Egyptian competitive athletes highlights the magnitude of overlooked mental health problems in this population group. The study showed that the percentage of current psychiatric morbidity was 31.7% among athletes, and past psychiatric morbidity was 34.7%, which could not be ignored. Depressive disorders were found to be higher in female athletes than in males, whereas SUD was more prevalent in male athletes than in females. Psychiatric morbidities were found to be associated with specific risk factors; some of them were unique to athletes themselves as the type of sport and history of unhealed injury. We recommend that all competitive athletes receive screening for their mental well-being as a routine assessment and those psychiatric symptoms in athletes should never be taken lightly, and should receiving care and support as early as possible. It is also extremely important for coaches to be familiar with the symptoms of common psychiatric disorders and the ways in which athletes may express their feelings. Finally, guiding athletes with the involvement of mental health specialist through injury or rehabilitation is of vital importance.
Further researches are needed to focus on the athletes' different coping strategies, prognosis, and the various therapeutic intervention that could be beneficial for the athletes.
Strength and limitations
To the best of our knowledge, this study is one of the few that has investigated the prevalence of different psychiatric disorders among competitive athletes. The use of a valid reliable tool in assessment in the form of SCID-I strengthened the results.
However, our study was limited by a small sample size, which may limit the generalization of the study. Future epidemiological studies on large numbers of athletes at different stages of competition are mandatory to tailor preventive and interventional mental health services among athletes. Furthermore, it was a cross-sectional study, and thus caution is still warranted in explaining the findings compared with longitudinal studies, which would be more confirmative. Another limitation is the lack of comparison or control group with which to compare the prevalence of different psychiatric disorders. A control group consisting of athletes who do not have any Axis-I psychiatric morbidity could have been used and strengthen the correlation analysis. Instead, we compared our results with those of other national surveys and systematic reviews on some national epidemiological studies. However, it would serve as a pilot research to be followed by more specific research into each psychiatric disorder.
The authors thank Professor Aida Seif Eldawla and professor Mohamed Fekry for their great support and help. They also thank all athletes for their cooperation in this work.
Financial support and sponsorship
Conflicts of interest
There are no conflicts of interest.
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[Table 1], [Table 2], [Table 3], [Table 4], [Table 5], [Table 6]