Impact of COVID-19 lockdown on glycemic control in children and adolescents =========================================================================== * Abdulmoein E. Al Agha * Razan S. Alharbi * Omar A. Almohammadi * Sondos Y. Yousef * Ahad E. Sulimani * Rawan A. Alaama ## Abstract **Objectives:** To identify how children and adolescents with type 1 diabetes were coping with their condition during the COVID-19 lockdown, by detecting differences in blood glucose control and in lifestyle, including diet, physical activity, and mood deterioration, before and during the lockdown. **Methods:** This descriptive, cross-sectional study was conducted between April and June 2020 at King Abdulaziz University Hospital (KAUH), Jeddah, Saudi Arabia. Data were collected from interviews, using various forms of telecommunication. **Results:** The total sample size was 150 patients, 48 (28%) of whom were males and 102 (72%) females. The mean age of the patients was 12.45 years. The lockdown was associated with a significant increase in patients’ weight (p=0.001), body mass index (p=0.001), and blood glucose readings (p=0.007) compared to their values before the lockdown. **Conclusion:** A negative impact of the COVID-19 lockdown was found on blood glucose values and BMI, which may correlate with a lack of physical activity, increased consumption of carbohydrates and fast food, and mood deterioration. * type 1 diabetes * COVID-19 * glycemic control The most frequent chronic metabolic disorder in children is diabetes mellitus. Hyperglycemia is the main characteristic of diabetes mellitus, which is attributed to insulin deficiency due to pancreatic β-cell loss.1,2 It is a lifelong illness that requires medical therapy, multiple daily administrations of insulin, a healthy diet, exercise, and psychological support.3,4 The control of type 1 diabetes (T1D) may be affected by many factors, and it is important to reduce the risk of complications and infections.5 It was postulated that, during the stressful time of the coronavirus (COVID-19) pandemic, managing diabetes could be difficult, especially for children with T1D.3,6 In addition, the pandemic induced some challenging lifestyle changes, including dietary habits, physical activity, insulin dose adjustment, and access to insulin supply. All of these changes could adversely affect the control of their disease. Recently, new approaches are being studied to provide new treatments to diabetic patients. Some studies have been conducted to explore how diabetic patients are dealing with their diabetes during the COVID-19 lockdown;7-9 however, few have been conducted in Saudi Arabia. We aimed to assess how children and adolescents with T1D were coping with their diabetes during the lockdown, and more broadly, to offer the diabetic community better strategies for healthy living in lockdown. ## Methods This was a descriptive, cross-sectional study on children and adolescents with T1D, conducted at King Abdulaziz University Hospital (KAUH) in Jeddah, Saudi Arabia, between April and June 2020. Subjects were contacted via an online virtual pediatric endocrine outpatient clinic at KAUH and interviewed. The study was approved by the KAUH Ethical Committee. The patients’ data were kept safe in the secure office of the principal investigator, ensuring the protection and anonymity of patients’ identities and accessed only by the authors. Informed consent was obtained from the patients’ parents prior to their participation in the study. The interview was designed to identify and assess the following: i) demographic characteristics and anthropometric measurements, including weight and height, comparing the data from their clinic visits within the last 3 months before lockdown and the first clinical visit during the lockdown. ii) The status of the patient’s blood glucose control before and during the lockdown. This was achieved by asking about daily home glucose readings, and frequency of home glucose monitoring, assessed 3 months before lockdown and 3 months into lockdown. iii) Glycosylated hemoglobin A1c (HbA1c) level, measured before lockdown and at the end of lockdown (lockdown lasted 3 months, which was long enough to evaluate the results) and DKA (diabetic ketoacidosis) episodes. iv) Lifestyle, including dietary habits. Data were obtained by asking about the number of basic meals and snacks each patient had, the type of diet, and any difficulty encountered in following a healthy diet. Multiple questions were asked of the adolescents themselves or their parents regarding the patients’ physical activity, including the baseline number of minutes of physical activity before lockdown, how it was affected during the lockdown, and satisfaction with its level. v) The insulin therapy regimen, types and frequency of injections before and during lockdown, insulin dose adjustment, and difficulties in accessing insulin supply. All children and adolescents with T1D aged 2-18 years, of both genders and all ethnicity, were included. Patients with type 2 diabetes, cognitive disability, language barriers, chronic complications, and comorbidities were excluded. ### Statistical analysis Data entry and analysis were performed using the Statistical Package for Social Sciences, version 23 (IBM Corp, Armonk, NY, USA). Data were compared before and during the lockdown. Quantitative data were expressed as a mean and standard deviation (± SD), and simple descriptive statistics were applied to report qualitative variables as frequencies and percentages. A paired t-test was utilized to check the presence of significant differences before and during the lockdown. Results having a p-value of less than 0.05 were considered to be statistically significant. ## Results Baseline demographic and clinical characteristics. This study enrolled 150 patients, with a mean age of 12.45 ± 4.62 years. Forty-eight (28%) of the patients were males, and 102 (72%) were females. The mean weight was 40.73 ± 15.49 kg, and the mean body mass index (BMI) was 20.36 ± 4.53 kg/m2. The mean age at diagnosis with T1D was 8.23 ± 5.34 years. The mean glucose reading before the lockdown was 182.29 ± 76.68 mg/d, and the mean reading of HbA1c was 7.45 ± 1.67%. **Table 1** presents the demographic and clinical profile of the patients. Approximately 10.7% of the patients did not analyze their glucose daily, 21.3% of patients analyzed their glucose 2-3 times daily, 14% analyzed their glucose 4-5 times daily, 14.7% analyzed their glucose 5-7 times daily, and 39.3% had a continuous glucose sensor (**Figure 1**). During the lockdown, the frequency of glucose monitoring has been changed in 48.8%; of them 75.6% reported an increased frequency of glucose monitoring, and 24.4% reported a reduced frequency. Interestingly, our findings demonstrated that the percentages of patients who experienced DKA were decreased from 34.5% pre the lockdown to 10.7% during the lockdown. Of the study population, 15.3% took insulin twice a day, 50.7% took insulin 3 times a day, and 24.7% took insulin more than 4 times a day before the lockdown compared to 32.7% during the lockdown. In addition, 9.3% took insulin administered by an insulin pump. View this table: [Table 1](http://smj.org.sa/content/42/1/44/T1) Table 1 Demographic data and anthropometric measurement (n=150). ![Figure 1](http://smj.org.sa/https://smj.org.sa/content/smj/42/1/44/F1.medium.gif) [Figure 1](http://smj.org.sa/content/42/1/44/F1) Figure 1 Daily frequency of home glucose analysis. ### Change from baseline due to the lockdown **Table 2** illustrates changes in weight and diabetic parameters from the baseline due to lockdown. View this table: [Table 2](http://smj.org.sa/content/42/1/44/T2) Table 2 A comparison of weights and diabetic parameters before and during lockdown **Figure 2** shows the comparison between the number of insulin taking before and during the lockdown. ![Figure 2](http://smj.org.sa/https://smj.org.sa/content/smj/42/1/44/F2.medium.gif) [Figure 2](http://smj.org.sa/content/42/1/44/F2) Figure 2 Comparison between the number of insulin taking before and during the lockdown. Regarding diet, **Table 3** shows that 23.2% of the subjects were following a healthy diet before the lockdown, whereas 46.4% found difficulty in following a healthy diet during the lockdown for various reasons, such as a larger number of meals (47.4%) and increased consumption of carbohydrates (37.1%), fast food (15.5%), and soft drinks (9.3%). More than half (52.2%) of the subjects reported that their diet had been affected by the lockdown. However, most of the patients were consuming the same number of snacks per day before and during the lockdown. View this table: [Table 3](http://smj.org.sa/content/42/1/44/T3) Table 3 Dietary patterns of the patients before and during the lockdow **Table 4** shows the difference between the physical activity pre and during the lockdown, physical activity was also affected. During the lockdown, we noticed a decrease in their daily activity, increased their daily physical activity, and reported no change in their physical activity. And it was found that 64.9% were not satisfied with their level of physical activity. View this table: [Table 4](http://smj.org.sa/content/42/1/44/T4) Table 4 Physical activity of patients before and during lockdown. ## Discussion Since the lockdown began in March 2020,10 several studies have been published about its effect on the lifestyle of children and adolescents.11 These data showed significant changes in their lifestyle habits.12 It is believed that the pandemic may have a lasting impact on physical activity patterns and dietary habits13 and therefore on the overall health of children/adolescents, especially for T1D patients and their glycemic control. Various factors have been shown to have a beneficial effect on T1D patients by improving their glycemic control, such as insulin therapy, glucose monitoring, regular exercise, following the recommendations about diet, and maintaining a healthy weight. The present study aimed to analyze the impact of the lockdown on these factors and explore how lifestyle changes reflected on the subjects’ glycemic control. Maintaining a healthy weight has obvious health benefits in improving glycemic outcomes. However, maintaining a healthy weight during the lockdown has become difficult, particularly for T1D children. According to studies, approximately half of the patients reported an increase in weight during the lockdown; a recent Italian survey reported a weight gain in 46.6% of the sample.14 Comparably, the present study’s results showed that the mean and SD of their weight during lockdown was higher than at their last clinic visit pre-lockdown (**Tables 1 & 2**). In addition, we calculated the patients’ BMI to detect if there was any difference before and during the lockdown. A significant increase in BMI and body weight during lockdown was found (**Table 2**). Impaired glycemic control was exacerbated by decreased physical activity and an unhealthy diet. The results of this study found that 52.2% of participants followed a healthy diet before lockdown, compared to 23.2% during lockdown (**Table 3**). This result was similar to that of a European study, which reported an increase in appetite by 34.4% of the respondents.14 A number of online surveys around the world agreed that food consumption and dietary patterns were unhealthier during confinement.15 In this study, it was found that 46.4% had difficulty in following a healthy diet during the lockdown, owing to increased consumption of fast food, carbohydrates, and soft drinks (**Table 3**). It has long been recognized that a sedentary lifestyle has a detrimental impact on glycemic control, and conversely, that physical activity has a significant role in the regulation of blood glucose.16 Lockdown policies in the current pandemic have caused massive distortion in people’s daily routines, including their physical activity level. Physical activity decreased in 66.1% of our patients during the lockdown compared to before lockdown. This was a function of sedentary habits during their leisure time, namely, watching TV,- playing- online games, and using computers. Hence, glycemic control was adversely affected during the lockdown. Good glycemic control can be achieved via frequent home monitoring of blood glucose levels and following up with regular HbA1c tests. Diabetic patients tended to face difficulties attending their pre-scheduled follow-up visits, and, as a consequence, many patients postponed or even canceled such visits. In this study, we analyzed the frequency of daily home glucose measurements and found that the majority of our patients were using a continuous glucose sensor (**Figure 1**). By comparing their blood glucose readings before and during the lockdown, a significant (*p*=0.007) increase in glucose readings was demonstrated. Patients with T1D depend on insulin therapy for glycemic control.17 The present study found that 27.1% had difficulty in obtaining insulin during the lockdown, which may have reflected on their readings. Diabetic patients are more likely to suffer from stress and mood deterioration, which could be exacerbated by circumstances such as a lockdown. According to our findings, 59.6% of the subjects suffered from mood deterioration, possibly affecting their blood glucose readings. ### Study limitations There are 5 major limitations in this study, which could be addressed in future research. First, for technical reasons, we were unable to obtain data about the average number of glucose readings per patient that were used to calculate mean glucose in patients who were not on CGMS (continuous glucose monitoring system) Second, we could not separate the analysis on participants who were on continuous glucose monitoring to confirm our findings. Third, this study involved a small number of patients; therefore, our findings may not be generalizable to the entire population of Saudi Arabia. The fourth limitation was the use of convenience sampling, which may aggravate the risk of selection bias. Future studies should involve a larger sample size. The fifth limitation was that the compliance of the participants with their regimen was not assessed. In conclusion, many patients reported a change in their lifestyle and eating habits during the lockdown, which likely predisposed them to difficulties in glycemic control. ## Acknowledgment *This research article was made possible with the help and support of Nada O. Alrowashed and Jamla A. Msfer Alshahrani. We would like to thank Scribendi company (Scribendi.com) for English language editing*. ## Footnotes * **Disclosure.** Authors have no conflict of interests, and the work was not supported or funded by any drug company. * Received September 24, 2020. * Accepted December 7, 2020. * Copyright: © Saudi Medical Journal This is an open-access article distributed under the terms of the Creative Commons Attribution-Noncommercial-Share Alike 3.0 Unported, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. ## References 1. 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