Hostname: page-component-7bb8b95d7b-s9k8s Total loading time: 0 Render date: 2024-09-26T14:13:27.790Z Has data issue: false hasContentIssue false
  • English
  • Français

Delayed sleep phase disorder during the COVID-19 pandemic and its health implications

Published online by Cambridge University Press:  28 February 2023

Ulises Jiménez-Correa ,
Naylea Bonilla ,
Horacio B. Álvarez-García ,
Gerardo Méndez-Alonzo ,
Andrés Barrera-Medina ,
Rafael Santana-Miranda ,
Adrián Poblano Open the ORCID record for Adrián Poblano [Opens in a new window]  and
Hernán A. Marín-Agudelo
Ulises Jiménez-Correa
Affiliation:
Clinic of Sleep Disorders, National University of Mexico (UNAM), Mexico City, México
Naylea Bonilla
Affiliation:
Clinic of Sleep Disorders, National University of Mexico (UNAM), Mexico City, México
Horacio B. Álvarez-García
Affiliation:
Clinic of Sleep Disorders, National University of Mexico (UNAM), Mexico City, México
Gerardo Méndez-Alonzo
Affiliation:
Clinic of Sleep Disorders, National University of Mexico (UNAM), Mexico City, México Department of Neurology, MIG Hospital, Mexico City, México
Andrés Barrera-Medina
Affiliation:
Clinic of Sleep Disorders, National University of Mexico (UNAM), Mexico City, México
Rafael Santana-Miranda
Affiliation:
Clinic of Sleep Disorders, National University of Mexico (UNAM), Mexico City, México
Adrián Poblano*
Affiliation:
Clinic of Sleep Disorders, National University of Mexico (UNAM), Mexico City, México Laboratory of Cognitive Neurophysiology, National Institute of Rehabilitation, Mexico City, México
Hernán A. Marín-Agudelo
Affiliation:
Center of Neurology, Institute of Behavioral Sleep Medicine, Medellín, Colombia
*
*Author for correspondence: Adrián Poblano, MD, DSc Email: drdislexia@yahoo.com.mx
Rights & Permissions [Opens in a new window]

Abstract

Circadian rhythm sleep disorders are alterations that are characterized by a shift in the sleep-wake cycle relative to day and night, such as the delayed sleep phase disorder (DSPD), which is a retard of at least 2 hours in the sleep start. Typically, the patient falls asleep after 2 a.m. and wakes up after 10 a.m. and with symptom of sleep onset insomnia. The prevalence of DSPD in young adults is 0.48%, increasing to 3.3% in adolescents. Interestingly, patients with COVID-19 infection report anxiety due to the intensive care unit lockdown and constant exposure to bright light. In addition, post-COVID patients have an increased risk of developing DSPD. For example, in adolescent post-COVID patients, the prevalence of DSPD increases to 63.3%. Patients with DSPD also have alterations in metabolic health, poor school performance, cognitive impairment, and a higher risk of developing other diseases. The objective of the present review is therefore to describe the characteristics of DSPD during the COVID-19 pandemic and to outline its possible implications for physical health (eg, metabolism) and mental health (eg, anxiety or depression).

Keywords

Chronobiology disordersdelayed sleep phaseCOVID-19metabolic diseasesmental health
Type
Review
Information
CNS Spectrums , Volume 28 , Issue 5 , October 2023 , pp. 581 - 586
Copyright
© The Author(s), 2023. Published by Cambridge University Press

Introduction

The daily cycles of light and dark are internalized in individuals as circadian rhythms such as the sleep-wake cycle, their existence allows the synchronization of biological and behavioral processes to the environment.Reference Walker, Walton, DeVries and Nelson1 The loss of synchronization produces circadian rhythm disorders, which are defined as alterations caused by abnormalities in the timing, its driving mechanisms, or a gap between the endogenous rhythm and environment.

Sleep disorders are a public health concern. They have a strong impact on quality of life; mental and physical health; and vehicle or work accidents. The diagnosis of sleep disorders including circadian rhythm sleep disorders (CRSD) carried out according to the criteria of the International Classification of Sleep Disorders.2 CRSD generated high costs for health services and high rate of accidents associated.

Delayed sleep phase disorder (DSPD) is defined as a significant retard of >2 hours in sleep onset to the time socially adequate, usually with diurnal sleepiness (see Table 1).2 The etiology is related to factors such as the expression of PER 1, PER 3, ARTL2, and CLOCK genes that modify the chronotype in hereditary way and can be present in entire families.Reference Hida, Kitamura and Katayose3, Reference Patke, Murphy and Onat4 Alterations increase the risk of mental illnesses,Reference Ebisawa, Uchiyama and Kajimura5 and contribute to a deficit of melatonin at the beginning of the night.Reference Aoki, Ozeki and Yamada6 In addition, some environmental factors have been related to DSPD, including work or school schedules and a high exposure to artificial light at night.Reference Uchiyama, Okawa and Shibui7

Table 1. Criteria for the Diagnosis of DSPD2

Abbreviation: DSPD, delayed sleep phase disorder.

The main complaint reported by patients with DSPD is a delay in their sleep schedule compared to what is socially accepted (see Figures 1 and 2), increased sleep latency, shortened subjective sleep time, and daytime sleepiness, and is also associated with being single, financial difficulties, parents divorced, obesity and sedentarism.Reference Sivertsen, Harvey, Gradisar, Pallesen and Hysing8 It has also been linked to the practice of home schooling and home office, such as what happened during the coronavirus pandemic (COVID-19).

Figure 1. Typical hypnogram of delayed sleep phase syndrome showing sleep onset until 2 a.m., causing the sleep period extend beyond 9 hours in the morning. In horizontal plane time in hours, in vertical column behavioral functional states: N1, non-REM sleep stage 1 (light sleep); N2, non-REM sleep stage 2 (light sleep); N3, non-REM sleep stage 3 (deep sleep); R, rapid eye movements (REM) sleep; W, wake.

Figure 2. Typical hypnogram of the sleep-wake cycle of a healthy subject, showing brief sleep latency after 23.00 hours, normal distribution of the sleep states, and some brief awakening through the night. In horizontal plane time in hours, in vertical column behavioral functional states: N1, non-REM sleep stage 1 (light sleep); N2, non-REM sleep stage 2 (light sleep); N3, non-REM sleep stage 3 (deep sleep); R, rapid eye movements (REM) sleep; W, wake.

DSPD has been related to some comorbidities such as cystic fibrosis,Reference Jensen, Jones, Kartsonaki, Packer, Adler and Liou9 breast cancer,Reference Ancoli-Israel, Liu and Marler10 diabetes, and cardiovascular diseases.Reference Marcheva, Ramsey and Buhr11 It has a comorbidity with other sleep disorders, such as insomnia and obstructive sleep apnea.

Evaluation and diagnosis of DSPD

Diagnosis of DSPD can be carried out by identifying sleep habits, bedtimes, and waking times (comparing days off with respect to school or work days). Objective diagnosis is carried out by actigraphy and can be complemented with sleep diaries and clinical interviews,2 salivary melatonin,Reference Bonmati-Carrion, Middleton, Revell, Skene, Rol and Madrid12 and peripheral white blood cell transcriptome of melatonin.Reference Laing, Möller-Levet, Poh, Santhi, Archer and Dijk13

Epidemiology of DSPD

Prevalence of DSPD is difficult to estimate because of the different definitions of the problem, different diagnostic criteria, and disparity of measurements. Before the COVID-19 pandemic, in a study in Norway, DSPD reached a prevalence of 0.17% in the general population, with a prevalence of 8.9% in patients with an evening chronotype.Reference Sivertsen, Pallesen, Stormark, Boe, Lundervold and Hysing14

DSPD is frequent in adolescents, studies from Norway and Australia showed a prevalence of 8.4% and 1.1%, respectively,Reference Saxvig, Pallesen, Wilhelmsen-Langeland, Molde and Bjorvatn15, Reference Lovato, Gradisar, Short, Dohnt and Micic16 with a higher percentage in girls than boys (3.7% and 2.7%, respectively). Among the adult population, DSPD is inversely associated with age, students aged 18 to 22 years had a prevalence of 3.6% compared to 2.0% in students aged 29 to 35 years.Reference Sivertsen, Pallesen, Stormark, Boe, Lundervold and Hysing14

The COVID-19 outbreak

The social restrictions that were implemented in response to the COVID-19 pandemic, changed lifestyles in society, work, school, and family, which lead to symptoms of sleep disorders. As an initial effort, the International COVID-19 Sleep Study aims to explore the effects of COVID-19 pandemic on various aspects of sleep and circadian rhythms.Reference Partinen, Bjorvatn and Holzinger17

Objective

The aim of this review was to search for the relationship between DSPD and COVID-19 during the pandemic, and its mental health and metabolic implications.

Operational definitions

For the purpose of this review, the DSM-5 definition criteria for Generalized Anxiety Disorder or Anxiety were as follows: excessive anxiety and worry (apprehensive expectation), difficulty to control the worry, association to restlessness, fatigue, difficulty for concentration, irritability, muscle tension, and sleep disturbance.18 For major depressive disorder (MDD) or depression, criteria of DSM-5 were as follows: depressed mood, loss of interest/pleasure, weight loss or gain, insomnia or hypersomnia, psychomotor agitation or retardation, fatigue, feeling worthless or excessive/inappropriate guilt, decreased concentration, thoughts of death/suicide, and others.18

Overweight and obesity were defined as disorders marked by an abnormally high, unhealthy amount of body fat. (ICD-10).19 Metabolic syndrome was met using the following criteria: central obesity with a waist circumference >80 cm in females or >90 cm in males, hypertriglyceridemia >150 mg/dL, high-density lipids <50 mg/dL in females or < 40 mg/dL in males, type II diabetes mellitus (DM), family antecedent of DM, gestational DM, or clinical evidence of insulin resistance, with acanthosis nigricans, nonalcoholic fatty liver disease, or fasting glycemia >110 mg/dL (ICD-10).19 DM was defined as a group of metabolic diseases characterized by chronic hyperglycemia resulting from deficits in insulin secretion, insulin action, or both (ICD-10).19

Method

Articles addressing “DSPD” and “COVID-19” from scientific journals were identified searching for its mental and metabolic consequences. Search was performed in scientific journals. Articles were selected in 3 phases: by title, by abstract, and full text, and were discussed among authors and discrepancies were commented until consensus was reached. The systematic review was performed in PubMed and Google Scholar. In Pubmed, the search with DSPD descriptor found 10 039 articles, whereas 10 articles associated with COVID-19 were discovered. In Scholar Google, search with DSPD descriptor disclosed 40 700 articles, whereas 27 articles associated with COVID-19 were found. A critical narrative review of the DSPD and COVID-19 relationship in mental and metabolic topics was performed.

Results

Sleep and COVID-19 pandemic

It has been reported that sleep onset, offset, and mid-time were delayed on work days but not on free days. Sleep duration was increased on work days, and social jet lag was reduced during the lockdown.Reference Tahara, Shinto and Inoue20 Studies reported that participants slept longer and later during lockdown weekdays and exhibited lower levels of social jet lag noting that while this seems to be an overall improvement of sleep conditions, chronotype was also delayed under lockdown.Reference Leone, Sigman and Golombek21

In an online study, Bottary et alReference Bottary, Fields, Kensinger and Cunningham22 during the first wave of COVID-19 found data suggesting DSPD reduced jet-lag and social sleep restriction. Similarly, with an online survey it was found a pronounced shift toward later sleep combined with an increase in sleep duration, these changes were not more pronounced in adolescents than in young adults and seemed to occur mostly during weekdays. Teenagers also report an improvement in daytime sleepiness and subjective sleep quality, while young adults reported an increase in sleep difficulties associated with sleep onset, nocturnal and early morning awakenings, and nightmares.Reference Ramos-Socarras, Potvin and Forest23

Mental health and its relationship with CRSD and DSPD

The COVID-19 pandemic and the confinement have produced significant stress, anxiety, and worries for fear of being infected, job loss, financial problems, and uncertainty about the future.Reference Morin, Carrier, Bastien and Godbout24 In India, we found symptoms of depression and stress, moderate levels of anxiety among males and females, and elevated levels of stress, anxiety, and depression among students and healthcare professionals.Reference Rehman, Shahnawaz and Khan25 Examining the effects of different forms and levels of restrictions on anxiety and depression, it was found that stronger lockdown restrictions, results in reduction of social contacts, perceived changes in lifestyle associated with 31.1% of increase in study of participants exceeding the cutoff score for a diagnosis of depression, 21.2% exceeding the cutoff for anxiety, and 13.1% having had fear.Reference Benke, Autenrieth, Asselmann and Pané-Farré26

Evidence of relationship between circadian rhythm disorders and mood disturbances, as sleep has been linked to emotional regulation.Reference Palmer and Alfano27 According to the DSM 5,18 MDD is characterized by alterations in mood, sadness, or irritability that is accompanied by at least one of the following alterations: sleep cycle, sexual desire, appetite, anhedonia, slowing of speech or actions, crying, and suicidal thoughts. It has also been described that depressive disorders are associated with various neurobiological alterations like hyperactivity of the hypothalamic-pituitary-adrenal axis, altered neuroplasticity, and altered circadian rhythms.Reference Fang, Tu, Sheng and Shao28 Sleep disturbance is the most prominent symptom in depressive patients, leading to the hypothesis that sleep problems are not an epiphenomenon of depression, but rather a predictive symptom.Reference Fang, Tu, Sheng and Shao28 Sleep architecture in MDD includes short rapid eye movement sleep latency (REM latency), increased REM sleep, and reduced slow waves sleep; evidencing strong relationship between sleep and depression.Reference Vadnie and McClung29 Considering the relationship between circadian rhythm disruption and the pathophysiology of depression, it has been hypothesized that pharmacological and nonpharmacological strategies affect circadian rhythms could lead an improvement in depressive symptoms.Reference Satyanarayanan, Su, Lin and Su30

Recent discovery of new antidepressant melatonergic substances may improve depression symptoms. That is, it has been evaluated whether 25 to 50 mg of agomelatine and psychoeducation are associated with the circadian realignment in young people with depression. After the intervention, depressive symptoms significantly reduced the timing of dim light melatonin onset (DLMO), shifted 3.6 hours earlier, sleep onset was shifted 28 minutes earlier, and total sleep time increased 24 minutes. Authors reported a strong correlation between relative improvements in depression severity and degree of shift in DMLO.Reference Robillard, Carpenter, Feilds, Hermens, White and Naismith31

It has been proposed that stress-induced perturbation of the serotonin system that disrupts circadian processes and increases susceptibility to depression.Reference Daut and Fonken32 This could explain in part, the relationship between circadian rhythm disorders and mood disturbances.

Anxiety disorders have also been related to DSPD. For example, catastrophic thinking is considered symptom of anxiety, and patients with DSPD are frequently concerned about their ability to function academically, followed by the effect of poor sleep on their ability to attend school, and consequences from their peers or teachers.Reference Danielsson, Markström, Broman, von Knorring and Jansson-Fröjmark33 Some individuals only suffer a delayed sleep phase (DSP), while others fulfill the criteria for the diagnosis of DSPD, obtaining higher frequency of a psychiatric symptom, worry, rumination, and elevated levels of anxiety.Reference Danielsson, Markström, Broman, von Knorring and Jansson-Fröjmark33

COVID-19 caused a greater predisposition of patients to develop of CRSD, including a 1.5-fold increase in DSPD. CRSD were associated with increased trait and anxiety state mediated by the neurotropic nature of SARS-CoV-2 and the quarantine associated with the COVID-19 pandemic.Reference Boiko, Skrypnikov, Shkodina, Hasan, Ashraf and Rahman34

As for MDD, agomelatine (a melatonergic MT1 and MT2 receptor agonist) has been used as a pharmacotherapy in anxiety disorders, for example, in patients with obsessive-compulsive disorder (OCD). A literature review showed that 7/10 patients reported sleep and/or circadian disruptions before the treatment, and they experienced a 46% to 90% reduction in OCD symptoms.Reference Coles and Goodman35

Metabolic consequences of DSPD

Obesity, type 2 DM, cardiovascular diseases, hypertension, and dyslipidaemias are strongly related to sleep disorders and complicate severely COVID-19. Effect of DSPD on metabolism remains insufficiently studied. We could infer that DSP have similar disturbances to those reported under circadian misalignment (eg, social jetlag, shift work disorder) or sleep restriction.

Although subjects with DSPD are typically unable to fall asleep before 2 a.m., they are not always able to sleep late the next day to complete the required 8 hours of sleep. Several studies have demonstrated that sleep restriction (<7-6 hours/night of sleep) is associated with metabolic impairment. A study performed on 1024 volunteers described that those with short sleep had lower circulating leptin levels and higher body mass index.Reference Taheri, Lin, Austin, Young and Mignot36 Accumulated evidence indicates that sleep loss is associated with increased hunger and preference of high-calorie diet.Reference Nedeltcheva, Kessler, Imperial and Penev37 These alterations have been corroborated in animal models.Reference Forcina-Martins, Soares-Marques, Tufik and D’Almeida38

Sleep restriction is a risk factor for glucose intolerance and insulin resistance, and is an important components in development of type 2 diabetes.Reference Spiegel, Knutson, Leproult, Tasali and Van Cauter39 In healthy young men, 8 days of sleep restriction (4 hours time in bed/night) decrease insulin sensitivity and lead to glucose intolerance.Reference Buxton, Pavlova, Reid, Wang, Simonson and Adler40 Another study revealed that 2 nights of restricted sleep (2:45-07:00) in unmedicated adequate-weight men also led to glucose intolerance by reduced insulin sensitivity.Reference Schmid, Hallschmid and Jauch-Chara41 Sleep restriction during a single night induced glucose intolerance and decrease insulin sensitivity (sleep allowed from 1:00 to 5:00),Reference Sweeney, Peart, Kyza, Harkes, Ellis and Walshe42 and increased insulin levels (sleep allowed from 03:00 to 07:00).Reference Wilms, Chamorro and Hallschmid43

The circadian component of sleep regulation is crucial in the development of metabolic disturbances, mainly in glucose control. Thus, sleep loss decreases insulin sensitivity independent of the timing of sleep restriction. Late-night sleep loss impairs the physiological rise of cortisol, which increases after glucose intake, this could induce insulin resistance via cortisol alteration.Reference Wilms, Chamorro and Hallschmid43

Recently, the role of the suprachiasmatic nucleus in maintaining lower glucose levels during the resting phase has been described.Reference Rodríguez-Cortés, Hurtado-Alvarado, Martínez-Gómez, León-Mercado, Prager-Khoutorsky and Buijs44 Thus, circadian misalignment could be one of the pathways by which social jetlag or shift work are associated with glucose impairment and why resynchronizing the circadian pattern of eating is able to reduce the effects of those conditions on metabolism.Reference Toyoura, Miike, Tajima, Matsuzawa and Konishi45

Treatment of DSPD

Behavioral therapy

Cognitive-behavioral therapy for insomnia such as bedtime restriction, stimulus control, cognitive restructuration, and relaxation could be integrated into the treatment of DSPD.Reference Jansson-Fröjmark, Danielsson, Markström and Broman46 DSPD may require behavioral therapy to modify some habits that may perpetuate the disorder and maintain good therapeutic results, as well as to break dysfunctional beliefs. Cognitive behavioral treatment for insomnia (CBT-I) is usually used as an adjuvant, such as phototherapy, or pharmacotherapy. There is no evidence on the effectiveness of CBT-I as the single therapy in DSPD.Reference Richardson, Micic, Cain, Bartel, Maddock and Gradisar47

Chronotherapy

It is theorized that individuals with DSPD can retrain certain rhythms. To shift their circadian dysfunction, they will need to progressively delay their sleeping time until they reach the desired sleep-wake schedule (usually 3 hours every 2 days), in accordance with good sleep hygiene, adjusting social events, diet, and exercise.Reference Alvarez, Dahlitz, Vignau and Parkes48 Due to the lack of controlled-randomized studies, the evidence for this therapy is limited to case series. Flexible schedule is required since it may interrupt daytime activities, such as school, work, and so forth.

Phototherapy

Off-time light exposure suppresses the nocturnal release of melatonin. Evening light suppression is recommended in patients with DSPD by minimizing or dimming indoor light. Blue light filtering or amber lenses can be used from sunset to bedtime.Reference Esaki, Kitajima and Ito49 Exposure to morning light can be beneficial promoting a greater increase in phase advancement in conjunction with evening light withdrawal and the use of melatonin. Preferably, natural light is used after awakening instructing the patient to go outside or sit behind a bright window for 30 minutes. In winter, light therapy can be used, the most studied treatment is a light with a brightness of 10 000 lux, indicated for 30 minutes after awakening at a distance of 30 to 50 cm. Combined therapy has shown greater results than one method alone.

Melatonin

The American Academy of Sleep Medicine suggests that children and adults with DSPD should be prescribed melatonin at a time between 7 and 9 pm. Melatonin has a good safety profile with few adverse effects, which include headache and nasopharyngitis. The drug reprogramming the internal circadian cycle and promoting sleep.Reference Aoki, Ozeki and Yamada6 Studies have shown effectiveness in phase advancement at doses of 0.3 to 5 mg of melatonin. It appears that time of administration has a greater impact than dose. A 0.5 mg of melatonin 10 to 12 hours before the midpoint of sleep achieves the greatest amount of phase advance.Reference Chua, Hauet-Richer, Swedrowska, Ingham, Tomlin and Forbes50 Also, it has been reported that a prescription of 1, 2, or 4 mg of ramelteon or ramelteon and 15 mg of suvorexant improve symptoms of DSPD.Reference Takeshima, Shimizu, Ishikawa and Kanbayashi51

Discussion

Main findings

One of the main consequences of the COVID-19 pandemic is the DSPD, associated to insomnia, mental health alterations such as depression and anxiety, and metabolic alterations such as insulin resistance and type 2 DM, as was set in evidence in this review. During the pandemic, symptoms of sleep disorders, mental and metabolic illness increased in prevalence. These have important interactions between alterations and have several implications in the pandemic context.

Clinical implications

Evidence of close relationship between depression-anxiety and CRSD should be considered, since sleep disorders have been associated with increased risk of depression. Thus, it is important to improve sleep quality in patients with symptoms of DSPD during pandemic to reduce the risk of mental illness.

Furthermore, it has been identified that sleep deprivation and CRSD are risk factors for metabolic disorders such as decreased sensitivity to insulin; these conditions are risk factors for type 2 diabetes. Prevalence of type 2 diabetes in 2019 in a global age-standardized prevalence rate, stood at 5282.8/100000 in adult population in one study that search the spatial-temporal patterns of incidence, mortality, and attributable risk factors from 1990 to 2019 among 21 world regions.Reference Nanda, Sharma, Mubarik, Aashima and Zhang52 In countries with a high prevalence of diabetes such as Mexico, the prevalence of type 2 diabetes is 10.3% for adult women and 8.4% for adult men.53 However, it is possible that in the period after the COVID-19 pandemic, there will be an increase in the prevalence of type 2 DM, in part as a consequence of the increased prevalence of sleep disorders, such as DSPD. This hypothesis deserves future research and follow-up. It is therefore essential to implement public health policies aimed at improving sleep quality in order to reduce their possible consequences on mental and metabolic health.

New hypothesis

Catastrophic information and isolation during the pandemic of COVID-19 set individuals with an increased level of anxiety. Along with the continuity of the outbreak and the apparition of new variants of the virus and successive waves of the disease, anxiety becomes a chronic condition that maintains individuals expectant and alert, increasing levels of excitation that result in DSPD. Increased levels of chronic anxiety may result in augmentation in circulation levels of cortisol and adrenaline that alter the carbohydrates metabolism, that in a long-term period may result in insulin resistance, metabolic syndrome, and diabetes type 2.

Study and close follow-up in individuals with DSPD to determine the exact time when sleep and metabolic changes become pathologic, deserve more research in order to know the natural history of the alteration, and give subjects an early treatment and generate preventive measures of prevention.

Strengths and limitation

The main strength of the systematic review is the novelty of the topic, addressing the need for identification, diagnosis, and therapy of DSPD during the COVID-19 pandemic. Previously, symptoms of DSPD had been strongly neglected or had not received enough attention.

Weaknesses in our review were articles included were mostly series of few participants. This was becasue the topic is new and there is no many original articles or systematic observations related to the topic. In the reviewed articles, there was little additional information about other pathological conditions, medications, sleep habits, or comorbid disorders.

We highlight the need of improve methodology to increase knowledge about the occurrence of DSPD in subjects during the COVID-19 pandemic, which would be very useful in determining the possible weight of each confounding factors. According to our observations, in the clinical evaluation of subjects with DSPD, it is important to ask about other sleep disorders beyond insomnia, apnea, and periodic limb movements, which cause sleep deprivation and are also contributors factors of DSPD.

Despite these limitations, literature reviewed showed that DSPD could be frequent in subjects during the pandemic of COVID-19. However, our study design did not allow us to conclude if DSPD is significantly more frequent during COVID-19 pandemic. But suggest that the relationship between different factors such as changes in neural systems functioning, comorbid sleep disorders, medication, stress, carbohydrates metabolic control, and antecedents of DSPD in childhood or adolescence are essential to the understanding of the problematic of DSPD in individuals during the COVID-19 pandemic.

Conclusions

During COVID-19 pandemic many subjects change their habits and suffering of DSPD, this condition set subjects to suffering of more mental health alterations, such as anxiety and depression, and of metabolic disorders, such as hyperlypidemia, insulin resistance, and type 2 DM. Thus, it is necessary to design projects for early identification and treatment of DSPD during and after COVID-19 pandemic.

Financial Support

The study has no external funding than participant institutions.

Author Contributions

Conceptualization: U.J.-C.; Data curation: U.J.-C., N.B., H.B.Á.-G., G.M.-A., A.B.-M., R.S.-M., A.P., H.A.M.-A.; Formal analysis: U.J.-C., N.B., H.B.Á.-G., G.M.-A., A.B.-M., R.S.-M., A.P., H.A.M.-A.; Investigation: U.J.-C., N.B., H.B.Á.-G., G.M.-A., A.B.-M., R.S.-M., H.A.M.-A.; Methodology: U.J.-C., N.B., H.B.Á.-G., R.S.-M., A.P., H.A.M.-A.; Validation: U.J.-C.; Writing—original draft: U.J.-C., N.B., H.B.Á.-G., G.M.-A., A.B.-M., R.S.-M., A.P., H.A.M.-A.; Writing—review and editing: U.J.-C., A.P.

Disclosures

The authors do not have any conflicts of interest.

References

Walker, WH, Walton, JC, DeVries, AC, Nelson, RJ. Circadian rhythm disruption and mental health. Transl Psychiatry. 2020;10(1):28.CrossRefGoogle ScholarPubMed
American Academy Sleep Medicine. International Classification of Sleep Disorders. 3rd ed. Darien, IL: American Academy of Sleep Medicine; 2014.Google Scholar
Hida, A, Kitamura, S, Katayose, Y, et al. Screening of clock gene polymorphisms demonstrates association of a PER3 polymorphism with morningness-eveningness preference and circadian rhythm sleep disorder. Sci Rep. 2014;4:6309.CrossRefGoogle ScholarPubMed
Patke, A, Murphy, PJ, Onat, OE, et al. Mutation of the human circadian clock gene CRY1 in familial delayed sleep phase disorder. Cell. 2017;169(2):203215.CrossRefGoogle ScholarPubMed
Ebisawa, T, Uchiyama, M, Kajimura, N, et al. Association of structural polymorphisms in the human period 3 gene with delayed sleep phase syndrome. EMBO Rep. 2001;2(4):342346.CrossRefGoogle ScholarPubMed
Aoki, H, Ozeki, Y, Yamada, N. Hypersensitivity of melatonin suppression in response to light in patients with delayed sleep phase syndrome. Chronobiol Int. 2001;18(2):263271.CrossRefGoogle ScholarPubMed
Uchiyama, M, Okawa, M, Shibui, K, et al. Poor compensatory function for sleep loss as a pathogenic factor in patients with delayed sleep phase syndrome. Sleep. 2000;23(4):553558.CrossRefGoogle Scholar
Sivertsen, B, Harvey, AG, Gradisar, M, Pallesen, S, Hysing, M. Delayed sleep-wake phase disorder in young adults: prevalence and correlates from a national survey of Norwegian university students. Sleep Med. 2021;77:184191.CrossRefGoogle ScholarPubMed
Jensen, JL, Jones, CR, Kartsonaki, C, Packer, KA, Adler, FR, Liou, TG. Sleep phase delay in cystic fibrosis: a potential new manifestation of cystic fibrosis transmembrane regulator dysfunction. Chest. 2014;152(2):386393.CrossRefGoogle Scholar
Ancoli-Israel, S, Liu, L, Marler, MR, et al. Fatigue, sleep, and circadian rhythms prior to chemotherapy for breast cancer. Support Care Cancer. 2006;14(3):201219.CrossRefGoogle ScholarPubMed
Marcheva, B, Ramsey, KM, Buhr, ED, et al. Disruption of the clock components CLOCK and BMAL1 leads to hypoinsulinaemia and diabetes. Nature. 2010;466(7306):627631.CrossRefGoogle ScholarPubMed
Bonmati-Carrion, MA, Middleton, B, Revell, V, Skene, DJ, Rol, MA, Madrid, MA. Circadian phase assessment by ambulatory monitoring in humans: correlation with dim light melatonin onset. Chronobiol Int. 2014;31(1):3751.CrossRefGoogle ScholarPubMed
Laing, EE, Möller-Levet, CS, Poh, N, Santhi, N, Archer, SN, Dijk, DJ. Blood transcriptome based biomarkers for human circadian phase. Elife. 2017;6:e20214.CrossRefGoogle ScholarPubMed
Sivertsen, B, Pallesen, S, Stormark, KM, Boe, T, Lundervold, A, Hysing, M. Delayed sleep phase syndrome in adolescents: prevalence and correlates in a large population based study. BMC Public Health. 2013;13:1163.CrossRefGoogle Scholar
Saxvig, IW, Pallesen, S, Wilhelmsen-Langeland, A, Molde, H, Bjorvatn, B. Prevalence and correlates of delayed sleep phase in high school students. Sleep Med. 2012;13(2):193199.CrossRefGoogle ScholarPubMed
Lovato, N, Gradisar, M, Short, M, Dohnt, H, Micic, G. Delayed sleep phase disorder in an Australian school-based sample of adolescents. J Clin Sleep Med. 2013;9(9):939944.CrossRefGoogle Scholar
Partinen, M, Bjorvatn, B, Holzinger, B, et al. Sleep and circadian problems during the coronavirus disease 2019 (COVID-19) pandemic: the International COVID-19 Sleep Study (ICOSS). J Sleep Res. 2021;30(1):e13206.CrossRefGoogle ScholarPubMed
American Psychiatric Association. Diagnostic and Statistical Manual of Mental Disorders. 5th ed. Arlington, VA: American Psychiatric Association; 2013.Google Scholar
World Health Organization. ICD-10 International Classification of Diseases. Geneva: WHO; 1993.Google Scholar
Tahara, Y, Shinto, T, Inoue, K, et al. Changes in sleep phase and body weight of mobile health app users during COVID-19 mild lockdown in Japan. Int J Obes (Lond). 2021;45(10):22772280.CrossRefGoogle ScholarPubMed
Leone, MJ, Sigman, M, Golombek, DA. Effects of lockdown on human sleep and chronotype during the COVID-19 pandemic. Curr Biol. 2021;30(16):R930R931.CrossRefGoogle Scholar
Bottary, R, Fields, EC, Kensinger, EA, Cunningham, TJ. Age and chronotype influenced sleep timing changes during the first wave of the COVID-19 pandemic. J Sleep Res. 2022;31(2):e13495.CrossRefGoogle ScholarPubMed
Ramos-Socarras, L, Potvin, J, Forest, G. COVID-19 and sleep patterns in adolescents and young adults. Sleep Med. 2021;83:2633.CrossRefGoogle ScholarPubMed
Morin, CM, Carrier, J, Bastien, C, Godbout, R, Canadian Sleep and Circadian Network. Sleep and circadian rhythm in response to the COVID-19 pandemic. Can J Public Health. 2020;111(5):654657.CrossRefGoogle ScholarPubMed
Rehman, U, Shahnawaz, MG, Khan, NH, et al. Depression, anxiety and stress among Indians in times of Covid-19 lockdown. Community Ment Health J. 2021;57(1):4248.CrossRefGoogle ScholarPubMed
Benke, C, Autenrieth, LK, Asselmann, E, Pané-Farré, CA. Lockdown, quarantine measures, and social distancing: Associations with depression, anxiety and distress at the beginning of the COVID-19 pandemic among adults from Germany. Psychiatry Res. 2020;293:113462.CrossRefGoogle ScholarPubMed
Palmer, CA, Alfano, CA. Anxiety modifies the emotional effects of sleep loss. Curr Opin Psychol. 2020;34:100104.CrossRefGoogle ScholarPubMed
Fang, H, Tu, S, Sheng, J, Shao, A. Depression in sleep disturbance: a review on a bidirectional relationship, mechanisms and treatment. J Cell Mol Med. 2019;23(4):23242332.CrossRefGoogle ScholarPubMed
Vadnie, CA, McClung, CA. Circadian rhythm disturbances in mood disorders: insights into the role of the suprachiasmatic nucleus. Neural Plast. 2017;2017:1504507.CrossRefGoogle ScholarPubMed
Satyanarayanan, SK, Su, H, Lin, YW, Su, KP. Circadian rhythm and melatonin in the treatment of depression. Curr Pharm Des. 2018;24(22):25492555.CrossRefGoogle ScholarPubMed
Robillard, R, Carpenter, JS, Feilds, KL, Hermens, DF, White, D, Naismith, SL. Parallel changes in mood and melatonin rhythm following an adjunctive multimodal chronobiological intervention with agomelatine in people with depression: a proof of concept open label study. Front Psychiatry. 2018;9:624.CrossRefGoogle ScholarPubMed
Daut, RA, Fonken, LK. Circadian regulation of depression: a role for serotonin. Front Neuroendocrinol. 2019;54:100746.CrossRefGoogle ScholarPubMed
Danielsson, K, Markström, A, Broman, JE, von Knorring, L, Jansson-Fröjmark, M. Delayed sleep phase disorder in a Swedish cohort of adolescents and young adults: prevalence and associated factors. Chronobiol Int. 2016;33(10):13311339.CrossRefGoogle Scholar
Boiko, DI, Skrypnikov, AM, Shkodina, AD, Hasan, MM, Ashraf, GM, Rahman, MH. Circadian rhythm disorder and anxiety as mental health complications in post-COVID-19. Environ Sci Pollut Res Int. 2022;29(19):2806228069.CrossRefGoogle ScholarPubMed
Coles, ME, Goodman, MH. A systematic review of case studies testing a melatonergic agonist/5HT2c antagonist for individuals with obsessive compulsive disorder. J Anxiety Disord. 2020;69:102173.CrossRefGoogle ScholarPubMed
Taheri, S, Lin, L, Austin, D, Young, T, Mignot, E. Short sleep duration is associated with reduced leptin, elevated ghrelin, and increased body mass index. PLoS Med. 2004;1(3):e62.CrossRefGoogle ScholarPubMed
Nedeltcheva, AV, Kessler, L, Imperial, J, Penev, PD. Exposure to recurrent sleep restriction in the setting of high caloric intake and physical inactivity results in increased insulin resistance and reduced glucose tolerance. J Clin Endocrinol Metab. 2004;94(9):32423250.CrossRefGoogle Scholar
Forcina-Martins, PJ, Soares-Marques, MS, Tufik, S, D’Almeida, V. Orexin activation precedes increased NPY expression, hyperphagia, and metabolic changes in response to sleep deprivation. Am J Physiol Endocrinol Metab. 2010;298(3):E726E734.CrossRefGoogle Scholar
Spiegel, K, Knutson, K, Leproult, R, Tasali, E, Van Cauter, E. Sleep loss: a novel risk factor for insulin resistance and Type 2 diabetes. J Appl Physiol. 2005;99(5):20082019.CrossRefGoogle Scholar
Buxton, OM, Pavlova, M, Reid, EW, Wang, W, Simonson, DC, Adler, GK. Sleep restriction for 1 week reduces insulin sensitivity in healthy men. Diabetes. 2010;59(9):21262133.CrossRefGoogle ScholarPubMed
Schmid, SM, Hallschmid, M, Jauch-Chara, K, et al. Disturbed glucoregulatory response to food intake after moderate sleep restriction. Sleep. 2011;34(3):371377.CrossRefGoogle ScholarPubMed
Sweeney, EL, Peart, DJ, Kyza, I, Harkes, T, Ellis, JG, Walshe, IH. Impaired insulin profiles following a single night of sleep restriction: the impact of acute sprint interval exercise. Int J Sport Nutr Exerc Metab. 2010;30(2):139144.CrossRefGoogle Scholar
Wilms, B, Chamorro, R, Hallschmid, M, et al. Timing modulates the effect of sleep loss on glucose homeostasis. J Clin Endocrinol Metab. 2019;104(7):28012808.CrossRefGoogle ScholarPubMed
Rodríguez-Cortés, B, Hurtado-Alvarado, G, Martínez-Gómez, R, León-Mercado, LA, Prager-Khoutorsky, M, Buijs, RM. Suprachiasmatic nucleus-mediated glucose entry into the arcuate nucleus determines the daily rhythm in blood glycemia. Curr Biol. 2022;32(4):796805.CrossRefGoogle ScholarPubMed
Toyoura, M, Miike, T, Tajima, S, Matsuzawa, S, Konishi, Y. Inadequate sleep as a contributor to impaired glucose tolerance: a cross-sectional study in children, adolescents, and young adults with circadian rhythm sleep-wake disorder. Pediatr Diabetes. 2020;21(4):557564.CrossRefGoogle Scholar
Jansson-Fröjmark, M, Danielsson, K, Markström, A, Broman, JE. Developing a cognitive behavioral therapy manual for delayed sleep-wake phase disorder. Cogn Behav Ther. 2016;45(6):518532.CrossRefGoogle ScholarPubMed
Richardson, C, Micic, G, Cain, N, Bartel, K, Maddock, B, Gradisar, M. Cognitive performance in adolescents with delayed sleep-wake phase disorder: treatment effects and a comparison with good sleepers. J Adolesc. 2018;65:7284.CrossRefGoogle Scholar
Alvarez, B, Dahlitz, MJ, Vignau, J, Parkes, JD. The delayed sleep phase syndrome: clinical and investigative findings in 14 subjects. J Neurol Neurosurg Psychiatry. 1992;55(8):665670.CrossRefGoogle ScholarPubMed
Esaki, Y, Kitajima, T, Ito, Y, et al. Wearing blue light-blocking glasses in the evening advances circadian rhythms in the patients with delayed sleep phase disorder: an open-label trial. Chronobiol Int. 2016;33(8):10371044.CrossRefGoogle Scholar
Chua, H, Hauet-Richer, N, Swedrowska, M, Ingham, S, Tomlin, S, Forbes, B. Dissolution of intact, divided and crushed circadin tablets: prolonged vs. immediate release of melatonin. Pharmaceutics. 2016;8(1):2.CrossRefGoogle ScholarPubMed
Takeshima, M, Shimizu, T, Ishikawa, H, Kanbayashi, T. Ramelteon for delayed sleep-wake phase disorder: a case report. Clin Psychopharmacol Neurosci. 2020;18(1):167169.CrossRefGoogle ScholarPubMed
Nanda, M, Sharma, R, Mubarik, S, Aashima, A, Zhang, K. Type-2 diabetes mellitus (T2DM): spatial-temporal patterns of incidence, mortality and attributable risk factors from 1990 to 2019 among 21 world regions. Endocrine. 2022;77(3):444454.CrossRefGoogle ScholarPubMed
National Institute of Public Health [México]. National Survey of Health and Nutrition at the Middle of the Road ENSANUT-MC [in Spanish]. https://ensanut.insp.mx/encuestas/ensanut2016/index.php. 2016. Accessed March 15, 2022. doi:10.1080/07420528.2016.1194289.CrossRefGoogle Scholar
Figure 0

Table 1. Criteria for the Diagnosis of DSPD2

Figure 1

Figure 1. Typical hypnogram of delayed sleep phase syndrome showing sleep onset until 2 a.m., causing the sleep period extend beyond 9 hours in the morning. In horizontal plane time in hours, in vertical column behavioral functional states: N1, non-REM sleep stage 1 (light sleep); N2, non-REM sleep stage 2 (light sleep); N3, non-REM sleep stage 3 (deep sleep); R, rapid eye movements (REM) sleep; W, wake.

Figure 2

Figure 2. Typical hypnogram of the sleep-wake cycle of a healthy subject, showing brief sleep latency after 23.00 hours, normal distribution of the sleep states, and some brief awakening through the night. In horizontal plane time in hours, in vertical column behavioral functional states: N1, non-REM sleep stage 1 (light sleep); N2, non-REM sleep stage 2 (light sleep); N3, non-REM sleep stage 3 (deep sleep); R, rapid eye movements (REM) sleep; W, wake.