The Biological Clock Influenced by Burnout, Hormonal Dysregulation and Circadian Misalignment: A Systematic Review

As indicated by the PRISMA flow diagram, a total of 32 studies were excluded following the eligibility assessment process. The reasons for exclusion were primarily methodological limitations, which affected the alignment of these studies with the physiological and endocrinological scope of the current systematic review. Specifically, studies were excluded if they did not incorporate hormonal biomarker analyses, consequently failing to provide measurable physiological correlations necessary for inclusion. Additionally, studies that exclusively emphasized psychological parameters without evaluating physiological markers were also excluded, as this review explicitly focused on hormonal dysregulation. Further exclusions resulted from insufficient sample sizes, as limited participant numbers compromised the reliability and general applicability of findings. Studies relying on secondary data (such as narrative reviews or theoretical analyses) and individual case studies were also excluded to ensure the robustness and empirical grounding of the synthesized evidence.

This thorough selection of literature ensured that only studies meeting strict methodological rigor and directly relevant to the physiological dimensions of burnout were included, thereby enhancing the validity and applicability of the review's conclusions.

The scope of the present analysis was to compare the previous studies with the inquiry that was conducted with the aim to investigate and forecast the prevalence and severity of burnout among healthcare professionals by examining it core dimensions such as emotional exhaustion, depersonalization, diminished personal accomplishment, but including also associated physical health symptoms. Additionally, the research sought to identify demographic and occupational factors potentially contributing to these outcomes. The study specifically targeted healthcare professionals employed in Romanian medical settings, including hospitals and outpatient clinics, and comprised physicians, nurses, and other clinical support personnel andillustrates the gender distribution of the respondents. Figure 2

Emphasizing both psychological and physiological dimensions, the report aimed to deepen the understanding of occupational burnout within the Romanian healthcare context and provide insights relevant to preventive interventions and clinical practice.

This analysis expands upon traditional burnout assessment frameworks by enhancing the Maslach Burnout Inventory by including targeted items assessing physical symptoms frequently reported among healthcare professionals experiencing chronic occupational stress. Particularly, additional questions focused on somatic complaints such as persistent headaches, musculoskeletal pain, and gastrointestinal disturbances were integrated to capture the physiological dimension of burnout broadly.

Recognizing the critical role occupational factors play in the development of burnout, this study also examined the impact of work schedule structures as shown inmainly night shifts and irregular work patterns which significantly influence circadian rhythm stability. Figure 3

The fixed schedule is determined by the 8 a.m.–4 p.m. or 9 a.m.–3 p.m. program, varying upon request. On-call shifts are determined by duty shifts and night shifts.

Previous literature consistently demonstrates that irregular shift patterns disrupt the physiological regulation of sleep–wake cycles and hormone secretion, especially melatonin and cortisol, exacerbating stress responses and contributing to both physical symptoms and overall burnout severity.

illustrates the prevalence of various physical symptoms—chest pain/palpitations, digestive issues, muscle pain, and frequent illnesses—reported by healthcare personnel. The 7-point response scale (where 1 = Never and 7 = Very Often) allows for a clear assessment of how frequently these symptoms occur among respondents. The data highlights that a significant proportion of participants experience these symptoms, particularly at lower to moderate frequencies. Figure 4

By incorporating these occupational and physiological dimensions, the study aims to provide an integrated perspective that advises the development of more effective preventive measures, workplace interventions, and clinical practices. Understanding the relationship between demanding work schedules and the manifestation of physical symptoms is essential in tailoring interventions that support the well-being of healthcare personnel exposed to high occupational stress.

In a separate exploratory component, we examined associations between self-reported stress-related symptoms and morning cortisol levels in a subsample of 26 healthcare professionals. Cortisol was collected once at 9 a.m.; therefore, this analysis does not represent a circadian or diurnal profile but a single-time-point snapshot of the physiological stress response. Individual cortisol rhythms differ substantially across people, and determining a true circadian pattern would require several equally spaced samples over a 24-h period and strict control of external Zeitgebers (time cues such as light exposure, food intake, and activity). Because only a single morning sample was collected, no baseline correction or normalization was applied; cortisol values are reported as raw, unadjusted concentrations intended solely for descriptive comparison within this exploratory analysis. As such, this component is explicitly described as preliminary and descriptive, intended only to illustrate potential physiological correlations of burnout within the broader context of the systematic review.

The examination made inprovides critical insights into the multidimensional environment of burnout, emphasizing notable associations between demographic, occupational, and physiological factors.

A particularly strong correlation (0.81) exists between burnout scores and the presence of physical symptoms, including cardiac manifestations (palpitations or chest pain), gastrointestinal disturbances (digestive problems), cephalic symptoms (headaches), musculoskeletal pain (particularly in the neck, shoulders, or back) and compromised immune function (frequent illnesses). These symptoms suggest that chronic occupational stress and burnout extend beyond psychological distress, translating into measurable physiological disturbances. These disturbances frequently result from persistent activation and dysregulation of stress-responsive neuroendocrine pathways, notably involving the hypothalamic–pituitary–adrenal axis and the sympathetic-adrenomedullary system. Chronic activation of these pathways results in sustained elevations in cortisol and catecholamines, triggering cardiovascular, gastrointestinal, musculoskeletal, and immune dysfunctions.

Furthermore, occupational scheduling emerges as an important variable influencing burnout. A clear positive correlation (0.26) was observed between irregular work schedules and burnout severity, emphasizing the destabilizing effect of on-call and rotating shifts. Conversely, regular schedules demonstrated a slight protective influence (−0.15), suggesting that circadian stability contributes to lower burnout scores. These findings reinforce the role of chronobiological disruption as a mediator between occupational demands and stress-related exhaustion.

shows the distribution of morning cortisol values obtained from 26 healthcare professionals with irregular work schedules and on-call duties. Because only a single morning sample was collected at 9 a.m., these data cannot be used to infer circadian or diurnal variation. The results therefore illustrate relative differences between participants rather than true rhythmic patterns. Individual cortisol secretion profiles vary substantially; consequently, this exploratory analysis should be interpreted as a preliminary indication of stress-related physiological activation rather than a characterization of circadian function. Figure 5

The analysis revealed that certain stress symptoms appear more closely linked to elevated cortisol levels, particularly palpitations, headaches, and muscle pain. Respondents experiencing frequent palpitations or chest pain exhibited a tendency toward higher cortisol levels, suggesting a connection between chronic stress and cardiovascular responses. Similarly, individuals reporting severe muscle pain or frequent headaches were more likely to have elevated cortisol, reinforcing the well-documented link between stress and musculoskeletal tension, as well as stress-induced headaches. On the contrary, the relationship between cortisol levels and digestive issues or frequent illnesses was less pronounced. While some respondents with high cortisol reported frequent digestive problems, the overall correlation was weaker, indicating that other factors may also contribute to gastrointestinal distress. Additionally, although chronic stress is known to impact immune function, no strong direct correlation emerged between cortisol levels and the frequency of illnesses, though individual cases suggest that prolonged occupational stress may still play a role.

These findings emphasize the physiological burden experienced by healthcare professionals exposed to irregular work schedules and on-call shifts. The observed associations between heightened cortisol levels and specific stress symptoms highlight the urgent need for targeted workplace interventions, including stress management programs and preventive health strategies, to support the well-being of professionals in high-stress environments.

Such disruption adversely affects melatonin production, a hormone centrally involved in the regulation of sleep–wake cycles and circadian homeostasis. Irregular shift patterns disturb the nocturnal secretion of melatonin, compromising restorative sleep, impairing cognitive and emotional resilience, and increasing susceptibility to both psychological and somatic manifestations of stress. This disruption is often exacerbated by irregular exposure to environmental cues such as light, meal timing, and physical activity patterns, leading to further hormonal dysregulation, metabolic disturbances, and heightened stress responsiveness.

In contrast, fixed scheduling exhibits a modest negative correlation with burnout (−0.15), suggesting a potential protective effect through maintenance of stable circadian alignment. A consistent work schedule promotes regular patterns of melatonin secretion, enhancing sleep quality and physiological recovery, thus potentially mitigating burnout severity. Regularity in occupational patterns not only stabilizes melatonin secretion but also facilitates optimal functioning of the endocrine system more broadly, including cortisol and other regulatory hormones. This circadian stability provides physiological resilience against the adverse effects of chronic occupational stress.

The obvious associations outlined in this table underscore the significance of integrating circadian biology and endocrine assessments within burnout evaluations. Recognizing the physiological bedrocks of burnout offers an essential foundation for implementing targeted clinical interventions, such as optimized shift scheduling, structured rest periods, melatonin supplementation, lifestyle modifications, and workplace policy reforms aimed at stabilizing circadian rhythms. Moreover, addressing these physiological disturbances can enhance clinical outcomes, reduce occupational stress levels, and significantly improve the overall well-being and health of healthcare professionals.

Our exploratory cortisol findings reflect morning stress reactivity rather than circadian dynamics, as only one sampling point was obtained. Hence, these results should be interpreted as indicative of physiological stress load, not of intrinsic circadian rhythmicity. The pattern observed nevertheless aligns with existing medical evidence demonstrating that hormonal dysregulation—particularly involving the hypothalamic–pituitary–adrenal (HPA) axis—plays a pivotal role in the pathophysiology of burnout. The strong correlations between burnout severity and physical symptoms emphasize that chronic occupational stress extends far beyond psychological distress, producing measurable physiological consequences. These somatic manifestations—such as cardiovascular irregularities (palpitations, chest pain), gastrointestinal dysfunction, headaches, musculoskeletal discomfort, and immune impairment—are consistent with stress-related HPA-axis activation described in prior studies [,].

Human field investigations rarely achieve complete control of Zeitgebers—external "time givers" such as light exposure, meal timing, and physical activity—that synchronize endogenous circadian rhythms to the 24-h day. Only constant-routine protocols can isolate intrinsic biological rhythms, minimizing such cues to reveal the internal phase and amplitude of circadian processes . Such control was beyond the scope of this exploratory design, which aimed instead to illustrate the biological plausibility of stress-related endocrine activation in healthcare professionals. Nevertheless, burnout cannot be fully understood without integrating the role of circadian disruption, particularly in professions where irregular work schedules and night shifts are pervasive. Our results, showing a moderate but meaningful positive correlation between burnout severity and on-call or night-shift schedules, align with prior evidence linking occupational scheduling to circadian misalignment and melatonin dysregulation [,,,]. Circadian misalignment disrupts melatonin secretion and impairs restorative sleep, thereby exacerbating emotional exhaustion, diminishing resilience, and aggravating physiological stress responses. Consistent with , exposure to light at atypical hours and irregular sleep–wake timing suppresses nocturnal melatonin and desynchronize biological rhythms, amplifying downstream metabolic and mood effects. On the contrary, our finding of a modest negative correlation between burnout and fixed work schedules supports the protective role of circadian stability. This protective effect is consistent with evidence that structured routines stabilize melatonin secretion and support physiological recovery, reducing vulnerability to stress-related endocrine disturbances [,,,].

The interplay between cortisol and melatonin represents a central mechanism in the chronobiology of burnout. Cortisol follows a diurnal pattern, peaking in the morning and decreasing throughout the day, while melatonin secretion peaks at night to promote restorative sleep. Chronic stress and irregular schedules disrupt these rhythms, resulting in both HPA axis dysregulation and suppression or desynchronization of melatonin secretion. These disruptions propagate downstream effects on metabolic health, immune regulation, and cardiovascular stability [,,,]. Nash's concept of Dysregulation of Mood, Energy, and Social Rhythms Syndrome (DYMERS) is particularly relevant, as it integrates the impact of circadian misalignment on both psychological functioning and biological homeostasis . This framework suggests that burnout cannot be adequately addressed without considering the synchrony—or lack thereof—between biological clocks and occupational demands.

The evidence also highlights the need to differentiate burnout from contested constructs such as "adrenal fatigue." As Cadegiani and Kater emphasized, there is insufficient empirical support for adrenal fatigue as a distinct entity; however, there is robust evidence of cortisol dysregulation associated with chronic stress and burnout . Our data support this nuanced perspective: while adrenal fatigue as a diagnostic label is unsubstantiated, the measurable alterations in cortisol secretion patterns observed in burnout represent real physiological changes with clinical implications. Similarly, studies by Jonsdottir and Sjörs Dahlman demonstrated immune suppression and systemic inflammation among burnout patients, highlighting that the syndrome is systemic, not limited to psychological exhaustion .

An additional contribution of our study is the integration of physical symptomatology into burnout assessment. The strong correlations we observed between burnout severity and somatic complaints (r = 0.81 for physical symptoms, r = 0.90 for emotional exhaustion) emphasize the psychosomatic character of occupational stress. These findings align with Ciobanu et al., who identified neuroendocrine alterations linked to immune dysfunction in burnout, reinforcing the need for multidimensional assessment tools that capture both psychological and physiological aspects of the syndrome .

The role of night-shift work and circadian misalignment therefore deserves particular attention. Prior literature shows that irregular shift patterns destabilize melatonin and cortisol rhythms, impairing sleep quality, cognitive functioning, and emotional stability [,,,]. Our findings confirm that irregular schedules significantly increase burnout severity, while fixed or regular schedules provide resilience by stabilizing circadian alignment. This has important implications for workplace policy: interventions that reduce night-shift frequency, increase schedule predictability, manage light exposure, and incorporate structured rest periods could act as protective chronobiological strategies against burnout [,,,].

Clinical strategies for managing burnout should therefore extend beyond traditional psychological interventions to include chronobiological approaches. Preliminary evidence suggests that melatonin supplementation may improve sleep initiation, stabilize circadian rhythms, and mitigate stress-induced physiological arousal; however, these findings remain tentative and require confirmation in larger controlled studies. Likewise, early findings indicate that adaptogenic herbs such as Rhodiola rosea and Withaniasomnifera (ashwagandha) may modulate cortisol secretion and enhance stress resilience, but current evidence is still limited and should be interpreted with caution [,]. When combined with organizational interventions—such as workload redistribution, resilience training, and optimized scheduling, these strategies may collectively offer a more comprehensive and biologically grounded approach to mitigating burnout risk.

Despite these insights, several limitations should be acknowledged. The heterogeneity of included studies, in terms of design, biomarkers assessed, and burnout definitions, complicates direct comparisons. Melatonin measurement remains methodologically challenging due to its pulsatile secretion and sensitivity to environmental cues such as light and meal timing. Our own empirical contribution relied primarily on cortisol assays, while melatonin dysregulation was inferred through circadian context. Future research should integrate real-time biomarker monitoring (e.g., wearable actigraphy combined with salivary cortisol and melatonin profiling) to capture the dynamic interplay of stress and circadian regulation. Additionally, longitudinal studies are needed to clarify causal relationships between circadian disruption and burnout progression.

In sum, this discussion underscores that burnout is best conceptualized as both a psychosocial and a chronobiological disorder. Cortisol and melatonin act as complementary biomarkers: cortisol reflecting HPA axis activation and stress reactivity, melatonin representing circadian integrity and restorative capacity. Their combined dysregulation explains why chronic occupational stress produces such profound physical consequences. Recognizing this dual framework has significant clinical and organizational implications, opening the door to integrated interventions that stabilize circadian rhythms, normalize endocrine function, and address occupational stressors at their root.