Discussion

The current study found that higher serum levels of sTNF-αR1 were associated with longer sleep latency across TRD and non-TRD groups. Elevated serum sIL-2R levels correlated with poorer overall sleep quality among patients with MDD. Severe sleep disturbance correlated with increased sIL-2R and MCP-1 levels, while patients with sleep initiation difficulties or sleep loss had elevated sIL-2R and sTNF-αR1 levels. Other inflammatory markers tested were not associated with subjective sleep quality in this study.

In our study, serum sTNF-αR1 level was significantly associated with sleep latency in patients with MDD, including both TRD and non-TRD subgroups. However, after applying false discovery rate correction for multiple comparisons, the associations became statistically nonsignificant. This suggests that the observed associations should be interpreted with caution, as they may be influenced by sample size and multiple testing adjustments. Given the biological plausibility of TNF-α’s role in sleep disturbances and prior evidence in the literature, future studies with larger samples are needed to validate these findings. The TNF-α system has emerged as a crucial player in sleep regulation and circadian biology, evident in both animal and human studies.Reference Krueger^9, Reference Rockstrom, Chen and Taishi²⁸ In rodents, both acute sleep deprivation and chronic sleep restriction have been observed to elevate TNF-α expression in various brain regions, including the cortex, hippocampus, and brainstem, indicating diurnal fluctuations in TNF-α levels.Reference Zielinski, McKenna and McCarley²⁹ In healthy individuals, acute sleep deprivation was shown to induce secretion of TNF-α, but not IL-6 or CRP.Reference Chennaoui, Sauvet and Drogou³⁰ A reduction in total sleep duration (from 8 to 6 hours per night for 1 week in healthy subjects) has been associated with increased TNF-α levels the following day. In pathological conditions associated with shortened sleep duration, chronic elevations of systemic TNF-α have been observed.Reference Haack, Pollmacher and Mullington³¹ Our observational results in MDD correspond to previous studies that TNF-α may serve as a mediator of pathological or experimentally induced sleepiness. Conversely, TNF-α can modulate sleep, and experimental studies across species by intravenous administration or microinjections into certain brain areas have consistently shown that TNF-α enhances non-rapid eye movement sleep (NREMS) duration and induces sleepiness.Reference Mullington, Korth and Hermann^32, Reference Terao, Matsumura and Yoneda³³ Blockade of TNF-α has shown promise in reducing depressive symptoms in patients with increased inflammation, yet its effect on sleep in depressed patients remains underexplored. A polysomnography study indicated that TNF-α blockade with infliximab may improve sleep continuity in patients with MDD, particularly those with high inflammation levels.Reference Weinberger, Raison and Rye³⁴ Additionally, levels of TNF-α messenger RNA (mRNA), sTNF-αR, and sTNF-αR mRNA in the CNS also vary with sleep propensity in a similar fashion. Irwin and colleagues demonstrated increased production of TNF-α mRNA by monocytes, notably observed the morning after sleep deprivation.Reference Irwin, Wang and Campomayor^35, Reference Irwin, Carrillo and Olmstead³⁶ This elevation in circulating TNF-α levels could stem from the activation of cellular TNF-α expression, potentially influencing the expression of other inflammatory cytokines within cells.Reference Irwin, Wang and Campomayor³⁵ Furthermore, the heightened expression of inflammatory genes following sleep deprivation is attributed to the activation of nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB) transcription control pathways, which play a pivotal role in regulating the expression of pro-inflammatory genes.Reference Irwin, Wang and Ribeiro^11, Reference Irwin, Wang and Campomayor³⁵ Regarding sTNF-αR, sTNF-αR1 levels rise after sleep loss in humans, while sTNF-αR2 remains unaffected.Reference Shearer, Reuben and Mullington³⁷ Additionally, sleep deprivation boosts sTNF-αR1 mRNA expression.Reference Taishi, Gardi and Chen³⁸ Further research is warranted to elucidate the intricate mechanisms underlying TNF-α’s role in sleep regulation and its potential therapeutic implications for sleep disorders and related conditions.

We found that serum sIL-2R level was positively associated with PSQI total score among patients with MDD, and patients with problems in sleep latency had higher serum sIL-2R levels. IL-2, primarily synthesized by helper T cells, serves as a T cell growth factor with extensive immunoregulatory functions and CNS regulatory roles.Reference Malek³⁹ The exact nature of IL-2’s inflammatory activity remains ambiguous. While historical literature has predominantly depicted IL-2 as pro-inflammatory, recent clinical investigations have suggested its anti-inflammatory properties. Researchers have observed IL-2’s capacity to suppress inflammatory responses, leading to its classification as both pro- and anti-inflammatory.Reference Boerrigter, Weickert and Lenroot^40, Reference Lan, Selmi and Gershwin⁴¹ Limited human studies have explored the relationship between sleep and IL-2. Previous studies in humans found that sleep deprivation increased IL-2 activity, with increased IL-2 production during sleep recovery.Reference Born, Lange and Hansen^42, Reference Irwin, McClintick and Costlow⁴³ Sleep deprivation may result in an upregulation of TNF-α, which in turn stimulates NF-κB and subsequently increases IL-2 production.Reference Krueger, Majde and Obal⁴⁴ This could explain our observation of the association between high sIL-2R levels and longer sleep latency. The sleep-inducing effects of IL-2 may be mediated through various mechanisms, including opioid receptor antagonism, induction of sleep regulatory substances such as TNF-α, and activation of neuronal nitric oxide (NO) synthase. These findings suggest a complex interplay between IL-2 and other sleep regulatory substances, highlighting the need for further research to elucidate the precise mechanisms underlying IL-2-induced sleep regulation.

This cross-sectional study suggests a potential interplay between sleep disturbance and inflammation in depression. However, the causal directionality between sleep and inflammation remains uncertain. From an evolutionary perspective, cytokines are crucial regulators of host defense against infection, and the sleep-inducing effects of cytokines, along with the activation of immune cells that stimulate cytokine production, may lead individuals with elevated inflammation levels to longer sleep durations.Reference Vgontzas, Papanicolaou and Bixler⁴⁵ Experimental studies have demonstrated that cytokines can modulate sleep architecture, implying that alterations in inflammation could plausibly contribute to sleep abnormalities and subsequently elevate the risk of depression.Reference Haack, Schuld and Kraus⁴⁶ Conversely, sleep disturbances might also contribute to increased systemic inflammation compared to periods of uninterrupted sleep.Reference Vgontzas, Zoumakis and Bixler⁴⁷ For example, sleep reduction by 2 hours per night for a week in non-depressed individuals has been shown to increase circulating TNF-α.Reference Vgontzas, Zoumakis and Bixler⁴⁷ Sleep disturbance is believed to influence the sympathetic nervous system and hypothalamic–pituitary–adrenal axis, thereby promoting inflammation. Specifically, β-adrenergic signaling has been implicated in inducing the expression of inflammatory genes, cytokine production, and systemic inflammation.Reference Hall, Smagula and Boudreau⁴⁸

We did not find sex-specific effects of subjective sleep quality on inflammatory responses. The association between sleep patterns and health outcomes seems to exhibit sex-specific differences, with recent evidence indicating that women may be more susceptible to the consequences of poor sleep, showing heightened inflammatory responses.Reference Irwin, Carrillo and Olmstead^36, Reference Suarez⁴⁹ However, population-based studies have yielded conflicting results, with some showing no association between poor sleep and peripheral inflammatory markers when pooling men and women, while others suggest a stronger link in women when analyzed separately.Reference Taheri, Austin and Lin⁵⁰ These findings underscore the need for further investigation into the sex-specific effects of sleep disturbances on inflammatory mechanisms and subsequent health outcomes.

Our study offers valuable insights into the potential underlying mechanisms of MDD and its related symptoms, namely sleep disturbance. It can inform the development of targeted interventions aimed at improving both sleep quality and inflammation, thereby potentially ameliorating the burden of depression and reducing the risk of related health complications.Reference Mallon, Broman and Hetta⁵¹ Chronic inflammation, linked to adverse health conditions like cardiovascular disease and diabetes, underscores the importance of investigating how poor sleep quality, inflammation, and depression interact. In addition, our team’s past research on patients with MDD found that inflammation is associated with cognitive impairment and suicidal ideation;Reference Huang, Chen and Hsu^5, Reference Huang, Chan and Chen²⁶ this study further expands the clinical influences of inflammation on sleep disturbance in MDD.

This study has several limitations. First, the sample size was relatively small. Studies with a larger sample size are required to avoid a type II error. Second, a cross-sectional design limits causality establishment between variables, only allowing for associations to be observed. To better understand the mediating role of inflammation in the relationship between MDD incidence and sleep disturbances, longitudinal studies or experimental manipulations of sleep and/or cytokines are necessary.Reference Prather, Rabinovitz and Pollock⁵² Third, other inflammatory markers, such as IL-1β or neutrophil-to-lymphocyte ratio, may also be relevant to the pathophysiology of depression and sleep disturbance, but were not included in this study.Reference Norman, Karelina and Zhang^53, Reference Fusar-Poli, Natale and Amerio⁵⁴ Also, inflammatory markers were measured only once in the current study, whereas repeated measurements would have provided a more robust validation of inflammatory activity. Fourth, the associations between sleep disturbance and inflammation varied by the method of sleep assessment,Reference Irwin, Olmstead and Carroll¹² as polysomnography or actigraphic assessment was not utilized. Objective sleep parameters and sleep apnea were not evaluated in this study, potentially impacting the results, given the known association between obstructive sleep apnea and increased inflammatory activity, including alterations in TNF-α production.Reference Tamaki, Yamauchi and Fukuoka⁵⁵ Additionally, lifestyle factors such as diet and physical activity,Reference Kiecolt-Glaser^56, Reference Gleeson, Bishop and Stensel⁵⁷ which could influence inflammation and sleep quality, were not collected in our study. Last, a considerable portion of patients were prescribed psychotropic medications in our study, particularly antidepressants, known to impact REM latency and REM sleep duration; some psychotropic medications carry anti-inflammatory effects.Reference Beurel and Jope⁵⁸ Cautious interpretation of our results due to potential confounding effects of medications on sleep quality and inflammation is needed,Reference Pompili, Venturini and Palermo⁵⁹ but preserving patients’ ongoing medication prevents disease relapse and exacerbation of symptoms throughout the study period and was ethically imperative.

This study elucidates the intricate relationship between sleep disturbance and inflammation among patients with MDD, particularly focusing on inflammatory markers such as sTNF-αR1 and sIL-2R. Patients with TRD exhibited higher levels of serum sTNF-αR1. Serum sTNF-αR1 levels positively correlated with sleep latency, and serum sIL-2R levels were associated with poorer overall sleep quality and specific sleep disturbances. These findings indicate the interplay between inflammation and sleep in MDD. Further longitudinal research is warranted to elucidate causal relationships, so as to inform potential therapeutic interventions targeting both domains.