AVP, also known as the anti-diuretic hormone, is produced primarily by SCN neurons and, to a lesser extent, paraventricular neurons and is released from the posterior pituitary (71). AVP binds to three G-protein-coupled receptors (vasopressin receptors (VR)): VR1a, VR1b, and VR2. AVP acts at VR1a on vascular smooth muscle cells to constrict blood vessels and increase systemic vascular resistance and is critical in blood pressure maintenance (72). AVP acts at VR1b to stimulate the release of adrenocorticotropic hormone (ACTH) from the anterior pituitary (73) and has an emerging role in regulating water permeability via intercellular crosstalk between renal VR1b and VR2 (74). AVP acts at renal VR2 to increase aquaporin-2 and promote the re-absorption of water and is essential in maintaining osmolarity (75).

Existing reports on the timing of AVP rhythms in the SCN and plasma are consistent in rodents. AVP concentrations and expression of the AVP1a receptor show a strong, inverse circadian rhythm in the SCN of 3-5-month-old C57BL/6 male and female mice; high plasma AVP concentrations at ZT-4 map to the nadir expression of the AVP1a receptor, while low AVP (ZT-16) maps to peak AVP1a receptor expression (76). These findings accord with peak AVP concentrations reported at ZT-2 and nadir at ZT-14 in the SCN of Wistar rats (sex unspecified) (77) and with peak bioluminescence of AVP at ZT-4 and nadir at ZT-15 in brain slices collected from C57BL/6 male mice (78).

Reports on AVP rhythms in human health are less consistent with peak AVP plasma levels reported at 0400 in adult males (aged 25 years), followed by an immediate decline to a nadir at 0800 (79). This contrasts reports in adolescents (14 years), where a prolonged AVP peak was reported from 0200 to 0800 and a nadir at 2200 (80). Moreover, absolute plasma AVP levels and AVP rhythmicity show age-dependent attenuation in older adults (70 years) (79).

Pathological settings, notably hypotension early in clinical and endotoxin-induced septic shock, increase AVP to supra-physiological levels (20- to 200-fold increase) in human, dog, and baboon plasma (81, 82), however, sepsis in C57BL/6 mice following CLP produced only a mild 4% increase in plasma AVP after 12 hours compared to sham mice (83). In humans, this increase is followed by a decline to sustained sub-physiological levels for up to 7 days (59). The initial increase of AVP in septic shock is due to the stimulation of its synthesis and release by the vagus nerve in response to hypotension (84, 85); however, the synthesis and production of nitric oxide, a negative regulator of vasopressin, is exacerbated during sepsis, contributing to the decline in AVP levels (86). Whether this decline in AVP is adaptive or maladaptive is not clear. However, it has been shown that plasma AVP levels increase in human septic shock non-survivors (87) which adds support to an adaptive change.

Clinical studies have reported circadian changes to AVP acrophase in enuresis (80), systemic atrophy (88) and hydrocephaly (89). To date, AVP levels have only been investigated in humans and modelled septic shock in cross-section, and longitudinal effects on AVP circadian rhythms are currently unknown, likely due to the persistently low level of AVP seen beyond early sepsis.

Epinephrine and norepinephrine are catecholamine neurotransmitters and hormones with distinct differences. Epinephrine is released mainly from the adrenal medulla during stress via the coordinated actions of the hypothalamic-pituitary-adrenal (HPA) axis and sympathetic nervous system. This occurs through neural connections between hypothalamic corticotropin-releasing hormones (CRH) neurons and brain stem autonomic nuclei A1, A2, and A6 (locus coeruleus) (90), and at the adrenal gland, where cortisol facilitates adrenomedullary phenyl ethanolamine N-methyltransferase enzyme activity for epinephrine synthesis (91). Epinephrine acts on cardiac and pulmonary β-adrenergic receptors to increase cardiac contractility and relax airway smooth muscle, respectively (92, 93). In contrast, norepinephrine is synthesised continuously in sympathetic neurons and targets α-adrenergic receptors in synergy with cortisol to constrict arterial vascular smooth muscle and increase blood pressure (94, 95).

Early studies reported that epinephrine and norepinephrine have similar circadian rhythmicity in the plasma of healthy adults, peaking shortly after waking at 0800 with a nadir at 0400 (96–99). However, the control of these rhythms differs: epinephrine rhythms are true circadian and persist without external cues, whereas norepinephrine rhythms do not meet the definition of a true circadian rhythm, and are lost in the absence of external cues (100, 101). α- and β-adrenergic receptors also display tissue-specific rhythmicity in binding capacity, with evidence of peak binding at ZT-20 and ZT-24 respectively in the brain of Sprague-Dawley male rats (102) and similar rhythms in the pineal gland of Sprague-Dawley male rats and Syrian male hamsters (103–105); there is limited knowledge on the rhythmicity of these receptors in other peripheral tissues.

Few studies have investigated the impact of sepsis on the circadian regulation of catecholamine levels due to their use as an exogenous therapy to sustain cardiac output and blood pressure in ICU standard care. Sepsis following CLP in Sprague-Dawley male rats led to a rapid (0.5 hours) increase in plasma epinephrine (10-fold) and norepinephrine (3-fold), that was sustained at 20 hours post-CLP, and in the absence of treatment, was coincident with a loss of the diurnal rhythm of plasma epinephrine and norepinephrine (60). Computer modelling using available data on the responses of TLR4, NF-κB, and heart rate to sepsis, also predicted an increase and loss of circadian rhythm of plasma epinephrine and norepinephrine in endotoxemia-induced sepsis in humans (61). Both catecholamines regulate cytokines responses to sepsis and other severe infections. Indeed, the infusion of epinephrine after LPS administration in humans reduces the levels of TNF-α and increases IL−10 levels in whole blood (106) adding support that catecholamines serve an anti-inflammatory role in sepsis.

Cortisol is a powerful immunomodulator produced by the adrenal glands in response to coordinated hypothalamic release of CRH, followed by CRH-dependent pituitary release of ACTH that converges on the adrenal gland to increase adrenocortical biosynthesis of cortisol (107). Cortisol prevents over-activation of the immune system to limit inflammatory damage to inflamed tissues (108), promotes gluconeogenesis and glycogenesis to increase blood glucose levels (109), and acts as a short-term vasopressor (110). Cortisol binds two receptors, the glucocorticoid (GR, NR3C1) and mineralocorticoid receptor (NR3C2), however, the GR is more relevant in responses to stress (111), sepsis and septic shock, and as such, the focus of this review. GR are present in almost all tissues and exists in two isoforms formed through alternate splicing of exon 9 (the inclusion of either exon 9α or 9β) to produce either GRα or GRβ. Alternate splicing for GRα produces a functional glucocorticoid binding C-terminal, while for GRβ, this produces a non-glucocorticoid binding C-terminal, that prevents it from mediating glucocorticoid effects (112). Upon cortisol binding, GRα translocates to the nucleus to bind glucocorticoid response elements acting as a transcription factor, or binds other transcription factors such as NF-κB, preventing them from acting on target genes (113). Cortisol-dependent changes in gene expression alter cellular functions to suppress T cell proliferation (114) and inhibit production of pro-inflammatory cytokines (107). Importantly, the GR is transcriptionally regulated by CLOCK and BMAL1 through acetylation, reducing GR-mediated transcriptional activity, as evidenced in HCT116 and HeLa human cell lines (115).

The circadian rhythm of circulating cortisol in healthy adults parallels that of GR expression on leukocytes, and increases towards the end of the sleep phase (0400) and peaks shortly after waking in the morning (0800, ~400nmol/L) followed by a progressive decline towards the onset of sleep (2100, < 50nmol/L) (116). Cortisol rhythmicity is pivotal to the timing of peripheral cellular clocks to the central SCN clock (117), providing ‘time cues’ to peripheral tissues by directly increasing the expression of Per1/2 and Cry1/2. Cortisol actions on Clock and Bmal1 are indirect, occurring through its effects on these negative clock regulators. The peripheral rhythms predominantly regulated by cortisol include metabolic (glucose and lipid metabolism) and immune (suppression of inflammation during active phases) rhythms.

Total and free circulating cortisol are significantly elevated in patients with sepsis and septic shock (118–121) and higher in non-survivors than survivors (118, 121, 122). This differential may arise due to glucocorticoid resistance (123). Normally, cortisol activation of the GR inhibits CRH and ACTH release, forming a negative feedback loop. However, in GR resistance, GRα undergoes tachyphylaxis or has reduced sensitivity to cortisol due to post-translational modification, leading to a reduction in this negative feedback loop and an increase in total cortisol levels. In addition, while GRβ protein is significantly increased in mononuclear cells from humans with sepsis, and increased more than GRα in the human T-cell line CEM in response to sepsis serum (124), augmented GRβ transcription in whole blood does not correlate with in vitro measures of glucocorticoid sensitivity (125).

While the mesor (circadian average) of cortisol is significantly higher in patients with sepsis (62–65) reports describing characteristics of this rhythm are equivocal. A complete loss of cortisol rhythms has been reported in sepsis (62, 64, 65), while a 7-hour-delayed acrophase has also been reported (63). Hourly blood sampling has shown blunted circadian rhythms of cortisol in ICU patients with frequent cortisol pulses (126). The specific reasons for these discrepancies are uncertain, although likely arise due to the heterogeneity of patients and sampling conditions. Ultradian (<24h) cortisol secretory episodes, if large, may well obscure the circadian rhythm and are essential to map to gain a precise understanding of cortisol responses. Dysregulation of cortisol rhythms is specific to immune activation in sepsis and/or septic shock, and is unrelated to the ICU environment, as critically ill patients without sepsis exhibit normal cortisol rhythms (127). It is unknown, however, whether the circadian rhythm of GR is altered during sepsis and/or septic shock in animal models or patients.

Melatonin is produced and released primarily by pinealocytes as an important sleep regulator (128) and by enterochromaffin cells in the gastrointestinal tract, where it regulates motility and inflammation (129). Melatonin binds two receptors (MtR) 1 and MtR2 that are widely distributed throughout the body; MtR1 promotes sleep, while MtR2 is involved in vasodilation and can induce phase shifts in circadian patterns. The expression of both receptors in the SCN of C3H/HeN male mice is low during the active period and increases markedly during inactive periods, a rhythm similar to that of circulating melatonin (130). In humans, melatonin levels rise in serum and urine during the night, peaking at 0000-0200, and are low throughout the day, aiding in a typical healthy sleep pattern (65, 128, 129).

Melatonin rhythms are absent in sedated and/or mechanically ventilated patients with sepsis or septic shock due to an absence of external environmental cues (64–69). However, limited reports suggest that a melatonin rhythm is present in mechanically ventilated patients but is variably shifted in acrophase to 0500 (25) or 1800 in early-stage sepsis (131), findings which may relate to discrepancies in melatonin sampling protocols. It has also been reported that a normal circadian rhythm is maintained in non-ventilated, non-sedated patients for at least the first 2 days in the ICU, after which circadian variation is lost (66, 132). However, only a subset of these patients was admitted due to sepsis, and it is not possible to separate whether sepsis or the ICU environment caused a loss of melatonin rhythm. It has also been shown that melatonin rhythms show an extended peak time during recovery from sepsis (66), and further investigation is warranted as to whether this feature follows or drives impaired recovery.

The adipokine leptin is a major regulator of appetite and metabolism but also plays an important role in the maturation and function of white blood cells, WBCs (133, 134). Leptin levels exhibit strong circadian rhythms in healthy adults and peak at night (~0100) with a morning nadir (~0900) (62, 135).

Leptin levels increase in patients with sepsis and murine sepsis models in association with increased pro- and anti-inflammatory cytokines, including IL-6 and IL-10 (62, 70, 136–138), while in patients, this occurs concurrent with a loss of circadian rhythm (62); whether leptin rhythmicity changes in murine models of sepsis is currently unknown. Leptin secretion from adipose tissue is increased by cortisol (139), and leptin can act as a negative regulator of the HPA axis by inhibiting CRH release (140, 141). Together, this suggests that the marked increase and loss of circadian rhythm in circulating glucocorticoids and the increase in IL-6 likely drive the increase in leptin levels in early sepsis. However, leptin levels decrease in persistent or prolonged clinical sepsis (138), likely due to a loss of fat mass. Evidence that mortality is variably increased (137) or decreased (136) in leptin receptor-deficient db/db mice subject to CLP-modelled sepsis adds to the uncertainty on whether leptin is a follower or driver of sepsis progression, and further research is required to confirm the nature of this interaction.

Toll-like receptors (TLRs) are crucial first responders to pathogens and trigger innate immune system activation, an effect increased by cortisol. Three heavily studied TLRs in the context of sepsis include TLR2, TRL4, and TLR9, which are present in lymphocytes and macrophages. TLR2 recognises lipoproteins and peptidoglycans from Gram-positive bacteria (162), whilst TLR4 recognises lipopolysaccharides from Gram-negative bacteria, damage-associated molecular patterns, and pathogen-associated molecular patterns (163). In contrast, TLR9 recognises bacterial and viral unmethylated CpG DNA (164). In the context of sepsis, activation of these TLRs triggers the synthesis and release of various cytokines from immune cells, including TNFα, IL-6, and IL-12, driving the excessive inflammatory response.

The body temperature of humans and most mammals follows a circadian rhythm with a sinusoidal fluctuation of about 0.5-1°C, peaking approximately 12 hours following the onset of daylight with a nadir during the night (178). Body temperature increases during the acute phase of infection to enhance the efficacy of WBCs and to induce pathogenic stress. This is observed in early-stage sepsis as body temperature rhythm changes to one with increased mesor, amplitude, and frequency (179), in essence, shifting to an ultradian rhythm (rhythm with several cycles of at least 1 hour throughout 24 hours). Patients with decompensated sepsis and high sequential organ failure scores often also exhibit hypothermia, which is linked to a significant increase in mortality (180, 181). It has been suggested that hypothermia during sepsis parallels the body entering an ‘energy saving’ mode, compared to hyperthermia in ‘active infection-fighting’ mode (182). LPS-induced sepsis in C57BL/6 male mice produced a larger and more rapid drop in body temperature in the light- compared to the dark phase (51), which was postulated due to hypothalamic overactivation during the light phase (measured as cFOS expression) (51). Overall, the effects of sepsis on the circadian rhythms of body temperature are not well elucidated, and substantial research is required for full knowledge.

Chronotherapy has been used to aid the treatment of mood and depressive disorders. For example, bright light therapy is used to treat seasonal and non-seasonal affective disorders, such as seasonal depression and major depressive disorder, with significant improvements noted in self-reported depression (184, 185). Other studies have used a combination of sleep deprivation for 24–48 hours and bright light therapy for 1 week to evidence a rapid and sustained reduction in bipolar and depressive symptoms (186, 187). In addition, using urinary melatonin as a marker of circadian rhythms, it was shown that exposure to a 400-700 lux light box for 3 hours in the morning (0900-1200) re-aligned circadian rhythms within 48 hours in phase-delayed ICU patients (188). Together, these studies highlight light and/or sleep cycle manipulations in current use to re-align circadian rhythms and effectively treat disorders, notably for improved mental health.

Chronopharmacotherapy leverages circadian rhythmicity to optimise management of several clinical conditions. For example, administration of H2 antagonists to treat duodenal ulcers is optimal at bedtime when gastric acid secretions are highest (189). Administration of non-steroidal anti-inflammatory drugs is optimal in the afternoon for arthritis and at night for rheumatic disorders (190, 191). Cortisol replacement therapy also leverages chronobiology in administering delayed-release cortisol once daily at night (i.e., Plenadren) or twice daily (i.e., Chroncort), with improved well-being reported in patients with adrenal insufficiency (192). In addition, inflammatory disorders such as rheumatoid arthritis and ankylosing spondylitis are optimally treated by early morning glucocorticoid therapy to manage peak symptom severity in the late evening and early morning in humans when pro-inflammatory cytokines peak (193). Together, these highlight the value of chronopharmacotherapy within current practice, and potential benefits on offer to leverage circadian machinery and rhythms to optimise disease treatment in the future.

Few studies have investigated the use of chronotherapy to treat immune responses in sepsis. Twenty-four hours of above-cage blue light (442 nm, lux 1400) exposure after CLP in C57BL/6 male mice increased splenic Rev-Erb protein and reduced peritoneal bacterial colony formation as well as serum TNFα, IL-6, and IL-12, compared to ambient light. This effect was lost in C57BL/6 male mice deficient in Rev-Erb, and likely relates to Rev-erb actions to suppress cytokine production (194), a notion that garners support in evidence that Rev-Erb agonists suppress cytokine production by LPS-treated human alveolar macrophages (195). Benefits of this same blue-light therapy over 18 hours were also shown in patients with appendicitis, who had lower postoperative serum IL-6 levels relative to patients under normal light (194). Exposure to blue light (442 nm, lux 1400) for 24 or 36 hours, followed by 12 hours per day for 72 hours in C57BL/6 male mice with a monobacterial Klebsiella pneumoniae infection led to significant reductions in mortality (40%) compared to mortality under ambient (75%) or red light (80%) (196). Together, these blue light intervention studies frame the potential for blue light chronotherapy to treat or augment the efficacy of other sepsis therapies and warrant deeper investigation.

Melatonin has been tested in the context of sepsis therapy in infants, where oral melatonin (10 mg twice for one day) significantly improved recovery time and reduced WBC count (197). In a more recent study, oral melatonin (50 mg daily for five days) was shown to significantly reduce sequential organ failure score and decrease vasodilator and ventilator dependency in adults with sepsis (198). While promising, further research is needed to elucidate whether melatonin effects arise due to circadian or anti-inflammatory actions or both.