Abnormal Sleep, Circadian Rhythm Disruption, and Delirium in the ICU: Are They Related?

The upregulation of GABA-A receptors, either through an increase in synthesis of endogenous GABA agonists or stimulation from exogenous GABA agonists, has been implicated in delirium (54, 55). GABA-ergic agents are thought to destabilize neurons preventing sleep transition (55), and upregulate inhibitory tone in the central nervous system contributing to neural connectivity and cognitive disintegration (56). Both benzodiazepines and propofol, commonly administered sedatives in the ICU, mediate their effect by modulating the effects of GABA. Zaal et al. (13) demonstrated that continuous infusion as compared to intermittent bolus dosing was associated with delirium; suggesting that higher doses or greater exposure is an important factor in transitioning to delirium. Although the interpretation of sleep in the ICU can be difficult in sedated patients, benzodiazepines typically increase total sleep time through prolonging stage 2 NREM, while suppressing both stage 3 NREM or slow wave sleep and REM (57). Propofol has been shown to worsen overall sleep architecture; specifically, suppressing REM sleep (58).

In contrast to the potentially deleterious effects of GABA agonists, the use of the alpha-2 agonist dexmedetomidine has been shown to be relatively effective in decreasing the daily prevalence of delirium in mechanically ventilated ICU patients (59). Dexmedetomidine is a highly selective alpha-2 agonist that facilitates both sedation and analgesia, without much respiratory depression. It appears to be particularly effective in lowering the daily prevalence and duration of delirium when compared with benzodiazepines, such as lorazepam, the comparator in the randomized, double-blind MENDS trial (60). The daily prevalence of delirium in dexmedetomidine-treated patients was also significantly lower when compared to a midazolam group in the randomized, double-blind SEDCOM trial (61). Recently, the prophylactic use of nocturnal dexmedetomidine was shown to reduce the incidence of delirium in the SKY-DEX trial (62). In the DahLIA, placebo-controlled trial (63), 74 mechanically ventilated patients with agitation and delirium were randomized to dexmedetomidine or placebo; patients treated with dexmedetomidine had increased ventilator-free hours at 7 days (median, 145 vs. 128 h) and faster resolution of their delirium symptoms (median, 23 vs. 40 h). The effect of dexmedetomidine on delirium prevention may be mediated both through its reduction in glutamate release, as glutamate toxicity has been previously associated with the development of delirium (64), but also through its decreased GABA receptor modulation or cholinergic receptor activity when compared to other commonly used sedatives (65). Furthermore, dexmedetomidine through the stimulation of alpha-2 receptors and resultant inhibition of noradrenergic neurons in the locus coeruleus and disinhibition of GABA neurons in the ventrolateral preoptic nucleus it may promote more natural sleep in the ICU environment (66).

Disturbed melatonergic activity is also implicated in delirium pathogenesis. Risk factors for delirium including pre-existing cognitive impairment, old age, and psychotropic medication use are all associated with impaired melatonergic function. Melatonin deficiency and abnormal secretion contribute to impairment of the sleep-wake cycle. Perras et al. (67) report that the normal response of melatonin secretion to changes in light and darkness is impaired in critically ill patients suggesting a dysregulation of the mechanism of melatonin secretion or a shift in the circadian clock phase in the SCN. Altered urinary levels of the melatonin metabolite 6-sulfatoxymelatonin (6-SMT) has been reported in delirious patients as compared to patients who were not delirious; levels were elevated in hypoactive patients and lower in hyperactive patients (68). Urinary 6-SMT exhibited loss of circadian rhythmicity with no daytime decline in septic patients (36), a frequently present in critical illness. Recently, Li et al. (69) measured plasma levels of melatonin, TNF-α, IL-6 and messenger RNA of the circadian genes Cry-1 and Per-2 for 24-h in septic and non-septic ICU patients (n = 22). Altered circadian rhythm of melatonin secretion, reduced expression of Cry-1 and Per-2, and elevated levels of TNF-α and IL-6 were again seen in patients with sepsis (69).

Hypothalamic-pituitary-adrenal-stress axis (HPA) dysregulation might also be related to incident delirium and circadian dysrhythmia and is intimately related to the SCN and melatonergic functions. Elevated plasma cortisol levels are associated with increased delirium risk after both cardiac- (70) and non-cardiac surgery (71). Pearson et al. (72) found that in post-operative patients over the age of 60 years with acute hip fracture, cortisol CSF levels were elevated in those who developed delirium as compared to those who did not. It has been postulated that aberrant stress responses related to disrupted function in the limbic-HPA axis and its interaction with the inflammatory response may be responsible for the increased risk of delirium with age as well as pre-existing cognitive impairment (73). In a cohort of ICU patients with severe sepsis and septic shock (n = 140), plasma cortisol level between 6 and 12 h post hemodynamic stabilization (odds ratio [OR]: 2.3, 95% CI 2.0–3.2; p = 0.02) and the combination of older age and plasma cortisol level (OR: 1.0, 95% CI 1.0–1.9; p = 0.04) were associated with increase delirium risk (74).

Relationship between mechanical ventilation, sleep disturbances and circadian dysrhythmia are not well-understood as they are complex and likely associated with variation in the administration of sedative agents and subsequent patient-ventilator asynchrony management (8). However, this relationship strongly influences the weaning process as sleep disturbances and delirium are associated with greater duration of mechanical ventilation and prolonged ICU length of stay (78–80). An opportunity must therefore exist for intervention with the aim of modifying ventilator settings and practices for improving sleep and circadian rhythmicity.

Sedation is commonly used to help patients tolerate mechanical ventilation. The 2018 PADIS Clinical Guidelines recommend the use of light levels of sedation (Richmond Agitation Sedation Score of −2 to +1) during invasive mechanical ventilation (30). This inevitably results in patients breathing spontaneously during assisted ventilation and resultant abnormal patient-ventilator interactions named asynchronies. The typical reaction of physicians to the presence of asynchronies involves the administration of additional sedation boluses or increasing the dose of sedative infusions which can significantly affect sleep architecture, circadian rhythmicity and delirium risk. However, not all asynchronies are “improved” (81) with sedation (82, 83). Therefore, an understanding of the mechanisms leading to the experienced asynchrony and personalized adjustment of ventilator settings (81) might spare a patient from further exposure to sedative agents, possibly mitigating further risk of sleep and circadian rhythm disruption. The titration of pressure support settings during non-invasive ventilation by adjusting the amount of support to meet the needs of the patient has previously been shown to decrease the number of asynchronies and improve sleep architecture in patients with chronic neuromuscular diseases (84).

Caution however needs to be exercised as over-assistance during pressure support can alternately lead to central apneas with resultant poor sleep, characterized by frequently awakenings and arousals leading to greater sleep fragmentation (85, 86). Ventilatory support in excess to a patient's metabolic need results in hyperventilation where CO₂ levels decrease below the apnea threshold (87). To eliminate over-assistance, which can also lead to other adverse outcomes such as disuse diaphragmatic atrophy (88), the amount of ventilatory support needs to be decreased (89). Alternatively, assist-controlled modes with a back-up respiratory rate can also be used to prevent apnea events which has been shown to reduce sleep fragmentation (86). Using assist-controlled modes however does not eliminate the risk of disuse diaphragmatic atrophy and might create the false impression that patients are not ready for liberation, potentially delaying extubation. Proportional modes of ventilation [i.e., proportional assist-ventilation [PAV+] and neurally adjust ventilatory assist [NAVA]] can be used to deliver pressure proportional to the patient's instantaneous efforts in terms of amplitude and timing which avoids over- and under-assistance and improves synchrony. The use of these modes has systematically been shown to decrease asynchronies (82, 90, 91) and improve sleep quality in cross-over studies of small size (92, 93).

Recently a review by Flannery investigated whether interventions targeted at improving sleep in the ICU were associated with reductions in ICU delirium (94). Six of the ten identified studies demonstrated a statistically significant reduction in the incidence of ICU delirium associated with sleep intervention. Unfortunately, although sleep interventions seem to be a promising approach for improving delirium and related outcomes (e.g., ICU length of stay) conclusions are limited by confounding, variable methodology and bias issues. Further study is therefore needed. Based on available data, potentially effective interventions might include a combination of dexmedetomidine (62), oral melatonin (95), and cognitive behavioral sleep therapy (96) using modified polysomnography to quantify sleep quality and quantity (25, 78) and understand to which extent sleep actually affects delirium occurrence.