Attenuation of Circadian Dysfunction Improves Sleep, Mood and Neuropsychometric Performance

• Main Author: Rahman, Shadab
• Other Authors: Casper, Robert
• Language: en_ca
• Published: 2012
• Subjects: Circadian Rhythms; Sleep Physiology/Medicine; Neuroendocrinology; Mood and Cognition; 0719; 0317
• Online Access: http://hdl.handle.net/1807/33824

Mood and cognition, along with numerous other physiological processes, are under circadian regulation. The synthesis and secretion rhythm of the pineal hormone melatonin is under the direct regulation of the central circadian pacemaker and the secretion rhythm of melatonin can be used to assess circadian alterations. In this thesis, it was demonstrated that low levels of endogenous nocturnal melatonin was associated with subsyndromal depression and alterations in sleep architecture. Studies in individuals with endogenous circadian rhythm disorder, with and without comorbid depressive symptoms, revealed that individuals with depressive symptoms had a greater phase delay in melatonin profiles as compared to individuals without depressive symptoms. Furthermore, in the same study, exogenous melatonin administered to induce phase advances significantly improved depression scores and sleep initiation. In addition to endogenous circadian disruption, circadian rhythms can also be disrupted by repeated atypical alterations in environmental time cues. In mammals, light is the strongest environmental cue that can modulate circadian rhythms. Recent studies suggest that circadian response to photic stimuli is preferentially sensitive to short wavelengths in the range of 450-480 nm. Using an animal model it was demonstrated that filtering a 10 nm bandwidth between 470-480 nm from polychromatic white light prevents nocturnal light exposure induced disruptions in melatonin and corticosterone secretion as well as central and peripheral clock gene expression. These findings were further investigated in humans and revealed that filtering short wavelengths below 480 nm attenuates 12 h nocturnal light exposure induced suppression of melatonin secretion, increased cortisol secretion and disrupted peripheral clock gene expression. Furthermore, attenuation of these changes was associated with improvements in mood, alertness and vigilance at a time close to the endogenous circadian wake drive. However, filtering short wavelengths below 460 nm or reducing the optical transmission by up to 30% below 480 nm did not attenuate the disruptive effects of nocturnal light exposure on physiological and behavioural variables. Overall, the results presented in this thesis support the role of circadian dysfunction in neuropsychometric impairment and presents evidence supporting spectral modulation as a promising approach to attenuate light-mediated chronodisruption.