, 2007). And in an environmentally induced model of circadian rhythm disruption, mice that were housed on a shortened 20-h light–dark cycle exhibited learning and structural connectivity deficits comparable to those seen in chronic stress states, including apical dendritic atrophy in mPFC pyramidal cells and PFC-dependent cognitive deficits ( Karatsoreos et al.,
2011). Studies like this also highlight implications for patients outside the psychiatric realm. For example, mice that were housed on a shortened 20-h light–dark cycle also developed metabolic problems, including obesity, increased leptin levels, and signs of insulin resistance. Shift workers and frequent travelers who suffer from chronic jet lag may experience analogous cognitive and metabolic changes (Sack et al., 2007, Lupien et al., 2009 and McEwen, 2012), and in susceptible check details see more individuals, travel across time zones may even trigger severe mood episodes requiring psychiatric hospitalization (Jauhar and Weller, 1982). An increasing
awareness of the importance of circadian and ultradian glucocorticoid oscillations in learning-related synaptic remodeling may also have implications for efforts to optimize training regimens for promoting motor skill learning, which is known to vary with the time of day in both adolescents and adults (Atkinson and Reilly, 1996 and Miller et al., 2012). Similarly, disruptions in circadian glucocorticoid oscillations may be an important factor to consider in patients undergoing treatment with corticosteroids, which are frequently used in the management of a variety of common autoimmune disorders. Cognitive complaints and mood symptoms are extremely common but poorly understood side effects of treatment (Brown and Suppes, 1998, Otte et al., 2007 and Cornelisse et al., 2011), which could potentially be mitigated by designing treatment regimens to preserve
naturally occurring oscillations whenever possible. Converging evidence from animal models Liothyronine Sodium and human neuroimaging studies indicates that stress-associated functional connectivity changes are a common feature of depression, PTSD, and other neuropsychiatric conditions and are associated with correlated structural changes in the prefrontal cortex, hippocampus, and other vulnerable brain regions. These, in turn, may be caused in part by circadian disturbances in glucocorticoid activity. Circadian glucocorticoid peaks and troughs are critical for generating and stabilizing new synapses after learning and pruning a corresponding subset of pre-existing synapses. Chronic stress disrupts this balance, interfering with glucocorticoid signaling during the circadian trough and leading to widespread synapse loss, dendritic remodeling, and behavioral consequences.