, 2007). In contrast, PFC dysfunction
in ADHD is likely genetic, and arises from slowed or impaired development of the PFC, particularly in the right hemisphere (Shaw Ibrutinib et al., 2009). Risk may be bi-directional such that antecedent impulse-control disorders may increase involvement in high-risk activities that may lead to traumatic events, and/or overarousal symptoms of PTSD may clinically mimic signs of impulse-control disorders. It is not surprising that PTSD and ADHD symptoms frequently co-occur in clinically referred children and adolescents since both disorders involve PFC dysfunction. Imaging and post-mortem studies have shown consistent signs of PFC dysfunction in patients with PTSD. For example, functional imaging studies of PTSD subjects vs. healthy controls have shown reduced BOLD response over the dlPFC during memory retrieval (Tian et al., 2014), and patients have deficits performing tasks that depend on the PFC (Koenen et al., 2001). Similarly, reduced vmPFC activation check details in subjects with PTSD correlated with impaired inhibition of the fear response (Jovanovic et al., 2013). Structural imaging studies have shown thinner dlPFC, thinner vmPFC, a smaller subgenual PFC, as well as thinner temporal association cortex (Mollica et al., 2009, Herringa et al., 2012 and Kühn and Gallinat, 2013). Gene
array analyses of post-mortem tissue show dysregulated mitochondrial function in the dlPFC of patients with PTSD (Su et al., 2008). Preliminary evidence suggests that rTMS to strengthen left dlPFC may aid treatment of PTSD, at least in those with depression (Nakama et al., 2014). Functional imaging has also shown altered patterns of PFC see more activity to emotional charged words in abused women with PTSD (Bremner et al.,
2003), although the pattern of changes was more complex. In addition to changes in the PFC, there is extensive evidence of elevated NE responsiveness in PTSD. For example, veterans with PTSD show elevated NE levels in CSF (Geracioti et al., 2001). They also show greater response to the alpha-2 receptor blocker, yohimbine, which increases the firing of the LC and increases NE release through actions at pre-synaptic alpha-2 receptors. Patients with PTSD given yohimbine showed greater NE metabolite levels in plasma than healthy controls, and yohimbine induced panic attacks and PTSD symptoms such as flashbacks in patients as well (Southwick et al., 1993). Yohimbine also decreased metabolism in the PFC of subjects with PTSD compared to healthy controls (Bremner et al., 1997). All of these changes are consistent with data from animal models showing weaker dlPFC and increased tonic firing of the LC following stress exposure. Research has begun to reveal how stress exposure can rapidly impair PFC function through intracellular signaling events that open ion channels and weaken dlPFC network connections (Arnsten, 2009).