Long-term disability from traumatic brain injury (TBI) is prevalent occurring in approximately 3.17 million persons on an annual basis.1 Among the long-term consequences of TBI, post-traumatic headache (PTH) disorder represents the most common chronic pain syndrome within this patient population.2–7 PTH disorders are highly prevalent across all grades of TBI severity.8 Mild and moderate TBI is more prevalent compared to severe cases of TBI; however, there is a current controversy surrounding epidemiologic reports that cite a higher incidence of PTH for mild TBI compared with moderate and severe cases. A recent prospective 12-month study of TBI patients provides compelling evidence that the prevalence of PTH is unrelated to injury severity.9 Important aspects of PTH to consider relate to the time-course of this disorder. In many patients, it resolves in 3 months; in others, it persists for much longer. Currently, PTH, as classified by the International Classification of Headache Disorders, is defined as headache secondary to head trauma that develops within 7 days after injury or regaining consciousness. TBI is a risk factor for acute episodic headache (headache occurring less than 15 days/month) persisting less than 3 months transitioning into chronic headache (≥15 days/month).10,11 Clinical evidence suggest that the persistence of PTH beyond the expected tissue-healing time-course would argue for its chronicity, as well as mechanisms of central sensitization.12–14 A recent prospective study found the onset of PTH occurred between 7 and 30 days after injury or later in nearly half of patients.15 A study by Ofek and Defrin found that patients with TBI had a mean onset of chronic pain, including head pain, just over 6 months after injury.14 Headache was reported at 3, 6, and 12 months in 41% of patients with TBI in a study by Hoffman and colleagues.9 Studies using quantitative sensory testing (eg, von Frey mechanical stimuli for allodynia [cutaneous sensitivity to mechanical stimuli that are innocuous under normal conditions]) show that 40% of patients with TBI experience chronic head and face pain after head injury.14,16 Significant reductions in pressure-pain thresholds were found at least 1 year after mild-to-moderate TBI.16 To date, investigations into the proposed mechanisms and treatments for PTH have been impeded by a lack of preclinical models. Therefore, a research initiative implemented by our laboratory is to study mechanisms of PTH and its chronification using a well-known animal model of TBI, controlled cortical impact (CCI) injury. Headache pain, whether acute or chronic, involves abnormal activation of the trigeminovascular system. Using a model of diffuse TBI, Hall and Lifshitz have characterized hypersensitivity of the whiskers to be associated with neuroplasticity in the cortical barrel circuit and thalamus.17 Peripheral axons of the trigeminal ganglion innervate the peri-orbital skin, facial whiskers, anterior scalp, meninges, and cerebral vasculature. Periorbital and facial allodynia have been well-documented in rodent migraine models following infusion of an inflammatory soup over the meninges.18–20 Afferent fibers of the trigeminal ganglia relay nociceptive information to the trigeminal nuclei in which the neuropeptides, calcitonin gene-related peptide (CGRP) and substance P (SP), play important roles. CGRP and SP are also important in normal physiologic and pathologic function including cerebrovascular regulation and the development of neurogenic inflammation.21–26 CGRP has been particularly well-studied for its role in primary headache disorders such as migraine.27,28 To date, preclinical studies examining allodynia and the potential role of CGRP and SP in PTH are nonexistent. This study aimed to characterize periorbital sensory changes to mechanical stimuli (allodynia) and neuroplasticity in the brainstem in a mouse model of TBI, as this has not yet been reported in any model of TBI. The present study tests the hypothesis that focal injury to the somatosensory cortex will be associated with increased neuropeptides within the brainstem trigeminal nucleus caudalis and periorbital allodynia in a mouse model of CCI injury. The time-course for macrophage/microglial and astrocyte responses in the somatosensory cortex after CCI were examined because these cell populations are a potential cellular source of mediators (eg, cytokines, nitric oxide [NO], excitatory amino acids) of nociceptor sensitization known to contribute to behavioral morbidity. The pattern of periorbital allodynia over 4 weeks in mice with CCI and those undergoing a craniotomy only was characterized, while changes in the nociceptive neuropeptides, CGRP, and SP within the brainstem were determined. The temporal relationships between periorbital sensory changes (allodynia), central nociceptive neuropeptides, and gliosis (macrophage/microglia and astrocyte activation) were examined.