Central sensitization is important for development and maintenance of mechanical hyperalgesia in inflammatory, neuropathic and chronic widespread pain. The supraspinal mechanism for central sensitization is not completely understood in most pain models. Enhanced pain-related synaptic transmission from parabrachial area (PB) to central nucleus of amygdala (CeA) has been demonstrated in inflammatory and neuropathic pain. It has been shown that manipulation of ERK activity in CeA can alter the mechanical hyperlagesia induced by formalin in mice. We have recently shown that acid-induced chronic mechanical hyperalgesia also induced ERK activation in CeA and in the anterior nucleus of paraventricular thalamus (PVA) in mice. Blocking ERK activity in PVA blunts the chronic mechanical hyperalgesia. We therefore hypothesize ERK activation in PVA contributes to mechanical hyperalgesia in different pain models. To test this hypothesis, we examined the ERK activity in PVA in formalin-induced inflammatory pain and spared nerve injury (SNI)-induced neuropathic pain models and determined the association between ERK activation and mechanical hyperalgesia in female C57B6 mice. Our results showed that pERK staining in PVA were enhanced in both formalin- and SNI- induced mechanical hyperalgesia compared to their control. Manipulation ERK activity in PVA alters formalin-induced, SNI-induced and acid-induced persistent mechanical hyperaglesia. The direct infusion of PDBu in PVA induced mechanical but not thermal hyperaglesia in naive mice further pointed out the importance of PVA in nocicpetion transmission in brain circuit. Finally, the repeated infusion of PDBu in PVA induced the persistent mechanical hyperalgia strongly support that ERK activation in PVA plays a crucial role in modulation of mechanical hyperalgesia. The discovery of the importance of PVA in the central mechanism of nociceptive sensation is attributable not only to the basic understanding of pain perception but also to patients who are suffered from pain issues.