7,86 These findings in drug addiction and OCD beg an important question; if both conditions can be explained, at least in part, by an enhancement
of habit-like learning or a dysregulation of the balance between learning systems, then why are they so manifestly different from a clinical perspective? This is an important question for further study. #trans-isomer mouse keyword# Conclusion In this brief review, we have sought to illustrate several instances in which dysregulation of mnemonic processes and the mechanisms of neuroplasticity contribute to prevalent neuropsychiatric diseases. As illustrated in the foregoing discussion, reduced, enhanced, and unbalanced plasticity can all potentially lead to psychopathology. This discussion has by no means been comprehensive—there are other disorders that might be chosen to illustrate the
connections between neuroplasticity Inhibitors,research,lifescience,medical and psychopathology, and each of the individual topics sketched above could be an ample focus for a lengthy review in its own Inhibitors,research,lifescience,medical right. The reader is directed to the various recent references provided for more detail. However, these examples serve to illustrate that advances in the basic science of synaptic plasticity, neurogenesis, memory systems, and related processes may lead very directly to new insight into a number of psychiatric diseases and, potentially, to new therapeutic strategies.
Drug addiction, which Inhibitors,research,lifescience,medical can be defined as the compulsive seeking and taking of drugs despite horrendous consequences or loss of control over drug use, is caused by long-lasting drug-induced changes that occur in certain brain regions.1 Only some individuals, however, succumb to addiction in the face of repeated drug exposure, while Inhibitors,research,lifescience,medical others are capable of using a drug casually and escaping an addiction syndrome. Genetic factors account for roughly 50% of this individual variability in addiction vulnerability, and this degree of heritability holds true for all major classes of addictive drugs, including stimulants, opiates, alcohol, nicotine, and cannabinoids.2
It has not yet been possible to identify most of the genes that comprise this genetic Dichloromethane dehalogenase risk, likely due to the involvement of perhaps hundreds of genetic variations summating in a single individual to confer addiction vulnerability (or, in other individuals, resistance). The other 50% of the risk for addiction is due to a host of environmental factors, occurring throughout a lifetime, that interact with an individual’s genetic composition to render him or her vulnerable to addiction to a greater or lesser extent. Several types of environmental factors have been implicated in addiction, including psychosocial stresses, but by far the most powerful factor is exposure to a drug of abuse itself.