Neuropsychopharmacology, an interdisciplinary science related to psychopharmacology (how drugs affect the mind) and fundamental neuroscience, is the study of the neural mechanisms that drugs act upon to influence behavior. It entails research of mechanisms of neuropathology, pharmacodynamics (drug action), psychiatric illness, and states of consciousness. These studies are instigated at the detailed level involving neurotransmission/receptor activity, bio-chemical processes, and neural circuitry. Neuropsychopharmacology supersedes psychopharmacology in the areas of "how" and "why", and additionally addresses other issues of brain function. Accordingly, the clinical aspect of the field includes psychiatric (psychoactive) as well as neurologic (non-psychoactive) pharmacology-based treatments. Developments in neuropsychopharmacology may directly impact the studies of anxiety disorders, affective disorders, psychotic disorders, degenerative disorders, eating behavior, and sleep behavior.

History

Drugs such as opium, alcohol, and certain plants have been used for millennia by humans to ease suffering or change awareness, but until the modern scientific era knowledge of how the substances actually worked was quite limited, most pharmacological knowledge being more a series of observation than a coherent model. The first half of the 20th century saw psychology and psychiatry as largely phenomenological, in that behaviors or themes which were observed in patients could often be correlated to a limited variety of factors such as childhood experience, inherited tendencies, or injury to specific brain areas. Models of mental function and dysfunction were based on such observations. Indeed, the behavioral branch of psychology dispensed altogether with what actually happened inside the brain, regarding most mental dysfunction as what could be dubbed as "software" errors. In the same era, the nervous system was progressively being studied at the microscopic and chemical level, but there was virtually no mutual benefit with clinical fields—until several developments after World War II began to bring them together. Neuropsychopharmacology may be regarded to have begun in the earlier 1950s with the discovery of drugs such as MAO inhibitors, tricyclic antidepressants, thorazine and lithium which showed some clinical specificity for mental illnesses such as depression and schizophrenia. Until that time, treatments that actually targeted these complex illnesses were practically non-existent. The prominent methods which could directly affect brain circuitry and neurotransmitter levels were the prefrontal lobotomy, and electroconvulsive therapy, the latter of which was conducted without muscle relaxants and both of which often caused the patient great physical and psychological injury.

The field now known as neuropsychopharmacology has resulted from the growth and extension of many previously isolated fields which have met at the core of psychiatric medicine, and engages a broad range of professionals from psychiatrists to researchers in genetics and chemistry. The use of the term has gained popularity since 1990 with the founding of several journals and institutions such as the Hungarian College of Neuropsychopharmacology. This rapidly maturing field shows some degree of flux, as research hypotheses are often restructured based on new information

Neurotransmission

So far as we know, everything we perceive, feel, think, know, and do are a result of neurons firing and resetting. When a cell in the brain fires, small chemical and electrical swings called the action potential may affect the firing of as many as a thousand other neurons in a process called neurotransmission. In this way signals are generated and carried through networks of neurons, the bulk electrical effect of which can be measured directly on the scalp by an EEG device.

By the last decade of the 20th century, the essential knowledge of all the central features of neurotransmission had been gained. These features are:

The synthesis and storage of neurotransmitter substances,

The transport of synaptic vesicles and subsequent release into the synapse,

Receptor activation and cascade function,

Transport mechanisms (reuptake) and/or enzyme degradation

The more recent advances involve understanding at the organic molecular level; biochemical action of the endogenous ligands, enzymes, receptor proteins, etc. The critical changes affecting cell firing occur when the signalling neurotransmitters from one neuron, acting as ligands, bind to receptors of another neuron. Many neurotransmitter systems and receptors are well known, and research continues toward the identification and characterization of a large number of very specific subtypes of receptors. For the six more important neurotransmitters Glu, GABA, Ach, NE, DA, and 5HT (listed at neurotransmitter) there are at least 29 major subtypes of receptor. Further "sub-subtypes" exist together with variants, totalling in the hundreds for just these 6 transmitters. - (see serotonin receptor for example.) It is often found that receptor subtypes have differentiated function, which in principle opens up the possibility of refined intentional control over brain function.

It has previously been known that ultimate control over the membrane voltage or potential of a nerve cell, and thus the firing of the cell, resides with the transmembrane ion channels which control the membrane currents via the ions K+, Na+, and Ca++, and of lesser importance Mg++ and Cl−. The concentration differences between the inside and outside of the cell determine the membrane voltage.

Abstract simplified diagram showing overlap between neurotransmission and metabolic activity. Neurotransmitters bind to receptors which cause changes to ion channels (black, yellow), metabotropic receptors also affect DNA transcription (red), transcription is responsible for all cell proteins including enzymes which manufacture neurotransmitters (blue).

Precisely how these currents are controlled has become much clearer with the advances in receptor structure and G-protein coupled processes. Many receptors are found to be pentameric clusters of five transmembrane proteins (not necessarily the same) or receptor

subunits, each a chain of many amino acids. Transmitters typically bind at the junction between two of these proteins, on the parts that protrude from the cell membrane. If the receptor is of the ionotropic type, a central pore or channel in the middle of the proteins will be mechanically moved to allow certain ions to flow through, thus altering the ion concentration difference. If the receptor is of the metabotropic type, G-proteins will cause metabolism inside the cell that may eventually change other ion channels. Researchers are better understanding precisely how these changes occur based on the protein structure shapes and chemical properties.

The scope of this activity has been stretched even further to the very blueprint of life since the clarification of the mechanism underlying gene transcription. The synthesis of cellular proteins from nuclear DNA has the same fundamental machinery for all cells; the exploration of which now has a firm basis thanks to the Human Genome Project which has enumerated the entire human DNA sequence, although many of the estimated 35,000 genes remain to be identified. The complete neurotransmission process extends to the genetic level. Gene expression determines protein structures through type II RNA polymerase. So enzymes which synthesize or breakdown neurotransmitters, receptors, and ion channels are each made from mRNA via the DNA transcription of their respective gene or genes. But neurotransmission, in addition to controlling ion channels either directly or otherwise through metabotropic processes, also actually modulates gene expression. This is most prominently achieved through modification of the transcription initiation process by a variety of transcription factors produced from receptor activity.

Aside from the important pharmacological possibilities of gene expression pathways, the correspondence of a gene with its protein allows the important analytical tool of gene knockout. Living specimens can be created using homolog recombination in which a specific gene cannot be expressed. The organism will then be deficient in the associated protein which may be a specific receptor. This method avoids chemical blockade which can produce confusing or ambiguous secondary effects so that the effects of a lack of receptor can be studied in a purer sense.

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