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Egyptian understanding and early Greek philosophers
Some of the first writings about the brain come from the Egyptians. In about 3000 BC the first known written description of the brain also indicated that the location of brain injuries may be related to specific symptoms. This document contrasted common theory at the time. Most of the Egyptians' other writings are very spiritual, describing thought and feelings as responsibilities of the heart. This idea was widely accepted and can be found into 17th century Europe.

Plato believed that the brain was the locus of mental processes. However, Aristotle believed instead the heart to be the source of mental processes and that the brain acted as a cooling system for the cardiovascular system.

Galen
In the Middle Ages, Galen was arguably one of the most influential scientists in regards to anatomy. In terms of neuroscience, Galen described the seven cranial nerves' functions along with giving a foundational understanding of the spinal cord. When it comes to the brain he believed that the sensation was caused in the middle of the brain, anterior brain produced the sensations, while the posterior of the brain produces motor sensation. Galen imparted some ideas on disordered mental health and its root cause. He believed that the cause was backed-up black bile and that epilepsy was caused by phlegm. Galen's observations on neuroscience were not challenged for many years.

Medieval European beliefs and Andreas Vesalius
Medieval beliefs generally held true the proposals of Galen, including the attribution of mental processes to specific ventricles in the brain. Functions of regions of the brain were defined based on their texture and composition: memory function was attributed to the posterior ventricle, a harder region of the brain and thus a good place for memory storage.

Andreas Vesalius redirected the study of neuroscience away from the anatomical focus; he considered the attribution of functions based on location crude. Pushing away from the superficial proposals made by Galen and medieval beliefs, Vesalius did not believe that studying anatomy would lead to any significant advances in the understanding of thinking and the brain.

Descartes - first proposal of the brain being connected to the nerves

Luigi Galvani and action potentials, also Humboldt, Emil du Bois Reymond

Golgi and Cajal, Golgi liked the reticular theory (intermeshed), Cajal liked the neuron doctrine.

Job description
Neuroscientists study neuroscience which is the study of the nervous system. The nervous system is composed of the brain, spinal cord and nerve cells. There are many approaches to the study of this system and they can be as focused as single ion channels or neurotransmitters or as broad as behavioral studies. A good portion of study is focused around diseases that affect the nervous system such as multiple sclerosis, Alzheimer's, Parkinson's, and Lou Gehrig's diseases. Research commonly occurs in private, government and public research institutions and universities.

Some common tasks for neuroscientists are:
 * Developing experiments and leading groups of people in supporting roles
 * Working with doctors to perform experimental studies of new drugs on willing patients
 * Research and development of new treatments for neurological disorders
 * Writing research proposals for grants
 * Following safety and sanitation procedures and guidelines
 * Dissecting experimental specimens

Salary
The overall median salary for neuroscientists was $79,940 in May 2014. Neuroscientists are usually full time employees. Below, median salaries for common work places are shown.

Work environment
Neuroscientists research and study both the psychology and biology/chemistry aspects of the brain and nervous system. Once neuroscientists finish their post doctoral programs, 39% go on to do more doctoral work, while 36% go into more faculty jobs. Neuroscientists use a wide range of computer programs and imaging such as magnetic resonance imaging, computed tomography angiography, and DTI.undefined Neuroscientists typically enter the realm of research and focus on illnesses ranging from psychological to biological. Imaging techniques allow scientists observe physical changes in the brain, as signals occur. Neuroscientists also can be part of several different neuroscience organizations where they can publish, and read different research topics.

Job outlook
Neuroscience is expecting a job growth of about 8% from 2014 to 2024. This is a fairly average job growth rate when compared to other professions. Factors leading to this growth are an aging population, new discoveries leading to new areas of research, and an increasing utilization of medications. Government funding for research will also continue to influence the demand for this specialty.

Education
Neuroscientists typically enroll in a four-year undergraduate program and then move on to a PhD program for graduate studies. There are many options such as combining a PhD with other programs like M.D. or D.M.D, along with many other health science programs. Once finished with their graduate studies, neuroscientists continue doing postdoctoral work to gain more lab experience and explore new laboratory methods. In their undergraduate years, neuroscientists typically take physical, and life sciences courses to gain a foundation in the field of research. Typical undergraduate majors include psychology, behavioral neuroscience, and cognitive neuroscience.

Interdisciplinary fields
Neuroscience has a unique perspective in that it can be applied in a broad range of disciplines, and thus the fields neuroscientists work in vary. They can span from studying the large hemispheres of the brain to neurotransmitters and synapses occurring in neurons at a micro-level. Some fields for example that combine these psychology and neurology are cognitive neuroscience, and behavorial neuroscience. Cognitive neuroscientists study the human consciousness, specifically the brain, and how it can be seen through a lens of biological and chemical processes. Behavorial neuroscience encompasses the whole nervous system, environment and the brain how these areas show us aspects of motivation, learning, and motor skills along with many others.

Current and developing research topics
Research in neuroscience is expanding and becoming increasingly interdisciplinary.

Many current research projects involve the integration of computer programs in mapping the human nervous system. The NIH sponsored Human Connectome Project, launched in 2009, hopes to establish a highly detailed map of the human nervous system and its millions of connections. Detailed neural mapping could lead the way for advances in the diagnosis and treatment of neurological disorders.

Neuroscientists are also at work studying Epigenetics and how certain factors that we face in our everyday lives not only affect us and our genes, but also how they will affect our children and change their genes to adapt to the environments we faced.

Behavioral and developmental studies
Neuroscientists have been working to show how the brain is far more elastic and able to change than we once might have thought. They have been using work that psychologists previously reported and are using that to show how the observations work, and give a model for it. One recent behavioral study is that of phenylketonuria (PKU), a disorder that heavily damages the brain due to high levels of the amino acid phenylalanine. Before neuroscientists had studied this disorder, psychologists did not have a mechanistic understanding as to how this disorder caused high levels of the amino acid and thus treatment was not well understood, and often times, was inadequate. The neuroscientists that studied this disorder used the previous observations of psychologists and used them to come up with a mechanistic model that gave better understanding of the disorder at the molecular level. This in turn led to better understanding of the disorder as a whole and greatly changed treatment that lead to better lives for patients with the disorder.

Another recent study was that of mirror neurons, neurons that fire when mimicking or observing another animal or person that is making some sort of expression, movement, gesture, etc. This study was again one where neuroscientists used the observations of psychologists to create a model for how the observation worked. The initial observation was that newborn infants mimicked facial expressions that were expressed to them. Scientists were not certain that newborn infants were developed enough to have complex neurons that allowed them to mimic different people and there was something else that allowed them to mimic expressions. Neuroscientists then did research to give a model for what was happening and it turned out that infants did in fact have these neurons that fired when watching and mimicking someone making a face at them or making some sort of expression.

Effects of early experience on the brain
Neuroscientists have also studied the effects of various effects of things like nurture have on the developing brain. Saul Schanberg and other neuroscientists did a study on how important nurturing touch is to the developing brains in rats. They found that the rats who were deprived of nurture from the mother for just one hour had reduced functions in things like DNA synthesis and hormone secretion.

Michael Meaney and his colleagues found that mother rats who give their offspring a lot of nurture and attention cause those offspring to show less fear, handle stressful situations better, and function higher and longer when they mature fully. They also found that the rats who were given a lot of attention to as adolescence also gave their offspring the same amount of attention and thus showed that rats raised their offspring similar to how they were raised. These studies were also seen on a microscopic level where different genes were expressed for the rats that were given high amounts of nurture and those same genes were not expressed in the rats who received less attention.

The effects of nurture and touch were not only studied in rats, but also in newborn humans. Many neuroscientists have performed studies where the importance of touch is show in newborn humans. The same results that were shown in rats, also held true for humans. Babies that received less touch and nurture developed slower than babies that received a lot of attention and nurture. Stress levels were also lower in babies that were nurtured regularly and cognitive development was also higher due to increased touch. Human offspring, much like rat offspring, thrive off of nurture, as shown by the various studies of neuroscientists.

Neuroscientists awarded Nobel Prizes in Physiology or Medicine

 * Camillo Golgi and Santiago Ramón y Cajal (1906) for the development of the silver staining method, revealing what would later be determined as individual neurons. Cajal's interpretations of the images produced by Golgi's staining technique led to the adoption of the neuron doctrine.


 * Charles Sherrington and Edgar Adrian (1932) for their discoveries of the general function of neurons, including excitatory and inhibitory signals, and the all-or-nothing response of nerve fibers.
 * Sir Henry Dale and Otto Loewi (1936) for the discovery of neurotransmitters and identification of acetylcholine.
 * Joseph Erlanger and Herbert Gasser (1944) for discoveries illustrating the varied timing exhibited by single nerve fibers.
 * Alan Hodgkin, Andrew Huxley, and Sir John Eccles (1963) for discovering the ionic basis of the action potential and macroscopic currents through their use of the squid giant axon.
 * Sir Bernard Katz, Ulf von Euler and Julius Axelrod (1970) for the discovery of the mechanisms responsible for neurotransmitter storage, release, and inactivation. Their work included the discovery of the synaptic vesicle and quantal neurotransmitter release.
 * Stanley Cohen and Rita Levi-Montalcini (1986) for their discovery of nerve growth factor (NGF) as well as epidermal growth factor (EGF).
 * Erwin Neher and Bert Sakmann (1991) for the development of the patch-clamp recording technique, allowing, for the first time, the observation of current flow through individual ion channels. Neher and Sakmann additionally characterized the specificity of ion channels.
 * Arvid Carlsson, Paul Greengard and Eric Kandel (2000) for the discovery of neural signal transduction pathways upon neurotransmitter binding, as well as the establishment of dopamine as a primary acting neurotransmitter.

Other famous neuroscientists

 * James Holmes, former Ph.D student in neuroscience and convicted mass murderer responsible for the 2012 Aurora theater shooting
 * William Williams Keen, first brain surgeon in the United States
 * Walter Freeman II, a student of Egas Moniz, popularized the lobotomy

Neuroscientists in popular culture

 * Victor Frankenstein, title character of Mary Shelley's 1818 novel Frankenstein; or, The Modern Prometheus
 * Amy Farrah Fowler, Ph.D, main character in CBS's The Big Bang Theory