1. What is Behavioral Neuroscience?
Chapter One
What is Behavioral Neuroscience?

2. Neuroscience as an Interdisciplinary Field
“The scientific study of the brain and nervous system, in health and in disease” (UCLA, 2000)
Incorporates the fields of psychology, biology, chemistry, medicine, mathematics, physics, engineering, and computer science

3. From Molecules to Behavior
The functions of the brain and nervous system are studied on many different levels
Figure 1.1 The Neurosciences: Building from Molecule to Behavior. (Laura Freberg)

4. Historical Highlights in Neuroscience
Ancient milestones
Trepanation
Egyptian medical papyrus; mummification
Ancient Greeks: Hippocrates, Galen
The dawn of scientific reasoning
Descartes ( ): mind-body dualism
Van Leeuwenhoek
Galvani and du Bois-Reymond
Bell and Magendie

5. Prehistoric Brain Surgery
Figure 1.2 Prehistoric Brain Surgery. As far back in history as 7,000 years ago, people used trepanation (trephining) or the drilling of holes in the skull, perhaps to cure “afflictions” such as demonic possession. Regrowth around some of the holes indicates that at least some of the patients survived the procedure. More recently, trephining has resurfaced as a DIY (do it yourself) process, possibly as a type of self-injurious behavior. (San Diego Museum of Man)

6. Galvani – the Role of Electricity in Neural Communication
Figure 1.3 Luigi Galvani Demonstrated a Role for Electricity in Neural Communication. This engraving illustrates the basement laboratory of Luigi Galvani, where his experiments with frogs helped establish understanding of the electrical nature of neural communication. (Time Life Pictures/Mansell/Time Life Pictures/Getty Images)

7. Modern Neuroscience Begins
Santiago Ramón y Cajal and Camillo Golgi
The Neuron Doctrine
Gall and Spurzheim: phrenology
Paul Broca
Fritsch and Hitzig
John Hughlings-Jackson ( )
Founding of modern neuroscience
Sherrington, Loewi, Eccles, Katz, Huxley, Hodgkin

8. Phrenology Bust
Figure 1.4: Phrenology Bust. Franz Josef Gall and his followers used busts like this one to identify traits located under different parts of the skull. Bumps on the skull were believed to indicate that the underlying trait had been “exercised.” Although Gall’s system was an example of very bad science, the underlying principle that functions could be localized in the brain turned out to be valuable. (Bettman/CORBIS)

9. Behavioral Neuroscience Research Methods – Histology
The study of microscopic structures and tissues
Provides the means for observing structure, organization, and connections of individual cells
Tissue fixation, microtome machine, and specialized stains

10. Tissue Sectioning using a Microtome
Figure 1.5 Using a Microtome to Section Patient H.M.’s Brain. Researchers at UC San Diego broadcast the careful sectioning of the brain of the late Henry Molaison, otherwise known as the famous amnesic patient, H.M., via streaming video on the Internet. Molaison’s temporal lobe surgery and resulting memory deficits he experienced are familiar to all students of psychology. (The Brain Observatory)

11. Behavioral Neuroscience Research Methods – Autopsy
Examination of the body after death
Correlational method that must be interpreted carefully and precisely

12. Behavioral Neuroscience Research Methods – Imaging
Types of imaging technologies
Computerized tomography (CT)
Positron emission tomography (PET)
Magnetic resonance imaging (MRI)
Functional MRI (fMRI)
Diffusion tensor imaging (DTI)
Advantage of imaging over autopsy
Can watch the living brain as it behaves

13. CT Scans – Historical and Modern
Figure 1.6 CT Scans. Hounsfield’s original machine took several hours to obtain data for a single slice (above). Modern scanning equipment is much faster, and can produce detailed 3-D images (bottom). (Siemens Healthcare; GJLP, CNRI/Science Source)

14. PET Scans Show Patterns of Brain Activation
Figure 1.7 PET Scans Show Patterns of Brain Activation. PET scans do not provide much structural detail, but they do offer a clear picture of brain activity. Red and yellow areas are most active, whereas blue and black areas are least active. These three images show different patterns of brain activity during a visual task, a listening task, and a problem-solving task. (Dept. of Energy Office of Public Affairs)

15. Functional MRI (fMRI) Tracks Cerebral Blood Flow
Figure 1.8 Functional Magnetic Resonance Imaging (fMRI) Tracks Cerebral Blood Flow. This image demonstrates the use of fMRI to identify parts of the brain (the red and yellow areas) that became selectively active when the author engaged in a “finger tap” exercise (touching each digit of her right hand one by one with her thumb). (Laura Freberg)

16. Diffusion Tensor Imaging (DTI) Constructs Maps of the Brain’s Fiber Pathways
Figure 1.9 Diffusion Tensor Imaging (DTI). Using MRI technology, the flow of water down the length of nerve fibers can be imaged to construct maps of the fiber pathways of the brain. (Parkinson Research Foundation)

17. Recording Records electrical and magnetic output from the brain
Electroencephalogram (EEG)
Event-related potentials
Magnetoencephalography (MEG)
Single-cell recordings

18. Event-Related Potentials (ERPs)
Figure 1.10 Event-Related Potentials (ERPs). The analysis of event-related potentials allows researchers to map the brain’s EEG response to environmental stimuli. In this example, a characteristic waveform emerges when responses to the presentation of a tone are averaged over 100 trials. (© 2016 Cengage Learning®)

19. Magnetoencephalography (MEG)
Figure 1.11 Magnetoencephalography. (a) To record the tiny magnetic fields generated by the brain, a series of supercooled sensors known as superconducting quantum intererence devices (SQUIDs) are arrayed around the participant’s head. (b) This sequence illustrates the process of using MEG to record a participant’s response to a tone. (© 2016 Cengage Learning®)

20. Brain Stimulation
Artificial stimulation of specific brain regions and observation of resulting behavior
Surface electrodes during neurosurgery
Surgically implanted electrodes
Repeated transcranial magnetic stimulation (rTMS)
Optogenetics

21. Deep Brain Stimulation and rTMS
Figure 1.12 (left) Deep Brain Stimulation. In research, brain stimulation is typically used to identify the possible functions of a part of the brain. Recently, brain stimulation has been used to treat Parkinson’s disease and, less frequently, major depressive disorder. (Living Art Enterprises/Science Source)
Figure 1.13 (right) Repeated Transcranial Magnetic Stimulation (rTMS). Repeated TMS changes the activity of the cortex underlying the stimulator. The technique is used for research purposes and potentially could be used for treating hallucination, depression, and migraine headaches. (AP Images/Charles Krupa, File)

22. Lesions Lesion: injury to neural tissue Ablation
Naturally occurring
Deliberately produced
Ablation
Surgical removal of neural tissue
Figure 1.14 Lesion. To investigate the function of a particular part of the brain (a), radio frequency current is passed through the tips of insulated electrodes that have been surgically implanted (b). Resulting changes in behavior are correlated with the lesions produced (c). (© 2016 Cengage Learning®)

23. Other Research Methods
Biochemical methods
Use of chemical stimulation and microdialysis
Genetic methods
Twin studies (concordance rates)
Adoption studies (heritability)
Studies of genetically-modified animals (knockout genes)
Epigenetics (gene expression due to external factors)

24. Other Research Methods (cont’d.)
Stem cells
Undifferentiated cells that can divide and differentiate into other types of cells
One of the most promising approaches to understanding neural development, regeneration, and disease
Embryonic or adult: advantages and disadvantages of both
Can be used to repair the nervous system

25. Research Ethics in Behavioral Neuroscience
Mechanisms for protection of human participants and animal research subjects
Hippocrates
Federal government and the Common Rule
University review and institutional review boards

26. Research Ethics – Human Participants
Coercion of research participants is unacceptable
Benefits to participants should not be “excessive or inappropriate”
Participants must be informed that they can leave without penalty at any time
Participants must be told enough about the experiment to make an informed decision about participating

27. Research Ethics – Human Participants (cont’d.)
Participants must receive contact information in case they have questions
Participants must be assured their data will be confidential

28. Research Ethics – Animal Subjects
Animal research should have a clear scientific purpose
Excellent care and housing should be provided
Experimental procedures should cause as little pain and distress as possible