Assessing objectively the neuroscience information presented to public at-large across various media outlets. Explaining the potential importance of these discoveries.

The field of neuroscience makes a special contribution to our understanding of the human condition, as it can both help us understand ourselves and also how we interact in a world of other individuals. Historically, there has been a dichotomy between disciplines that identify the abstract principles of the social world we live in and the biology of the organ (i.e., the central nervous system) we use to identify and coordinate those abstract principles as we function in our daily lives. By merging these disciplines and studying our interactions with the world on many layers of analysis, from genes to social dynamics, we can develop a richer understanding of who we are as people. prereq: None

Ethical implications. Readings, personal reflections, class discussions, debates, and formal writing. Development of logical arguments, writing skills, oral presentation skills, and teamwork. Students present/argue both their own personal views and those of others. What it is like to have altered mentation, i.e. a brain disease or disability. Readings/multimedia reports from primary neuroscience literature as well as philosophy, policy, and law literature and popular media.

This course is intended as an introduction to the new views on the relationship between mind and brain. Over the last several decades, a new view of cognition and neural processing has been developed based on the concepts of al¬gorithm, representation, computation, and information processing. Within this theoretical frame¬work, psychological constructs are computational processes occur¬ring across physical neural systems. We will take a neuroscience and psychological perspective in which the physical neuroscience instantiates but does not diminish the psychological constructs. Although our conceptual framework will be computational, this course will not require or expect any mathematical or computer background. At the completion of this class, you will understand the implications of the physical nature of the brain ? how mentation is explicable from physical processes, and how decision-making arises from those same physical processes. Importantly, you will also understand the limitations of current knowledge and the methodologies being used to push those limitations. This class is not intended as a final step in this understanding, but as a first step into these issues. At the conclusion of the class, you should have sufficient understanding to continue more in-depth reading and study in these issues. There are no official prerequisites. However, I have found that students who have EITHER a strong computational background (computer science, mathematics, economics, physics) OR have taken an introductory neuroscience course (e.g. Nsci 2100) have done better in the class than students with no background. However, I have seen students come in with very little background and do well in the class if they engage with the class and work hard.

This course will provide a broad introduction to the nervous system with an emphasis on the human nervous system. The course will introduce the structure and function of neurons, the major anatomical parts of the nervous system and the main functional systems. Functional systems will be approached through an understanding of the anatomical circuitry. The fundamental concepts of neurochemical communication studied in general terms in the first part of the course will be re-examined relative to specific functional systems later in the course. Although the major focus of the course will be on the normal nervous system, common diseases will be introduced for each main topic. Students will gain an understanding of the nature of many neurological diseases, which will provide further insight into how the normal nervous system functions. The neuronal substrates of learning/memory, addiction and drug actions will be examined. Through the lectures, discussions and other resources, students will be expected to gain an understanding of the neural circuitry and information processing responsible for the diverse range of human behaviors. The material covered in Nsci 2001 and 2100 is very similar. N2100 is taught only fall semester. It is a traditional lecture course that includes a weekly laboratory. The faculty believe that the laboratory is a valuable part of the course. N2001 is taught only spring semester for those who cannot take the fall course. It does not have a lab, but has the advantage of a flipped format. In N2001, students will be expected to watch the assigned lectures prior to coming to class. Class time will be spent on exercises and discussions that use the material presented in the online lectures. Students who take one of these two courses will not be allowed to take the other course. For more information, see http://mcloonlab.neuroscience.umn.edu/2001/index.htm

This course will provide a broad introduction to the nervous system with an emphasis on the human nervous system. The course will introduce the structure and function of neurons, the major anatomical parts of the nervous system and the main functional systems. Functional systems will be approached through an understanding of the anatomical circuitry. The fundamental concepts of neurochemical communication studied in general terms in the first part of the course will be re-examined relative to specific functional systems later in the course. Although the major focus of the course will be on the normal nervous system, common diseases will be introduced for each main topic. Students will gain an understanding of the nature of many neurological diseases, which will provide further insight into how the normal nervous system functions. The neuronal substrates of learning/memory, addiction and drug actions will be examined. Through the lectures, laboratory exercises and other resources, students will be expected to gain an understanding of the neural circuitry and information processing responsible for the diverse range of human behaviors. The material covered in Nsci 2001 and 2100 is very similar. N2100 is taught only fall semester. It is a traditional lecture course that includes a weekly laboratory. The faculty believe that the laboratory is a valuable part of the course. N2001 is taught only spring semester for those who cannot take the fall course. It does not have a lab, but has the advantage of a flipped format. In N2001, students will be expected to watch the assigned lectures prior to coming to class. Class time will be spent on exercises and discussions that use the material presented in the online lectures. Students who take one of these two courses will not be allowed to take the other course. For more information, see http://mcloonlab.neuroscience.umn.edu/2100/index.htm

Theoretical basis. Signal processing techniques. Modeling of nervous system, its response to stimulation. Electrode design, neural modeling, cochlear implants, deep brain stimulation. Prosthetic limbs, micturition control, prosthetic vision. Brain machine interface, seizure prediction, optical imaging of nervous system, place cell recordings in hippocampus. prereq: 3401 recommended

Evolutionary theory and behavioral genetics applied to understanding of development of human behavior; formation of species-typical adaptive behavior and individual differences in infancy, childhood, and adolescence. prereq: CPSY 2301 / 3301 or equiv

Concepts/principles of coordination/control of perceptually guided movement. Constraints imposed by properties of environment, body (including the nervous system), and goals of behavior. Why we move the way that we do. prereq: [3112, 3132, 3135, KIN major] or instr consent

The field of neuroscience makes a special contribution to our understanding of the human condition, as it can both help us understand ourselves and also how we interact in a world of other individuals. Historically, there has been a dichotomy between disciplines that identify the abstract principles of the social world we live in and the biology of the organ (i.e., the central nervous system) we use to identify and coordinate those abstract principles as we function in our daily lives. By merging these disciplines and studying our interactions with the world on many layers of analysis, from genes to social dynamics, we can develop a richer understanding of who we are as people. prereq: None

Ethical implications. Readings, personal reflections, class discussions, debates, and formal writing. Development of logical arguments, writing skills, oral presentation skills, and teamwork. Students present/argue both their own personal views and those of others. What it is like to have altered mentation, i.e. a brain disease or disability. Readings/multimedia reports from primary neuroscience literature as well as philosophy, policy, and law literature and popular media.

This course is intended as an introduction to the new views on the relationship between mind and brain. Over the last several decades, a new view of cognition and neural processing has been developed based on the concepts of al¬gorithm, representation, computation, and information processing. Within this theoretical frame¬work, psychological constructs are computational processes occur¬ring across physical neural systems. We will take a neuroscience and psychological perspective in which the physical neuroscience instantiates but does not diminish the psychological constructs. Although our conceptual framework will be computational, this course will not require or expect any mathematical or computer background. At the completion of this class, you will understand the implications of the physical nature of the brain ? how mentation is explicable from physical processes, and how decision-making arises from those same physical processes. Importantly, you will also understand the limitations of current knowledge and the methodologies being used to push those limitations. This class is not intended as a final step in this understanding, but as a first step into these issues. At the conclusion of the class, you should have sufficient understanding to continue more in-depth reading and study in these issues. There are no official prerequisites. However, I have found that students who have EITHER a strong computational background (computer science, mathematics, economics, physics) OR have taken an introductory neuroscience course (e.g. Nsci 2100) have done better in the class than students with no background. However, I have seen students come in with very little background and do well in the class if they engage with the class and work hard.

In-depth study of aspects of neurodevelopment, neurochemistry/molecular neuroscience, sensory systems, motor control, and behavioral neuroscience. Primarily for undergraduates majoring in neuroscience or related areas.

Study synapse as pharmacological gateway to nervous system. Explore physiology of/cellular signalling at synapse, how signalling influences conditions such as Parkinson's disease, depression, anxiety, pain, addiction. How various drugs modify signalling at synapse. recommend: [PHCL 2001, PHCL 3100]

Muscle molecular structure/function and disease. Muscle regulation, ion transport, and force generation. Muscular dystrophy and heart disease. prereq: PHSL 3061 or PHSL 5061 or BioC 3021, BIOL 3021 or BIOL 4331 or instr consent

Neurophysiology/neuroanatomy, neural mechanisms of motivation, emotion, sleep-wakefulness cycle, learning/memory in animals/humans. Neural basis of abnormal behavior, drug abuse. prereq: 1001 or BIOL 1009 or NSci 1100

Introduction to affective neuroscience. How brain promotes emotional/motivated behavior in animals/humans. Biological theories of emotion in historical/current theoretical contexts. Fundamental brain motivational systems, including fear, pleasure, attachment, stress, and regulation of motivated behavior. Implications for emotional development, vulnerability to psychiatric disorders. prereq: 3061 or 5061 or instr consent

Survey of anatomy and physiology of the auditory and speech production systems, including the nervous, respiratory, laryngeal, velopharyngeal and orofacial subsystems. Emphasis on normal processes and functions.

Basic neuroanatomy and neurophysiology, especially as they relate to normal speech, language, and hearing processes.

This course will provide a broad introduction to the nervous system with an emphasis on the human nervous system. The course will introduce the structure and function of neurons, the major anatomical parts of the nervous system and the main functional systems. Functional systems will be approached through an understanding of the anatomical circuitry. The fundamental concepts of neurochemical communication studied in general terms in the first part of the course will be re-examined relative to specific functional systems later in the course. Although the major focus of the course will be on the normal nervous system, common diseases will be introduced for each main topic. Students will gain an understanding of the nature of many neurological diseases, which will provide further insight into how the normal nervous system functions. The neuronal substrates of learning/memory, addiction and drug actions will be examined. Through the lectures, laboratory exercises and other resources, students will be expected to gain an understanding of the neural circuitry and information processing responsible for the diverse range of human behaviors. The material covered in Nsci 2001 and 2100 is very similar. N2100 is taught only fall semester. It is a traditional lecture course that includes a weekly laboratory. The faculty believe that the laboratory is a valuable part of the course. N2001 is taught only spring semester for those who cannot take the fall course. It does not have a lab, but has the advantage of a flipped format. In N2001, students will be expected to watch the assigned lectures prior to coming to class. Class time will be spent on exercises and discussions that use the material presented in the online lectures. Students who take one of these two courses will not be allowed to take the other course. For more information, see http://mcloonlab.neuroscience.umn.edu/2100/index.htm

This course will provide a broad introduction to the nervous system with an emphasis on the human nervous system. The course will introduce the structure and function of neurons, the major anatomical parts of the nervous system and the main functional systems. Functional systems will be approached through an understanding of the anatomical circuitry. The fundamental concepts of neurochemical communication studied in general terms in the first part of the course will be re-examined relative to specific functional systems later in the course. Although the major focus of the course will be on the normal nervous system, common diseases will be introduced for each main topic. Students will gain an understanding of the nature of many neurological diseases, which will provide further insight into how the normal nervous system functions. The neuronal substrates of learning/memory, addiction and drug actions will be examined. Through the lectures, discussions and other resources, students will be expected to gain an understanding of the neural circuitry and information processing responsible for the diverse range of human behaviors. The material covered in Nsci 2001 and 2100 is very similar. N2100 is taught only fall semester. It is a traditional lecture course that includes a weekly laboratory. The faculty believe that the laboratory is a valuable part of the course. N2001 is taught only spring semester for those who cannot take the fall course. It does not have a lab, but has the advantage of a flipped format. In N2001, students will be expected to watch the assigned lectures prior to coming to class. Class time will be spent on exercises and discussions that use the material presented in the online lectures. Students who take one of these two courses will not be allowed to take the other course. For more information, see http://mcloonlab.neuroscience.umn.edu/2001/index.htm