Students are introduced to the structure and organisation of the central and peripheral nervous system. The course begins with an exploration into the make-up of the individual cells, followed by an examination of the different regions of the nervous system. A final theme of the course touches on the organisation of various systems (sensory and motor), together with aspects of higher-order function such as memory and language. In essence, the subject covers general concepts of organisation, structure and function of the brain. The laboratory practical sessions offer students the special privilege to examine human specimens in the Anatomy labs and museum. Tutorial meetings will provide the opportunity to encounter topics in functional anatomy and histology of the brain using photographs, diagrams, models, animations and problem-solving. Topics in identification of central nervous system structure in typical magnetic resonance images will assist in reinforcing the theory of functional anatomy in a format students are likely to encounter in further study, in real-world situations and readings. This course will be of considerable interest to students studying anatomy and related disciplines, as well as those wishing to pursue further study in Neuroscience at senior levels.

Students are introduced to the structure and organisation of the central and peripheral nervous system. The course begins with an exploration into the make-up of the individual cells, followed by an examination of the different regions of the nervous system. A final theme of the course touches on the organisation of various systems (sensory and motor), together with aspects of higher-order function such as memory and language. In essence, the subject covers general concepts of organisation, structure and function of the brain. The laboratory practical sessions offer students the special privilege to examine human specimens in the Anatomy labs and museum. Tutorial meetings will provide the opportunity to encounter topics in functional anatomy and histology of the brain using photographs, diagrams, models, animations and problem-solving. Topics in identification of central nervous system structure in typical magnetic resonance images will assist in reinforcing the theory of functional anatomy in a format students are likely to encounter in further study and in real-world situations and readings. This course will be of considerable interest to students studying anatomy and related disciplines, as well as those wishing to pursue further study in Neuroscience at senior levels.

Without cells, life as we know it would not exist. These dynamic assemblies, packed with biological molecules are constantly in action. But how do cells work? Why is the food that you eat so important for cellular function? How is information transmitted from generation to generation? And, what happens as a result of disease or genetic mutation? In this unit of study you will learn how cells work at the molecular level, with an emphasis on human biochemistry and molecular biology. We will focus initially on cellular metabolism and how cells extract and store energy from fuels like fats and carbohydrates, how the use of fuels is modulated in response to exercise, starvation and disease, and how other key metabolites are processed. Then we will explore how genetic information is regulated in eukaryotes, including replication, transcription and translation, and molecular aspects of the cell cycle, mitosis and meiosis. Our practicals, along with other guided and online learning sessions will introduce you to widely applied and cutting edge tools that are essential for modern biochemistry and molecular biology. By the end of this unit you will be equipped with foundational skills and knowledge to support your studies in the life and medical sciences.

Without cells, life as we know it would not exist. These dynamic assemblies, packed with biological molecules are constantly in action. But how do cells work? Why is the food that you eat so important for cellular function? How is information transmitted from generation to generation? And, what happens as a result of disease or genetic mutation? In this unit of study you will learn how cells work at the molecular level, with an emphasis on human biochemistry and molecular biology. We will focus initially on cellular metabolism and how cells extract and store energy from fuels like fats and carbohydrates, how the use of fuels is modulated in response to exercise, starvation and disease, and how other key metabolites are processed. Then we will explore how genetic information is regulated in eukaryotes, including replication, transcription and translation, and molecular aspects of the cell cycle, mitosis and meiosis. The advanced laboratory component will provide students with an authentic research laboratory experience while in the theory component, current research topics will be presented in a problem-based format through dedicated advanced tutorial sessions. This material will be assessed by creative student-centered activities supported by eLearning platforms.

The era of genomics has revolutionised our approach to biology. Recent breakthroughs in genetics and genomic technologies have led to improvements in human and animal health, in breeding and selection of economically important organisms and in the curation and care of wild species and complex ecosystems. In this unit, students will investigate/describe ways in which modern biology uses genetics and genomics to study life, from the unicellular through to complex multicellular organisms and their interactions in communities and ecosystems. This unit includes a solid foundation in classical Mendelian genetics and its extensions into quantitative and population genetics. It also examines how our ability to sequence whole genomes has changed our capacities and our understanding of biology. Links between DNA, phenotype and the performance of organisms and ecosystems will be highlighted. The unit will examine the profound insights that modern molecular techniques have enabled in the fields of developmental biology, gene regulation, population genetics and molecular evolution.

The era of genomics has revolutionised our approach to biology. Recent breakthroughs in genetics and genomic technologies have led to improvements in human and animal health, in breeding and selection of economically important organisms and in the curation and care of wild species and complex ecosystems. In this unit, students will investigate/describe ways in which modern biology uses genetics and genomics to study life, from the unicellular through to complex multicellular organisms and their interactions in communities and ecosystems. This unit includes a solid foundation in classical Mendelian genetics and its extensions into quantitative and population genetics. It also examines how our ability to sequence whole genomes has changed our capacities and our understanding of biology. Links between DNA, phenotype and the performance of organisms and ecosystems will be highlighted. The unit will examine the profound insights that modern molecular techniques have enabled in the fields of developmental biology, gene regulation, population genetics and molecular evolution. The Advanced mode of Genetics and Genomics will provide you with challenge and a higher level of academic rigour. You will have the opportunity to plan and carry out a project that will develop your skills in contemporary genetics/molecular biology techniques and will provide you with a greater depth of disciplinary understanding. The Advanced mode will culminate in a written report and in an oral presentation where you will discuss a recent breakthrough that has been enabled by the use of modern genetics and genomics technologies. This is a unit for anyone wanting to better understand the how genetics has shaped the earth and how it will shape the future.

This unit of study provides the fundamental grounding in four basic areas in Pharmacology: (1) principles of drug action (2) pharmacokinetics and drug metabolism (3) experimental design and autonomic pharmacology, and (4) drug design. The delivery of material involves lectures, practicals, computer-aided learning and problem-based workshops. Practical classes provide students with the opportunity of acquiring technical experience and teamwork skills. Problem-based workshops are based on real-life scenarios of drug use in the community. These workshops require students to integrate information obtained in lectures in order to provide solutions to the problems. Online quizzes accompany each module and are to encourage continued learning throughout the semester.

This unit of study examines four important areas of Pharmacology: (1) Principles of drug action in the nervous system; (2) Drug abuse, addiction and analgesia; (3) Drug treatment of allergies and GI disorders; (4) Introduction to drug discovery and development. The delivery of material involves lectures, practicals, computer-aided learning and problem-based workshops. Practical classes provide students with the opportunity of acquiring technical experience and teamwork skills. Problem-based workshops are based on real-life scenarios of drug use in the community. These workshops require students to apply information obtained in lectures and readings in order to 'solve' the problems. Workshop activities will include oral presentations.

This unit of study offers an introduction to the basic concepts underpinning physiology, excitable cell (nerve and muscle) physiology, as well as the functions of the nervous system (central processing, and sensory and motor systems). It also incorporates cardiovascular and exercise physiology. The practical component involves experiments on humans and isolated tissues, with an emphasis on hypothesis generation and data analysis. Tutorial sessions develop critical thinking, the integrative nature of physiology, and generic skills in scientific writing and presentation. The practicals and tutorials also emphasise group learning and team work.

This unit of study is an extension of PHSI2005 for talented students with an interest in Physiology and Physiological research. The lecture component of the course is run in conjunction with PHSI2005. This unit of study offers a basic introduction to the functions of the nervous system, excitable cell (nerve and muscle) physiology, sensory and motor systems, and central processing. It also incorporates haematology and cardiovascular physiology. The practical component involves experiments on humans and isolated tissues, with an emphasis on hypothesis generation and data analysis. Inquiry-based learning sessions develop critical thinking and generic skills while demonstrating the integrative nature of physiology. Oral and written communication skills are emphasized, as well as group learning and team work. The course will provide an opportunity for students to apply and extend their understanding of physiological concepts by designing and conducting actual experiments. Small class sizes will provide a chance for students to interact directly with faculty members mentoring the practical sessions. Assessment for this stream will be based on oral group presentations and two practical reports. These items will replace some other assessable activities from the regular course.

This unit of study offers a basic introduction to the functions of the remaining body systems: gastrointestinal, respiratory, haematology, endocrine, reproductive and renal. The practical component involves experiments on humans and computer simulations, with an emphasis on hypothesis generation and data analysis. The tutorial sessions develop critical thinking and graduate attributes while demonstrating the integrative nature of physiology. Oral and written communication skills are emphasized, as well as group learning and team work.

This unit of study is an extension of PHSI2006 for talented students with an interest in Physiology and Physiological research. The lecture component of the course is run in conjunction with PHSI2006. This unit of study gives a basic introduction to the remaining of the body systems: gastrointestinal, respiratory, endocrine, reproductive and renal. The practical component involves simple experiments on humans, isolated tissues, and computer simulations, with an emphasis on hypothesis generation and data analysis. Both oral and written communication skills are emphasised, as well as group learning. The course will provide an opportunity for students to apply and extend their understanding of physiological concepts by designing and conducting actual experiments. Small class sizes will provide a chance for students to interact directly with faculty members mentoring the practical sessions. Assessment for this stream will be based on oral group presentations and two practical reports. These items will replace some other assessable activities from the regular course.

This Unit of Study examines a range of phenomena and principles in behaviour, learning and perception, abnormal psychology and their relations to underlying neural substrates. The emphasis in learning is on instrumental conditioning and the principle of reinforcement, ranging from applications of this principle to its neural substrates. Also covered are motivational aspects of behaviour, such as punishment and avoidance. The Abnormal Psychology section will focus on emotional and motivational disorders, such as anxiety and depression, addiction, sex and appetite, together with related neurochemical mechanisms and the effects of various psychopharmacological agents on these processes. A number of perceptual phenomena will be studied, such as motion detection, recognition of faces, identification of emotion, hearing and hearing loss, taste discrimination, and chronic pain. The practical classes are designed for students with an interest in clinical and therapeutic Psychology, and will allow students to design and implement a behaviour modification programme.

This Unit of Study focuses on the Behavioural Sciences, Neurosciences, Abnormal Psychology and the study of perception. The lecture content is the same as PSYC2011, and examines a range of phenomena and principles in behaviour, learning and perception, and their relations to underlying neural substrates. The emphasis in learning is on instrumental conditioning and the principle of reinforcement, ranging from applications of this principle to its neural substrates. Also covered are motivational aspects of behaviour, such as punishment and avoidance. The Abnormal Psychology section will focus on emotional and motivational disorders, such as anxiety and depression, addiction, sex and appetite, together with related neurochemical mechanisms and the effects of various psychopharmacological agents on these processes. A number of perceptual phenomena will be studied, such as motion detection, recognition of faces, identification of emotion, hearing and hearing loss, taste discrimination, and chronic pain. The practical classes differ from PSYC2011, as it is targeted for those who would like to learn more about the experimental study of behaviour and the neurosciences. Students will gain hands-on laboratory experience in how the principles and phenomena of behavioural neuroscience may be studied experimentally.

This unit expands the depth and range of topics introduced in the first year lectures on Cognitive Processes, Social Psychology and Developmental Psychology. The section on Cognitive Processes focuses on current theories of memory, attention, and reasoning and discusses the methods and issues involved in investigating these processes in both healthy individuals and people with cognitive dysfunctions. The second section on Social Psychology examines salient social constructs such as impression management, and prejudice, and explores how mental processes affect social judgment and behaviour. The final section on Developmental Psychology presents and evaluates evidence about the early influences on children's social and cognitive development.

This second semester unit is designed to introduce students to "cutting edge" issues in the neurosciences. This course is a combination of small lectures on current issues in cellular and developmental neuroscience and a research-based library project. Issues covered in the lecture series will include the role of glial on cerebral blood flow and neural transmission, neurochemistry and psychiatric disorders, neurodegeneration and the development of central and peripheral nervous systems.

This unit encompasses the material taught in NEUR3003. Advanced students perform a research project and present a mini-lecture on a current topic in neuroscience.

This second semester unit is designed to introduce students to "cutting edge" issues in the neurosciences and to be taken in conjunction with NEUR3003. This course is a combination of small group lectures on current issues in neuroscience, seminar groups and mini research projects. Examples of recent seminar topics include imaging pain, emotions, neural development and plasticity, vision, stroke and hypertension, mechanisms of neural degeneration and long-term regulation of blood pressure.

This unit encompasses the material taught in NEUR3004. Advanced students perform a research project and present a mini-lecture on a current topic in neuroscience research.
BMedSc degree students: You must have successfully completed BMED2401 and an additional 12cp from BMED240X before enrolling in this unit.

The aim of this unit is to provide students with advanced knowledge of functional neuroanatomy and systems neuroscience, and an appreciation that neuroscience is a constantly evolving field. There will be a detailed exploration of the anatomical structures and pathways that underlie sensation and perception in each of the sensory modalities. The neural circuits and mechanisms that control somatic and autonomic motor systems, motivated behaviours, emotions, and other higher order functions will be explored in great detail based on current neuroscience literature. Practical classes will allow students to identify and learn the functions of critical anatomical structures in human brain and spinal cord specimens. Reading and interpreting images from functional and structural brain imaging techniques will be incorporated into the neuroanatomy practical classes, and develop an appreciation of how these technologies can be used in neuroscience research. The Neuroscience in the Media seminars will develop neuroscience literature searching skills as well as developing critical thinking and analysis of the accuracy of the media portrayal of neuroscience research. Building on these skills and working in small groups, students will re-frame and communicate neuroscience evidence through the production of a short video. Students will also learn the skills required to write an unbiased and accurate popular media article based on a recent neuroscience research paper. This unit will develop key attributes that are essential for science graduates as they move forward in their careers.

The aim of this unit is to provide students with advanced knowledge of functional neuroanatomy and systems neuroscience, and an appreciation that neuroscience is a constantly evolving field. There will be a detailed exploration of the anatomical structures and pathways that underlie sensation and perception in each of the sensory modalities. The neural circutis and mechanisms that control somatic and autonomic motor systems, motivated behaviours, emotions, and other higher order functions will be explored in great detail based on current neuroscience literature. Practical classes will allow students to identify and learn the functions of critical anatomical structures in human brain and spinal corde specimens. Reading and interpreting images from functional ans tructural brain imaging techniques will be incorporated intot the neuroanatomy practical classes, and develop an appreciation of how these technologies can be used in neuroscience research. By undertaking the advanced unit students will participate in weekly small group seminars under the guidance of a research-active academic. The seminars will take the form of a Journal Club, a style practiced widely in research laboratories around the world. The aim of the Journal Club is to develop critical thinking and detailed knowledge in a specific area of neuroscience research through group discussions. The Journal Club will also develop the skills required to lead a discussion in a small group setting as well as research and write a scholarly neuroscience review article. This unit will develop key attributes that are essential for science graduates as they move forward in their careers.

This unit provides an introduction the mechanisms that drive neurons and neural circuits throughout the brain and body. The lectures explore how signal intensity is translated into nerve impulse codes and how this information is again translated through synapses to convey and interpret information about the external world, to control the body and to record information for future use (learning and memory). We also consider how sensory and motor information is integrated through neural circuits in the brain and spinal cord. Practical classes introduce some of the different ways in which the workings of the brain are studied. Each student chooses a journal club that focuses on a specific topic in neuroscience. In the weekly sessions, group members read, present and interpret original research papers, developing a deep understanding of the emerging scientific evidence in the topic area. This senior year unit of study will develop skills in critical analysis, interpretation and communication of new evidence.

This unit provides an introduction into the mechanisms that drive neurons and neural circuits throughout the brain and body. The lectures explore how signal intensity is translated into nerve impulse codes and how this information is again translated through synapses to convey and interpret information about the external world, to control the body and to record information for future use. We also consider how sensory and motor information is integrated through neural circuits in the brain and spinal cord. Practical classes introduce some of the different ways in which the workings of the brain are studied. This senior year unit of study will develop skills in critical analysis, interpretation and communication of new evidence.

This unit of study builds on pharmacological knowledge acquired in the 2000 level pharmacology units of study with a major emphasis on gaining an understanding of neuropharmacology. The neuropharmacology of the major neurotransmitters and their role in neuropsychiatric diseases is explored together with the treatment of conditions such as Alzheimer's disease, movement disorders, stroke, depression, anxiety, epilepsy, pain and schizophrenia. Each student will conduct a capstone elective project (laboratory or literature-based) in applied pharmacology supervised by academic members of the department.

This unit of study builds on pharmacological knowledge acquired in the 2000 level pharmacology units of study with a major emphasis on gaining an understanding of neuropharmacology. The neuropharmacology of the major neurotransmitters and their role in neuropsychiatric diseases is explored together with the treatment of conditions such as Alzheimer's disease, movement disorders, stroke, depression, anxiety, epilepsy, pain and schizophrenia. Each student will conduct a capstone elective project (laboratory or literature-based) in applied pharmacology supervised by academic members of the department.

This unit addresses the fundamental concepts and more important research findings related to contemporary theories of associative learning in animals and humans. It examines the application of such fundamental research to issues such as drug use and food choice. It is designed to foster skills in reading primary sources in this area, and provide the opportunity for hands-on experience in carrying out a research project.

This unit addresses the fundamental concepts and more important research findings related to contemporary theories of associative learning in animals and humans. It examines the application of such fundamental research to issues such as drug use and food choice. It is designed to foster skills in reading primary sources in this area, and provide the opportunity for hands-on experience in carrying out a research project. In the advanced unit of study students will learn techniques to model learning and behaviour, and independently apply these skills to experimental data that they have collected.

This unit extends the theories and methods of investigating memory and attentional processes discussed in PSYC2013/PSYC2016 to consider a number of domains of higher cognitive processing. One strand of the course will focus on the cognitive processes involved in speech perception, language comprehension, language production, and reading. The remainder of the course will deal with the cognitive processes involved in reasoning and skilled behaviour across a range of domains. The practical program will expose students to a variety of the research methods used to investigate higher cognitive processes, develop their understanding of how these methods can be used to investigate hypotheses about mental processes and consider applications of cognitive research to real-world problems and issues.

Perception poses many challenges: how do we see colour and movement? How do we perceive surfaces and materials? How does combining information from multiple senses improve our perception? This unit draws on behavioural and neurophysiological perspectives to deepen understanding of current research topics in perception. The emphasis is on how visual information is processed to accomplish functions such as perceiving a single edge, extracting the contours that form a face, or the spatial relations needed to call offside on the sports field. Students also gain conceptual tools for evaluating the empirical and theoretical worth of recent research in perception. During the tutorial component of the course students will develop a practical experiment in which they formulate and test a hypothesis. In this way students gain important research experience that gives them valuable insight into the scientific process as it exists both in professional work and in the empirical research project required for the Honours degree.

Perception poses many challenges: how do we see colour and movement? How do we perceive surfaces and materials? How does combining information from multiple senses improve our perception? This unit draws on behavioural and neurophysiological perspectives to deepen understanding of current research topics in perception. The emphasis is on how visual information is processed to accomplish functions such as perceiving a single edge, extracting the contours that form a face, or the spatial relations needed to call offside on the sports field. Students also gain conceptual tools for evaluating the empirical and theoretical worth of recent research in perception. During the tutorial component of the course students will develop a practical experiment in which they formulate and test a hypothesis. In this way students gain important research experience that gives them valuable insight into the scientific process as it exists both in professional work and in the empirical research project required for the Honours degree. In the advanced unit of study students will be placed in laboratories and will learn research techniques while helping conduct experiments in these laboratories.

This unit of study will focus on approaches to studying neurosciences incorporating molecular, pre-clinical and clinical models of brain function. These biological models of brain function will be linked with behavioural, affective and cognitive function and dysfunction. The implications of focal cognitive deficits in neurological patients for models of normal cognitive function will also be explored. Specific topics to be covered will be selected from the following areas: sensorimotor integration and the neural and molecular basis of learning and memory, attention, language, visual cognition and praxis. In addition to lectures, a practical component will cover basic neuroanatomy and neuroscientific methods. The practical component will also introduce students to experimental and neuropsychological approaches to studying the relationahip between brain and behaviour.

This unit of study will focus on approaches to studying neurosciences incorporating molecular, pre-clinical and clinical models of brain function. These biological models of brain function will be linked with behavioural, affective and cognitive function and dysfunction. Specific topics to be covered will be selected from the following areas: sensorimotor integration, and the neural and molecular basis of learning and memory, attention, language, visual cognition and praxis. The lecture material will be the same as for PSYC3014, however, the practical class is targeted for those who would like to learn more about the experimental study of behaviour and the neurosciences. The practical component of the advanced stream will cover basic neuroanatomy, histology and neuropharmacology and will introduce students to experimental approaches to studying brain-behaviour relationships.