This unit of study introduces the basic concepts in musculoskeletal anatomy prior to a more detailed study of the gross anatomical structure of the upper limb as it relates to functional activities. Students will also study the histological structure of musculoskeletal tissues and surface anatomy of the upper limb. Material will be presented in lectures, practical sessions and online. Students will also be expected to undertake some independent learning activities (e.g. online video tutorials and practice quizzes) to supplement the lectures and practicals. This unit includes laboratory classes in which human cadavers are studied; attendance at such classes is compulsory.

This unit of study examines the detailed gross, radiological and surface anatomy of the lower limb, trunk and neck. Included are the anatomical analyses of functional activities which involve the lower limb, back and neck. Material will be presented in lectures as well as in practical and tutorial sessions on-campus or online. Students are also expected to undertake independent learning. Practical classes involve the study of human cadavers. Attendance at the practical and tutorial sessions is compulsory.

This unit will present the gross anatomy, functional histology, physiology and pathophysiology of the cardiovascular, respiratory and renal systems (including acid-base homeostasis) relevant to human movement. This unit includes laboratory classes in which human cadaveric material is studied; attendance at such classes is compulsory. It includes classes during which students interpret physiological data and explain the physiological principles associated demonstrated. These classes link across all topics culminating in a capstone activity which emphasizes the integrated nature of human movement and performance.

This intermediate unit of study will introduce the human nervous system and its function, with a focus on the control of movement. Content includes the neuroanatomy and neurophysiology of the healthy human, as well as the introduction of disorders of the nervous system, especially those affecting movement. The unit is designed to equip students to pursue advanced studies in clinical neuroscience or a professional degree program in medicine or other health professions. Material will be presented in lectures, tutorial and practical classes. Active learning approaches including case-based, on-line and individual learning will be used.

The purpose of the unit is to provide students with a comprehensive understanding of skeletal muscle function and how muscle adapts to increased use, specifically how muscle responds to high-resistance training (HRT, also know as strength training) and to disuse. Students will gain an understanding of muscle force development in terms of myosin function and organization (sarcomeres, myofibrils, muscle fibers) and the neural processes involved in maximal voluntary contractions. Students will then apply this knowledge to understand how HRT works in terms of hypertrophy and neural adaptations, the process of muscle atrophy during disuse and the effects of retraining after disuse. Students will integrate this biological understanding with an evidence-base approach to HRT prescription. Students apply and integrate these approaches gain skills in the real-world prescription of HRT through participation in HRT program in practical session, and then gain skills in data analysis via interpretation of their own responses to training. Students will gain skills in the ability to critically evaluate, and communicate applications of evidence-base research in healthy and clinical populations. Finally the unit examines concepts on muscle energy balance in terms of methods and control of ATP production and use, and these concepts are used to understand the concepts of peripheral and central fatigue.

This unit provides students with a broad understanding of the physiological responses and adaptations to exercise. The unit describes the basic metabolic, cardiovascular and respiratory responses and adaptations to exercise training in healthy, asymptomatic individuals. It outlines the different modalities of exercise testing for quantification of functional capacity, exercise prescription and training. It examines physical deconditioning and the associated physiological deterioration. It also provides an introduction to clinical populations who would benefit from exercise training. Students apply and integrate theoretical knowledge through practical and tutorial classes. Students will develop skills to measure physiological responses to exercise and cardiorespiratory fitness. Based on best-practice guidelines, students will design an exercise program for a healthy individual.

This unit provides students with a broad overview of motor control and learning with the aim of stimulating students to think about the mechanisms of normal human movement. Both a behavioural and a neurophysiological approach are taken to understand the acquisition and execution of skilled motor actions. The behavioural approach is directed at the process of optimizing the learning of skills. Meanwhile the neurophysiological approach is directed at the neuromuscular machinery and the functional neural connections which enable skill-acquisition to occur.

This unit of study will extend the student's knowledge of functional musculoskeletal anatomy by applying functional anatomy principles to the analysis of exercises. Relevant research and advanced knowledge of
functional musculoskeletal anatomical concepts will be used to explore exercises designed to: strengthen and lengthen specific muscles; improve muscle coordination; develop dynamic stability; and prevent the development of muscle imbalances that may contribute to musculoskeletal injury. The application of musculoskeletal anatomy principles to increase exercise difficulty and variety will also be explored.

This interdisciplinary unit provides students with the opportunity to address complex problems identified by industry, community, and government organisations, and gain valuable experience in working across disciplinary boundaries. In collaboration with a major industry partner and an academic lead, students integrate their academic skills and knowledge by working in teams with students from a range of disciplinary backgrounds. This experience allows students to research, analyse and present solutions to a real world problem, and to build on their interpersonal and transferable skills by engaging with and learning from industry experts and presenting their ideas and solutions to the industry partner.

This interdisciplinary unit provides students with the opportunity to address complex problems identified by industry, community, and government organisations, and gain valuable experience in working across disciplinary boundaries. In collaboration with a major industry partner and an academic lead, students integrate their academic skills and knowledge by working in teams with students from a range of disciplinary backgrounds. This experience allows students to research, analyse and present solutions to a real world problem, and to build on their interpersonal and transferable skills by engaging with and learning from industry experts and presenting their ideas and solutions to the industry partner.

This unit provides students with a broad understanding of the physiological responses and adaptations to exercise. The unit describes the basic metabolic, cardiovascular and respiratory responses and adaptations to exercise training in healthy, asymptomatic individuals. It outlines the different modalities of exercise testing for quantification of functional capacity, exercise prescription and training. It examines physical deconditioning and the associated physiological deterioration. It also provides an introduction to clinical populations who would benefit from exercise training. Students apply and integrate theoretical knowledge through practical and tutorial classes. Students will develop skills to measure physiological responses to exercise and cardiorespiratory fitness. Based on best-practice guidelines, students will design an exercise program for a healthy individual.

This unit provides students with a broad overview of motor control and learning with the aim of stimulating students to think about the mechanisms of normal human movement. Both a behavioural and a neurophysiological approach are taken to understand the acquisition and execution of skilled motor actions. The behavioural approach is directed at the process of optimizing the learning of skills. Meanwhile the neurophysiological approach is directed at the neuromuscular machinery and the functional neural connections which enable skill-acquisition to occur.

This unit of study will extend the student's knowledge of functional musculoskeletal anatomy by applying functional anatomy principles to the analysis of exercises. Relevant research and advanced knowledge of
functional musculoskeletal anatomical concepts will be used to explore exercises designed to: strengthen and lengthen specific muscles; improve muscle coordination; develop dynamic stability; and prevent the development of muscle imbalances that may contribute to musculoskeletal injury. The application of musculoskeletal anatomy principles to increase exercise difficulty and variety will also be explored.