Chemistry describes how and why things happen from a molecular perspective. Chemistry underpins all aspects of the natural and physical world, and provides the basis for new technologies and advances in the life, medical and physical sciences, engineering, and industrial processes. This unit of study will further develop your knowledge and skills in chemistry for application to life and medical sciences, engineering, and further study in chemistry. You will learn about nuclear and radiation chemistry, wave theory, atomic orbitals, spectroscopy, bonding, enthalpy and entropy, equilibrium, processes occurring in solutions, and the functional groups in carbon chemistry. You will develop experimental design, conduct and analysis skills in chemistry through experiments that ask and answer questions like how do dyes work, how do we desalinate water, how do we measure the acid content in foods, how do we get the blue in a blueprint, and how do we extract natural products from plants? Through inquiry, observation and measurement, you will understand the 'why' and the 'how' of the natural and physical world and will be able to apply this understanding to real-world problems and solutions. This unit of study is directed toward students with a satisfactory prior knowledge of the HSC chemistry course.

Chemistry describes how and why things happen from a molecular perspective. Chemistry underpins all aspects of the natural and physical world, and provides the basis for new technologies and advances in sciences, engineering, and industrial processes. This unit of study will further develop your knowledge and skills in chemistry for broad application, including further study in chemistry. You will learn about nuclear and radiation chemistry, wave theory, atomic orbitals, spectroscopy, bonding, enthalpy and entropy, equilibrium, processes occurring in solutions, and the functional groups of molecules. You will develop experimental design, conduct and analysis skills in chemistry through experiments that ask and answer questions about the chemical nature and processes occurring around you. Through inquiry, observation and measurement, you will better understand natural and physical world and will be able to apply this understanding to real-world problems and solutions. This unit of study is directed toward students with a good secondary performance both overall and in chemistry or science. Students in this category are expected to do this unit rather than Chemistry 1A. Compared to the mainstream Chemistry 1A, the theory component of this unit provides a higher level of academic rigour and makes broader connections between topics.

Chemistry describes how and why things happen from a molecular perspective. Chemistry underpins all aspects of the natural and physical world, and provides the basis for new technologies and advances in the life, medical and physical sciences, engineering, and industrial processes. This unit of study will further develop your knowledge and skills in chemistry for application to life and medical sciences, engineering, and further study in chemistry. You will learn about nuclear and radiation chemistry, wave theory, atomic orbitals, spectroscopy, bonding, enthalpy and entropy, equilibrium, processes occurring in solutions, and the functional groups in carbon chemistry. You will develop experimental design, conduct and analysis skills in chemistry in small group projects. The laboratory program is designed to extend students who already have chemistry laboratory experience, and particularly caters for students who already show a passion and enthusiasm for research chemistry, as well as aptitude as demonstrated by high school chemistry results. Entry to Chemistry 1A (Special Studies Program) is restricted to a small number of students with an excellent school record in Chemistry, and applications must be made to the School of Chemistry. The practical work syllabus for Chemistry 1A (Special Studies Program) is very different from that for Chemistry 1A and Chemistry 1A (Advanced) and consists of special project-based laboratory exercises. All other unit of study details are the same as those for Chemistry 1A (Advanced).

This unit of study aims to develop knowledge of the fundamental concepts and building blocks of electrical and electronics circuits. This is a foundation unit in circuit theory. Circuit theory is the electrical engineer's fundamental tool.
The concepts learnt in this unit will be made use of heavily in many units of study (in later years) in the areas of electronics, instrumentation, electrical machines, power systems, communication systems, and signal processing.
Topics: a) Basic electrical and electronic circuit concepts: Circuits, circuit elements, circuit laws, node and mesh analysis, circuit theorems, energy storage, capacitors and inductors, circuits with switches, transient response, sine waves and complex analysis, phasors, impedance, ac power. ; b) Project management, teamwork, ethics; c) Safety issues

AMME1362 is an introductory course in engineering materials. The unit aims to develop students' understanding of the structures, mechanical properties and manufacture of a range of engineering materials as well as how the mechanical properties relate to microstructure and forming and treatment methods. The unit has no prerequisite subject and is therefore intended for those with little or no previous background in engineering materials. However the unit does require students to take a significant degree of independent responsibility for developing their own background knowledge of materials and their properties. The electrical, magnetic, thermal and optical properties of materials are a critical need-to-know area where students are expected to do most of their learning by independent study.

The unit aims to provide students with an understanding of and competence in solving statics and introductory dynamics problems in engineering. Tutorial sessions will help students to improve their group work and problem solving skills, and gain competency in extracting a simplified version of a problem from a complex situation. Emphasis is placed on the ability to work in 3D as well as 2D, including the 2D and 3D visualisation of structures and structural components, and the vectorial 2D and 3D representations of spatial points, forces and moments. Introduction to kinematics and dynamics topics includes position, velocity and acceleration of a point; relative motion, force and acceleration, momentum, collisions and energy methods.

This biomedical engineering core junior unit of study provides an introduction to the relatively recent, and rapidly growing, biotechnology industry, with a focus on the current key commercial applications. In the 1990s, the word 'biotech' entered our lexicon as a synonym for overnight investment wealth. The biotechnology acronym GM (genetically modified) also entered our lexicon in the 1990s. Biotechnology can be broadly defined as the commercial exploitation of biological processes for industrial and other purposes. A significant focus for commercial activities has been GM technology: GM microorganisms, plants, animals, and even humans (gene therapy). The 'biotech industry' arose rapidly in the late 20th century, and is now one of the largest industries in the world, and is one of the cornerstones of the global biomedical industry which comprises three main sectors: Medical Devices, Pharmaceuticals, and Biotechnology. Significant global commercial biotechnology activity concerns the manufacture of therapeutic compounds from GM microorganisms using bioreactors, for example insulin. Another significant sector is agricultural: 'agri-biotech' which concerns GM higher lifeforms (plants and animals) primarily for the food industry, and also other industries such as the energy industry (biofuels). The third sector concerns therapeutic GM of humans, known as 'gene-therapy'. Some other important biotechnologies will also be explored including monoclonal antibodies, genome sequencing and personalised medicine, and RNA-interference technology (RNAi).

This unit of study provides the underpinning knowledge needed in biomedical engineering designs. The anatomic and physiological functional knowledge gained in this subject will enhance prototype development of biomedical designs. Students should gain familiarity with anatomical and physiological terms and their meaning, understanding of the gross anatomy of the major systems in the human body and their importance in the design of biomedical devices and understanding of the major physiological principles which govern the operation of the human body.

This unit offers essential knowledge of physics for applications in biomedical engineering, medicine and medical sciences. The unit will cover fundamentals concepts of electromagnetism, optics and quantum physics - these concepts are becoming rapidly relevant and vital with new and emerging technologies in the biomedical and health sector. It is imperative for the next generation of biomedical engineers and healthcare providers to develop a strong foundational knowledge in these concepts in the context of biomedicine. The knowledge provided by this unit is intended to prepare the students to be able to understand pivotal technologies used in medical research and the medical clinic, such as fluorescence based imaging, nuclear magnetic resonance, magnetotherapy.

Biomedical engineering is being deeply reshaped by the advancements in computational tools and the utilisation of rich data. This unit will explore the processes involved in designing and building systems to perform computational analysis on biological signals, using microcontrollers and desktop or server computing. The main teaching activities will focus on the theory and practical skills for data capture, cleaning, communication, storage, and analytics. The purpose is to ensure that students develop the skills necessary to design systems that can be used for monitoring of patients, where the data can be used for analytics, e.g. prediction of an adverse event. This is relevant to a number of applications in modern healthcare such as continuous and remote monitoring devices. The unit will develop core skills in programming, solution design, sensor interfacing, and data analysis.

AMME2960 Biomedical Engineering 2 is the third of the four Biomedical Engineering foundational units. The first (AMME1960 Biomedical Engineering 1A) introduces students to the discipline of biomedical engineering, covering the key concepts of biomedical technology, design, biomechanics, and the important systems of the human body from a biomedical engineering perspective. The second (AMME1961 Biomedical Engineering 1B) is an introduction to Biotechnology. The fourth (MECH2901 Anatomy and Physiology for Engineers) provides a hands-on anatomy and physiology study of the key systems of the human body from a biomedical engineering perspective and includes cadaver laboratories. This unit (AMME2960 Biomedical Engineering 2) is designed to provide students with the necessary tools for mathematically modelling and solving problems in engineering. Engineering methods will be considered for a range of canonical problems, including conduction heat transfer in one and two dimensions, vibration, stress and deflection analysis, convection and stability problems. The mathematical tools covered in the lectures include: deriving analytical solutions via separation of variables, Fourier series and Fourier transforms, Laplace transforms, scaling and solving numerically using finite differences, finite element and finite volume approaches. There is a strong emphasis in both the lectures and tutorials on applying these mathematical methods to real biomedical engineering problems involving electrical, mechanical, thermal and chemical mechanisms in the human body. Specific examples include heat regulation, vibrations in biological systems, and the analysis of physiological signals such as ECG and EEG.

The unit aims to teach the fundamentals of biomedical manufacturing processes, including traditional and advanced manufacturing technologies. This unit aims to develop the following attributes: to understand the fundamental principles of biomedical manufacturing approaches; to gain the ability to understand and select appropriate manufacturing processes and systems for biomedical applications; to develop ability to create innovative new manufacturing technologies for medical bionics and other applications in biomedical engineering; to develop ability to invent new manufacturing systems suitable for biomedical engineering implementation. At the end of this unit students will have a good understanding of the following: merits and advantages of individual manufacturing processes and systems used in the fabrication of medical devices and products that support human health and well-being; principles of developing new technologies for biomedical engineering applications; comprehensive applications and strategic selection of manufacturing processes and systems within the regulatory landscape of biomedical manufacturing. Unit content will include: Materials Processing: An introduction into the use of joining, moulding, and other manufacturing processes. Rapid Prototyping: An introduction into the most current prototyping methods currently in use. Manufacturing Processes: Common processes and their science (machining, moulding, sintering, materials processing, joining processes) and their relative merits and limitations.

This unit aims to give students an understanding of the Australian and International biomedical industry and in the development, manufacture and uses of biomedical engineering products in therapeutic, rehabilitation and clinical settings. Students will gain an understanding of the process of biomedical regulation in Australia and other major international markets as well as the entire process of creating a new biomedical engineering product, from design through to marketing and monitoring of the product. Students will design a biomedical device including the preparation of a detailed design brief. This will be done as a team project. Each team will work on a specific biomedical design project following formal design protocols, including design control, regulatory considerations, and commercialisation/IP considerations.

This unit will build on knowledge in materials science and merge knowledge in the biomedical sciences, in particular with the aspects of the human anatomy and physiology. The students will appreciate that developing engineering solutions to solve problems associated with the human body will bring forward a unique set of constraints and conditions not found in alternate contexts. For example, the human body is composed of living constituents called 'cells' that produce matter called 'tissues' in a structured manner to form functioning systems called 'organs'. The function(s) of these cells is heavily dependent on the surrounding physical and chemical cues - the parameters (for which there are multiple) of these cues have to be 'right' or 'optimal' for the cells to function well to produce the correct type of tissue for the correct functioning of the organ. A biomedical engineering solution (e.g. an implantable or wearable device) to treat, monitor or diagnose a disease or medical condition must take these parameters into serious consideration.

With the severe worldwide shortage of donor organs and the ubiquitous problem of donor organ rejection, there is a strong need for developing technologies for engineering replacement organs and other body parts. Recent developments in engineering and the life sciences have begun to make this possible, and as a consequence, the very new and multidisciplinary field of tissue engineering has been making dramatic progress in the last few years. This unit will provide an introduction to the principles of tissue engineering, as well as an up to date overview of recent progress and future outlook in the field of tissue engineering. This unit assumes prior knowledge of cell biology and chemistry and builds on that foundation to elaborate on the important aspects of tissue engineering. The objectives are: To gain a basic understanding of the major areas of interest in tissue engineering; To learn to apply basic engineering principles to tissue engineering systems; To understand the promises and limitations of tissue engineering; To understand the advances and challenges of stem cell applications; Enable students to access web-based resources in tissue engineering; Enable students to develop basic skills in tissue engineering research.

Product development in the biomedical area presents unique challenges that need to be addressed to efficiently satisfy strict regulatory requirements and to successfully advance products to approval for marketing. Biomedical engineers need a broad understanding of these challenges as the main components of product development are complex and interdependent. Development of good manufacturing and quality control processes, preclinical and clinical validation of product safety and efficacy, and regulatory filings, are each progressive and interdependent processes. This UoS will provide a broad understanding of regulatory requirements for biomedical product development, with particular emphasis on the dependence of each component on the development of processes and control systems that conform to Good Manufacturing Practice. This UoS assumes prior knowledge of cell biology and chemistry and builds on that foundation to elaborate on the important aspects of biomedical product development.

Supply of medical devices, diagnostics and related therapeutic products is regulated in most jurisdictions, with sophisticated and complex regulatory regimes in all large economies. These regulations are applied both to manufacturers and designers and to biomedical engineers undertaking device custom manufacture or maintenance in clinical environments. This UoS will explore the different regulatory frameworks in the 'Global Harmonisation Task Force' group of jurisdictions (US, EU, Canada, Japan, Australia), as well as emerging regulatory practices in Asia and South America. Emphasis will be on the commonality of the underlying technical standards and the importance of sophisticated risk management approaches to compliance.

The ability to design within the context of biomedical engineering requires cross-disciplinary knowledge and an appreciation and application of professional engineering standards and ethics. This unit provides students the opportunity to experience the design process and to develop good engineering skills. Students will build on skills and knowledge developed in prerequisite units and be introduced to standards and creative tools relevant to biomedical applications. The importance of standard engineering drawings in the communication and definition of parts and assemblies, the use of a CAD package to create them, and the importance and deeper understanding of standard components will be integral to the learning in this unit. Students will also learn and use the design process from initial idea to finished product, and practice various methods used to generate creative solutions.

Unprecedented growth in computing power, the advent of artificial intelligence (AI)/machine learning technologies, and global data platforms are changing the way in which we approach real-world healthcare challenges. This interdisciplinary unit will introduce students from different backgrounds to the fundamental concepts of data analytics and AI, and their practical applications in healthcare. Throughout the unit, students will learn about the key concepts in data analytics and AI techniques, and obtain hands-on experience in applying these techniques to a broad range of healthcare problems. At the same time, they will develop an understanding of the ethical considerations in health data analytics and AI, and how their use impacts society: from the patient, to the doctor, to the broader community. A key element of the learning process will be a team-based Datathon project where students will deploy their knowledge to address an open-ended healthcare problem, in particular developing a practical solution and analysing how it's use may change things in the healthcare domain. Upon completion of this unit, students will understand and be able to enlist data analytics and AI tools to design solutions to healthcare problems.

This unit assumes a knowledge of basic principles in physics, mathematics, circuit theory and electronics. In particular, some understanding of the following is required: Thevenins and Nortons theorems, Fourier analysis, radiation, filtering, bipolar and field effect transistors, and operational amplifiers. The following topics are covered. Biology of the heart, circulatory and respiratory systems, physiology of nerve and muscle cells, fundamental organization of the brain and spinal cord. Medical instrumentation. ElectrocardioGram and automated diagnosis. Heart pacemakers and defibrillators. The bionic ear. Apparatus for treatment of sleep disordered breathing(sleep apnoea). Medical imaging and signal processing This unit is descriptive and does not require detailed knowledge of electronics or mathematics, but does require an understanding of some key aspects of mathematical and electronic theory. The unit concentrates on some of the practical applications of biomedical engineering to patient diagnosis and treatment.

This UoS will give students an understanding of CT/MRI based solid modelling, finite element methods, constitutive material models, design analysis and optimisation, experimental validation and their use in biomedical engineering. The students are expected to gain skills and experience with finite element software for the solution to sophisticated problems associated with biomedical engineering and experimentation techniques for the validation of these problems. The unit will take a holistic approach to the learning outcomes: an overview of typical biomedical design problems, an overview of finite element analysis software, a detailed look at finite element methods in biomedical applications, and a project-based learning approach to the development of a biomedical prosthesis. By the end of the unit, the students are expected to have familiarised themselves with design analysis, optimisation, and validation for biomedical engineering problems.

Biomechatronics is the application of mechatronic engineering to human biology, and as such it forms an important subset of the overall biomedical engineering discipline. This unit focusses on a number of areas of interest including auditory and optical prostheses, artificial hearts and active and passive prosthetic limbs and examines the biomechatronic systems (hardware and signal processing) that underpin their operation.

The aims and objectives of the UoS are: 1. To introduce the student to the details and practice of orthopaedic engineering; 2. To give students an overview of the diverse knowledge necessary for the design and evaluation of implants used in orthopaedic surgery; 3. To enable students to learn the language and concepts necessary for interaction with orthopaedic surgeons and the orthopaedic implant industry; 4. To introduce the student to the details and practice of other engineering applications in surgery, particularly in the cardiovascular realm.

This UoS offers fundamental knowledge about the working principles of scanning probe microscopies, microsensors and other key instrumentation in nanotechnology with a focus on biophysical, biomedical and material science applications. Scanning probe microscopes work in a variety of environments ranging from vacuum to liquids, and are frequently used to study samples spanning from single atoms all the way up to live cells and tissues. Besides imaging, these technologies enable the manipulation of matter and the acquisition of many physical and chemical properties of samples up to the atomic scale. The knowledge provided in this UoS is intended to improve the competences of the students to understand, use and create technologies of great value in nanotechnology with applications across multiple disciplines.

The application of science and technology at the nanoscale for biomedical problems promises to revolutionise medicine. Recent years have witnessed unprecedented advances in the diagnosis and treatment of diseases by applying nanotechnology to medicine. This course focuses on explaining the fundamentals of nanomedicine, and highlighting the special properties and application of nanomaterials in medicine. This course also reviews the most significant biomedical applications of nanomaterials including the recent breakthroughs in drug delivery, medical imaging, gene therapy, biosensors and cancer treatment.

Biomedical imaging technology is a fundamental element of both clinical practice and biomedical research, enabling the visualisation of biological characteristics and function often in a non-invasive fashion. The advancement of digital scanning technologies alongside the development of computational tools has driven significant progress in medical image analysis tools that support clinical decisions and the analysis of data from biological experiments. The focus of this unit will be the development of fundamental computational skills and knowledge in biomedical imaging, including data acquisition, formats, visualisation, segmentation, feature extraction, and machine learning based image analysis. On completion of this unit, students will be able to engineer and develop solutions for different biomedical imaging tasks encountered across a variety of use cases: clinical practice (e.g., computerised disease detection and diagnosis), research (e.g., cell video analysis), and industry (e.g., fabrication of customised implants from patient image data).

BMET5944 equips students with the state-of-the-art knowledge about the design and development of new generations of multifunctional materials by learning from nature. The unit covers: (a) the construction, deformation and failure behaviour of hard and soft natural materials which confer them with outstanding mechanical properties and multi-functionalities such as shape-morphing, self-healing and damage sensing, (b) the fabrication techniques to implement similar principles in engineering materials in order to improve their performance, (c) the theoretical and experimental approaches to study the mechanics of resulting materials, and (d) examples of bioinspired materials in industries, current challenges of the field and future perspectives.

Rehabilitation Engineering is a staple course of biomedical engineering programs worldwide. This unit focuses on rehabilitation devices, external and internal, for communication and mobility. Rehabilitation engineering is the application of engineering analysis and design expertise to overcome disabilities and improve quality of life with assistive technologies. The unit will cover the inclusive design or 'design for all' process with consumer engagement, human-computer interfaces, mobility and communication needs. All students will design a project that addresses an unmet need. There will be visits to disability services organisations and learn about the National Disability Insurance Scheme. The unit will be taught through lectures and the design lab including computational and hands on design. Communication skills will be tested through a project 'pitch' presentation. Some teaching will be provided by rehabilitation engineers working in industry.

This unit is focused on the emergent and highly interdisciplinary field of electroceuticals as an alternative to pharmaceutical therapeutics. Biomedical devices, circuits and systems employ electrical, magnetic, optical, ultrasound, or other pulses to modulate peripheral nerves for target- and organ-specific effects. We want to understand: What is electroceutical therapy? How bioelectronic medicine could replace drugs? What are the benefits and side effects of electroceuticals in terms of safety, efficacy, and cost compared with pharmaceutical therapeutics?, and How a future bioelectrician works with clinician and conventional clinical practice? This unit aims to build complementary capabilities in design and simulation of circuits and systems for bioelectronic medicine interfaces. Students review, learn, design, simulate and implement test platforms for circuits and systems that enable bioelectronic treatments. Students will be equipped with knowledge on how to make more targeted and personalised treatments for neurological based diseases and conditions with a focus on closed-loop control systems. Students are expected to perform research on circuit implementation for different applications such as pain relief, bionic eye, pace makers. The unit also provides a deep overview on the roadmap of technologies and future trends in bioelectronic medicine and electroceuticals.

Nanotechnology in Biomedical Engineering will have a broad nanotechnology focus and a particular focus on the biophysics and electrical aspects of nanotechnology, as it relates to nanobiosensors and nanobioelectronics which represents a rapidly growing field in Biomedical Engineering that combines nanotechnology, electronics and biology with promising applications in bionics and biosensors. Nanodimensionality and biomimetics holds the potential for significant improvements in the sensitivity and biocompatibility and thereby open up new routes in clinical diagnostics, personalized health monitoring and therapeutic biomedical devices.

Mechanobiology has emerged as a new field of science that integrates biology and engineering and is now considered to have significant influence on the development of technologies for regenerative medicine and tissue engineering. It is well known that tissues and cells are sensitive to their mechanical environment and changes to this environment can affect the physiological and pathophysiological processes. Understanding the mechanisms by which biological cells sense and respond to mechanical signals can lead to the development of novel treatments and therapies for a variety of diseases.

The field of 'bionics' is one of the primary embodiments of biomedical engineering. In the context of this unit, bionics is defined as a collection of therapeutic devices implanted into the body to restore or enhance functions lost through disease, developmental anomaly, or injury. Most typically, bionic devices intervene with the nervous system and aim to control neural activity through the delivery of electrical impulses. An example of this is a cochlear implant which delivers electrical impulses to physiologically excite surviving neurons of the auditory system, providing the capacity to elicit the psychological perception of sound. This unit primarily focuses upon the replacement of human senses, the nature and transduction of signals acquired, and how these ultimately effect neural activity.