This unit introduces the concept of clinical epidemiology and provides students with core skills in clinical epidemiology at an introductory level. Topics covered include asking and answering clinical questions; basic and accessible literature searching techniques; study designs used in clinical epidemiological research; confounding and effect modification; sources of bias; interpretation of results including odds ratios, relative risks, confidence intervals and p values; applicability of results to individual patients; critical appraisal of clinical epidemiological research literature used to answer questions of therapy (RCTs and systematic reviews), harm, prognosis, diagnosis and screening; applicability of results to individual patients; and evidence-based use of health resources.

This unit introduces the concept of clinical epidemiology and provides students with core skills in clinical epidemiology at an introductory level. Topics covered include asking and answering clinical questions; basic and accessible literature searching techniques; study designs used in clinical epidemiological research; confounding and effect modification; sources of bias; interpretation of results including odds ratios, relative risks, confidence intervals and p values; applicability of results to individual patients; critical appraisal of clinical epidemiological research literature used to answer questions of therapy (RCTs and systematic reviews), harm, prognosis, diagnosis and screening; applicability of results to individual patients; and evidence-based use of health resources.

This unit of study provides the core anatomical, physiological and technical knowledge required for the practice of clinical neurophysiology. In order to obtain and interpret information regarding the function of the neural systems, clinicians must be able to accurately record and quantify electrical signals from a myriad of neurological structures. This unit describes the methods by which these electrical signals are generated, recorded, processed and presented for interpretation. It also examines the neurological systems and processes responsible for signal generation, and introduces the role of clinical neurophysiology in diagnosis of systemic disease.

This unit introduces the concept of clinical epidemiology and provides students with core skills in clinical epidemiology at an introductory level. Topics covered include asking and answering clinical questions; basic and accessible literature searching techniques; study designs used in clinical epidemiological research; confounding and effect modification; sources of bias; interpretation of results including odds ratios, relative risks, confidence intervals and p values; applicability of results to individual patients; critical appraisal of clinical epidemiological research literature used to answer questions of therapy (RCTs and systematic reviews), harm, prognosis, diagnosis and screening; applicability of results to individual patients; and evidence-based use of health resources.

This unit of study provides the core anatomical, physiological and technical knowledge required for the practice of clinical neurophysiology. In order to obtain and interpret information regarding the function of the neural systems, clinicians must be able to accurately record and quantify electrical signals from a myriad of neurological structures. This unit describes the methods by which these electrical signals are generated, recorded, processed and presented for interpretation. It also examines the neurological systems and processes responsible for signal generation, and introduces the role of clinical neurophysiology in diagnosis of systemic disease.

Electroencephalography (EEG) forms the basis of multiple neurophysiological techniques and is a powerful tool in its own right. This unit will introduce the standardised systems and nomenclature for EEG recordings, examine the characteristics of normal recordings and, using a case based approach illustrate the pathological changes associated with intracranial lesions, systemic disease and critical illness. The utility of EEG in the diagnosis of seizure disorders will be examined in detail.

Clinical neurophysiologists are required to have expertise in a number of different diagnostic and monitoring modalities. This unit will use a case based approach to cover the most commonly used diagnostic techniques (other than EEG) and will focus on nerve conduction studies and sensory evoked potential recordings.

This unit covers advanced aspects of diagnostic electroencephalography, including the specific technical requirements for continuous video EEG monitoring, seizure recognition during invasive EEG monitoring, current techniques in cortical mapping of seizures and their utility in tailored cortical resection.

This unit of study examines the techniques available to monitor the function and wellbeing of the brain and nervous system during anaesthesia and surgery. Despite their widespread use, the effect of general anaesthetic agents on the brain and spinal cord is still poorly understood. There is wide interpatient variability in responses to these agents, and intraoperative haemodynamic fluctuations and underlying disease processes are all threats to the central nervous system which may be mitigated by careful monitoring.

Unexpected postoperative neurologic deficit is arguably one of the most devastating potential complications of surgery. This unit examines the fundamental neurophysiological techniques necessary for continuous functional monitoring of the human nervous system during at risk surgical procedures. In particular, this unit provides the theoretical and practical knowledge underpinning somatosensory evoked potentials, brainstem auditory evoked potentials, motor evoked potentials and electromyography as they relate to various surgical disciplines.

This unit of study builds on CLNP5006 and focuses on how multimodal monitoring can be used in a broad range of cranial, spinal and peripheral nerve procedures to minimise the likelihood of neurological trauma. Students will acquire the theoretical knowlede and practical skills to perform the various modalities of intraoperatrive neurophysiological monitoring and understand the structures at risk during a particular surgery.

This unit provides an overview of the neuromuscular, central nervous system, and neurosurgical disorders commonly encountered in clinical neurophysiology laboratories. Presenting symptoms, diagnoses and the application of common neurophysiological techniques are explored.

This unit will provide students with a grounding in the essential skills required for neurophysiology scientists to deliver high quality, safe and ethical care to their patients. Students will develop critical thinking and problem solving skills for a diverse range of scenarios which they may encounter within a clinical neurophysiology setting. Key ethical concepts and methods of ethical analysis, communication, quality control methodology, workplace health and safety, risk management and teaching skills required for effective work within the field will be discussed with a specific focus on their relationship to neurophysiological testing in both a clinical and intraoperative environment. Students with no neurophysiology workplace experience should undertake this unit after completion of at least one stream specific neurophysiology unit, or towards the end of their course

The Basic Neurology syllabus covers the requirements of trainee physician practice. The content is focussed on diagnosis and investigation of common neurological conditions and the essentials of management of these conditions. The module learning materials are linked to a library of clinical cases representing common and important neurological conditions.

The Advanced Neurology syllabus is at a level appropriate for practitioners undertaking specialist training in neurology or with an interest in the field. The content is focussed on diagnosis and investigation of important but less common neurological conditions and advanced management of common and important neurological diseases. The module learning materials are linked to a library of clinical cases representing common and important neurological conditions.

This course is specifically designed for health professionals who are working in health care. It will equip participants with underpinning knowledge about patient safety. The course modules cover quality and safety principles, professionalism and ethics, the blame culture, risk information, health care as a system, the impact of adverse events, methods to measure and make improvements in health care.
The modules, tools and the discussions are designed to enable participants to change behaviours by understanding the main causes of adverse events. The course provides foundation knowledge about quality and safety; governments around the world are concerned to address unsafe care. The course will better prepare health professional to understand the complexity of health care and take steps to minimise the opportunities for errors and address vulnerabilities in the system.

Almost all healthcare professionals are involved in education and training throughout their careers. This unit of study provides a practical introduction to the theory and practice of teaching and learning in the health environment. The unit will cover three main areas: planning for and facilitating learning in the clinical environment; assessing performance and providing constructive feedback; and fostering the development of students as professionals. Each of these areas will be underpinned by best evidence from clinical education research and will address current challenges and opportunities in the learning environment from the perspective of both educators and learners. Participants in the course will gain a framework they can use to support their teaching, and will develop a portfolio of evidence to support their professional development as clinician educators.

This unit introduces students to statistical methods relevant in medicine and health. Students will learn how to appropriately summarise and visualise data, carry out a statistical analysis, interpret p-values and confidence intervals, and present statistical findings in a scientific publication. Students will also learn how to determine the appropriate sample size when planning a research study. Students will learn how to conduct analyses using calculators and statistical software.
Specific analysis methods of this unit include: hypothesis tests for one-sample, two paired samples and two independent samples for continuous and binary data; distribution-free methods for two paired samples, two independent samples; correlation and simple linear regression; power and sample size estimation for simple studies; and introduction to multivariable regression models;.
Students who wish to continue with their statistical learning after this unit are encouraged to take PUBH5217 Biostatistics: Statistical Modelling.

This unit of study aims to develop an understanding of normal human sleep across the lifecycle and introduces common sleep disorders and sleep related breathing disorders. Normal sleep and respiratory physiology will be discussed, as well as the methods used for measurement and analysis of sleep recordings. Obstructive and central sleep apnoea and non-respiratory sleep disorders such as narcolespy, parasomnias, insomnia and circadian rhythm disorders are introduced. Current scoring guidelines for sleep stage scoring and respiratory event scoring will be explored and their practical application will be demonstrated using short examples of sleep studies. Learning will include regular short answer quizzes, as well as broader written assessments.

To optimise healthcare delivery, we need evidence-based strategies to enable research translation and to assess impact. This unit of study will teach these skills, including fostering and maintaining stakeholder engagement, pragmatic study design, cost effectiveness analysis, recognising and managing barriers and enablers to implementation, and post-research translation. Case-based discussions and preparation of a research proposal will develop the skills required to enhance impact and hasten adoption of research into routine care. This practical unit will suit students who are interested in improving their skills and knowledge in the areas of clinical or health services research and who are keen to enhance the impact of their current or future research.

Candidates will work on an independent research project in an area of specific interest relevant to their master's degree. The project may take the form of analysis of an existing data set, a systematic or integrative review of the literature, a case series, survey or other project acceptable to the project supervisor. In some streams, projects may be available for students to select. It is essential, where there is the use of patient information or recruitiment of patient study subjects, that appropriate ethics approval is gained from the governing body where the project will take place. The candidate will enter into a learning contract and will be guided through the steps required to plan and execute a substantial research project, and prepare a scholarly work which may be a paper for publication. A candidate must enrol in a minimum of 12 credit points of project units of study in order to submit their final written work.

Candidates will work on an independent research project in an area of specific interest relevant to their master's degree. The project may take the form of analysis of an existing data set, a systematic or integrative review of the literature, a case series, survey or other project acceptable to the project supervisor. In some streams, projects may be available for students to select. It is essential, where there is the use of patient information or recruitment of patient study subjects, that appropriate ethics approval is gained from the governing body where the project will take place. The candidate will enter into a learning contract and will be guided through the steps required to plan and execute a substantial research project and prepare a scholarly work which may be a paper for publication. Where appropriate students will prepare a work suitable for publication. A candidate must enrol in a minimum of 12 credit points of project units of study in order to submit their final written work.

Candidates will work on an independent research project in an area of specific interest relevant to their master's degree. The project may take the form of analysis of an existing data set, a systematic or integrative review of the literature, a case series, survey or other project acceptable to the project supervisor. In some streams, projects may be available for students to select. It is essential where there is the use of patient information or recruitment of patient study subjects that appropriate ethics approval is gained from the governing body where the project will take place. The candidate will enter into a learning contract and will be guided through the steps required to plan and execute a substantial research project and prepare a scholarly work which may be a paper for publication. A candidate must enrol in a minimum of 12 credit points of project units of study in order to submit their final written work.