Higher Degree by Research

Background

Brain cells (neurons) communicate with each other by exchanging neurotransmitter molecules across the synapse, in a process called neuroexocytosis, involving fusion of neurotransmitter vesicles with the synaptic membrane. The composition of phospholipids which comprise vesicular and cellular membranes is dynamically regulated, and phospholipid metabolites such as free fatty acids (FFAs) and lysophospholipids (LPLs) generated during this regulation are emerging as key players in neurotransmission, learning and memory. The goal of this PhD project is to understand the roles of these lipids in learning and memory and establish how they are affected during ageing.

Project aim

Our laboratory has contributed to the burgeoning field of neurolipidomics through the development of novel and sensitive targeted lipidomics workflows for analysis of FFA, LPL and phospholipids in cultured neurons and animal brains. We recently published a groundbreaking study correlating increases in the saturated FFA myristic acid with memory, and have strong preliminary evidence correlating this FFA with retention of cognitive ability in ageing mice. The project aims to build on these findings by establishing whether dietary supplementation can affect the brain lipidome and alter the trajectory of cognitive decline during ageing.

Your role

The successful candidate will join the lipidomics team in the lab and will use our in-house and collaborative mass spectrometry based lipidomics workflows to assess how dietary FFA supplementation alters the brain lipidome, and whether these changes correlate with improvements to cognitive ability in ageing mice. The candidate will ideally have a background in neuroscience, cell biology or analytical biochemistry. Familiarity with Python, data analysis and informatics will further help the candidate to carry out their role (but is not essential).

Contact

Single Molecule Neuroscience Laboratory

 Group leader: Professor Frederic Meunier    f.meunier@uq.edu.au

Background

Brain cells primarily communicate with each other through the release of neurotransmitters (chemical signals) across the synapse. The sequence of molecular interactions involved in neurotransmitter release is largely unknown. Super-resolution microscopy techniques provide unprecedented quantitative information on the dynamics of individual molecules in living cells. This interdisciplinary PhD project aims to use super-resolution imaging experiments to understand the molecular mechanisms controlling the neurotransmitter release in health and disease.

Project aim

Our laboratory has contributed to the rapidly emerging super-resolution field by providing a means of visualizing single molecule behaviour in living neurosecretory cells and presynapses to unravel dynamically regulated molecular binding events at the level of the synapse. The successful candidate will join the established laboratory group of Professor Frederic Meunier at the Queensland Brain Institute at the University of Queensland and will use super-resolution microscopy to detect and track individual molecules in live cultured neurons. The project will look at decrypting the complex behaviour of single molecules in terms of nanoscale organisation and molecular kinetics to better understand their role in physiology and pathology.

Your role

Expressions of Interest are invited from outstanding and enthusiastic, international and Australian, science graduates ideally with a background in engineering, biophysics, cell biology, neuroscience or any other relevant scientific discipline. Candidates will have a First Class Honours degree or equivalent and should be eligible for UQ scholarship consideration. Previous experience with microscopy, image analysis, and cloning is desirable, but applicants with no background in biology are also encouraged to apply for this position.  
Applicants must fulfill the PhD admission criteria for the University of Queensland, including meeting English language requirements and demonstrating excellent capacity and potential for research. Demonstration of research ability through publication output in peer-reviewed international journals is desirable.

Contact

Single Molecule Neuroscience Laboratory

 Group leader: Professor Frederic Meunier    f.meunier@uq.edu.au

Background

The Neural Migration Laboratory is headed by Professor Helen Cooper. Professor Cooper’s research investigates the molecular signalling pathways regulating neural stem cell activity, neuronal differentiation and migration, and synapse formation in the developing brain. A major research theme is the identification of the molecular mechanisms underpinning neuropsychiatric disorders such as autism and schizophrenia. The laboratory uses developmental mouse models, in vitro stem cell culture systems and state-of-the-art molecular/cellular biological approaches and super-resolution microscopy.

 Learn more about the Cooper Lab.

Project aim

Abnormal synapse formation leads to diminished synaptic transmission and impaired cognitive function. The goal of this project is to identify the molecular pathways that govern synaptic connectivity. This research will not only provide key insights into the fundamental principles guiding the establishment of complex neural circuits, but will also shed light on the aberrant processes contributing to autism and schizophrenia.

Your role

The Cooper lab has identified several autism genes predicted to play a central role in building the actin cytoskeleton - an essential requirement for synaptic development and synaptic transmission. This project will investigate how mutations in these genes impacts actin remodelling and synaptic function. To address these questions the successful candidate will utilize the following experimental tools: developmental mouse models, in vitro neuronal culture systems, state-of-the-art molecular and imaging approaches, including super-resolution microscopy.

Contact

Neural Migration Laboratory

 Group leader: Professor Helen Cooper    h.cooper@uq.edu.au

Background

There is overwhelming evidence that regular physical exercise can counteract cognitive decline in both healthy aging and in neurodegenerative conditions such as Alzheimer’s disease (AD).  However, it is often not practical to prescribe to the elderly, making the development of a pharmacological intervention that could mimic the cognition-enhancing effects of exercise an enticing prospect. In a major advance towards deciphering how exercise affects brain function, we found that platelets are activated by physical exercise and release factors, including platelet factor 4 (PF4), that promote hippocampal precursor proliferation and neurogenesis. 

Project aim

This project will investigate the therapeutic potential of PF4 administration on AD progression using a transgenic mouse model of AD. In addition, it will address whether platelets, or their released factors, can mediate blood-brain barrier permeability to facilitate the delivery of systemic exercise-released neurogenesis-promoting factors to the neural stem cell niche.

Your role

The student who takes part in this project will perform experiments, including mouse behavioural testing, histology, microscopy, and a range of molecular biology techniques, under the supervision of Dr Odette Leiter and Dr Tara Walker. All training in the relevant techniques will be provided. This project will likely generate data that will be included in an associated manuscript on which the student will be an author.

Contact

Dr Tara Walker laboratory 

 Group leader: Dr Tara Walker    t.walker1@uq.edu.au

Background

Depression is among the top public health concerns worldwide, and the third highest burden of all diseases in Australia. For decades, pharmacotherapy for depression has focused narrowly on enhancing monoaminergic neurotransmission resulting in more than 30 approved treatments. Yet, rates of remission are low for any given drug. Recently, ketamine, an approved dissociative anaesthetic, has demonstrated therapeutic efficacy in MDD and PTSD via its action on the glutamate system by potently blocking ionotropic glutamate NMDA (N-methyl-D-aspartate) receptors. Ketamine exerts a rapid onset of positive clinical effects in severely refractory depressed patients consistent across numerous randomised trials, which distinguishes it from conventional slow-acting therapeutics. In the past decade, off-label prescribing of ketamine infusions to patients in Australia and worldwide for post-traumatic stress disorder (PTSD) and major depressive disorder (MDD) has increased.

The therapeutic potential of ketamine (i.e., rapid symptom relief and response in treatment-resistant patients) has stimulated considerable interest in the psychiatric community, and the clinical use of ketamine infusion for the treatment of depression is now an intense focus of research worldwide. However, this further progress is challenged by the absence of reliable and valid predictors of antidepressive response to ketamine.

Project aim

The study aims to identify subpopulations of patients with post-traumatic stress disorder (PTSD) or treatment resistant depression) are more likely (or less likely) to benefit from ketamine treatment using multiple modalities including neuroimaging, blood, cognitive and clinical biomarkers. The study will leverage efforts from the Australian Defence Force, the Department of Veterans Affairs and the Department of Defense- Alzheimer’s Disease Neuroimaging Initiative (DOD-ADNI) database. The study will collect data from patients as part of their standard of care treatment for analysis. Structural and functional 3T-Magnetic Resonance imaging, markers of brain dysfunction, and clinical/cognitive/psychological assessments will be collected from 300 Australian Veterans. This work will be the first of its kind, in Australia and worldwide, to determine at a large scale, predictors of ketamine efficacy in patients with PTSD/TRD.

Your role

The student who takes part in this project will have the opportunity to engage in data collection and interacting with patients at Zed Three Specialist Centre under the supervision of Dr. Alex Lim who is the clinical lead on this project. This will expose the students to the clinical environment should their interest lie in undergoing a clinical role in the future. They will also have the opportunity to collect data, analyse data from multiple modalities such as blood biomarker assays, magnetic resonance imaging data and clinical/cognitive data. This training will be provided to the students on this project.

Contact

Functional neuroimaging and brain injury laboratory

 Group leader: Dr Fatima Nasrallah      f.nasrallah@uq.edu.au 

Background

This Earmarked Scholarship project is aligned with a recently awarded Category 1 research grant. Creative thought is fundamental to human advances throughout history and scientific discovery. It is also needed in daily life to adapt behaviour and solve everyday problems. The cognitive and neural bases of creative thought have not been explored in detail. Most past work in cognitive science has drawn a consistent distinction between needing a knowledge system to generate possibilities and an evaluation system to analyse and refine these ideas. The interplay between these two distinct systems results in productive creative thought. However, the knowledge source and the evaluation mechanisms, and their neural bases, are under-specified (e.g., what are the knowledge sources, how are they evaluated, etc).

Project aim

This project aims to understand the behavioural and brain bases of creative thought by using a novel approach at the intersection between executive control operations and semantic cognition. In brief, executive functions such as response initiation and inhibition, strategy application and flexibility play a critical role in everyday life because they enable individuals to adapt to circumstances, exhibit self-control and to solve new problems as they arise. Semantic cognition refers to our ability to flexibly retrieve and manipulate our generalized knowledge, which is acquired over the lifespan, to support verbal and non-verbal (multimodal) behaviours. In this project both executive control and semantic cognition will be investigated using behavioural and neuroimaging techniques in individuals that are healthy and those with focal brain lesions due to neurological disorders. The focus of the PhD could be on any of these aspects of the project, depending on the candidate.

Your suitability

A working knowledge of cognition, experimental psychology and statistical analysis and a keen interest in neuropsychology would be of benefit to someone working on this project.

The applicant will demonstrate academic achievement in the field(s) of psychology and the potential for scholastic success.

A background or knowledge of cognition and statistical analysis is highly desirable.

Your role

You will be supervised by both Prof Gail Robinson (UQ) and Prof Matt Lambon Ralph (University of Cambridge). You will have opportunities to work with a team of cognitive neuroscientists and clinicial researchers, learning neuropsychological, experimental psychological and neuroimaging methods.

Apply

You need to apply for this project as part of your PhD application.

View application process

Contact

Cognitive and clinical neuropsychology lab

 Group leader: Professor Gail Robinson    Email: gail.robinson@uq.edu.au

Background

As animals walk, run, or hop, motor circuits in the spinal cord convert descending “command” signals from the brain into the coordinated movements of many different leg muscles. How are command signals from the brain deconvolved into the appropriate patterns for motor neuron activity?

Project aim

We aim to answer this question for Drosophila by studying the functional organization of leg motor circuits in the ventral nerve cord, the fly’s analogue of the spinal cord. In Drosophila, individual neuronal cell types can be reproducibly identified and manipulated using genetic reagents that have been developed to target specific descending neurons, interneurons, or motor neurons.

Your role

In your thesis project, you will learn a range of methods including genetics, multiphoton imaging, optogenetics and quantitative behavioural analysis, and use these methods to elucidate the structure and function of the motor circuits controlled by a specific class of descending neuron. This may be, for example, a descending neuron that, when activated, causes the fly to walk backwards (see Bidaye et al, Science 6179:97), or one that elicits turning. Understanding the circuit mechanisms behind those simple actions will shed light on general computational principles of neural networks, and may even help us to design smarter robots.

Contact

Locomotor Circuits in Drosophila lab

Group leader: Professor Barry Dickson   Email: b.dickson@uq.edu.au

Background:

Disruption of the activity of the interneurons, cells that are fundamental for neuronal circuit function, is thought to underlie the emergence of symptoms that characterise Autism Spectrum Disorder. Yet, the molecular mechanisms which control interneuron electrical activity in autism are still largely unknown. Our data indicates that specific modulation of interneuron activity during brain maturation considerably alters adult function and triggers autism -like symptoms in wild-type mice. We show that the pattern of expression of specific molecules is significantly changed in autism, in the prefrontal cortex, a brain structure linked to the core symptoms. We also discovered that specific regulation of the interneuron activity restores normal brain function and behaviour in autism models.

Project Aim:

The proposed PhD project will focus on a molecule the Dehorter lab discovered as a key regulator of interneuron development and autism. Together with the PhD candidate, we propose to investigate the molecular pathway of this new target for the treatment of the most deleterious symptoms of autism (e.g. working memory, social impairments, epilepsy). It will combine electrophysiology, imaging, genetics and molecular biology to precisely characterise how the activity of cortical interneurons underlies brain function and behaviour. By uncovering the cellular and molecular substrates of neuronal dysfunction in mice and in human cell cultures, this research will open new perspectives for identification and use of neurobiological targets amenable to therapy in patients.

PhD Student’s Profile

 The Dehorter lab is seeking enthusiastic Australian and international graduate students, with a background in biophysics, cell biology, neuroscience or any other relevant scientific discipline. Candidates will have a First-Class Honours degree or equivalent and should be eligible for UQ scholarship consideration. Previous experience with electrophysiology, molecular biology and/or microscopy is necessary. Applicants must fulfill the PhD admission criteria for the University of Queensland, including meeting English language requirements and ideally, demonstrating excellent capacity and potential for research (e.g. publication output in peer-reviewed international journals).

Contact:

 https://www.dehorterlab.com/  Email: n.dehorter@uq.edu.au

Background:

Aboriginal and Torres Strait Islander students face significant challenges throughout their schooling experience. The Closing the Gap report (2020) identifies persisting gaps in numeracy and literacy attainment, most likely as a consequence of persistently lower rates of school attendance. Year after year, across school levels, average attendance for Aboriginal and Torres Strait Islander students remains under the critical rate of 90%. Data has shown that the disparity in attendance starts in early primary school and evidence a significant drop at the transition to secondary school.

Project Aim:

In collaboration with industry partners, communities and schools, this project aims to:
-    understand and document reasons behind the average precipitous drop in Aboriginal and Torres Strait Islander students’ educational outcomes once they transition to secondary school (Why?),
-    identify effective culturally-led support strategies during the school transition period 

Primary supervisor – Azhar Hussain Potia

Associate supervisors – Dr Kai Wheeler and Prof. Karen Thorpe

Contact:

Azhar Hussain Potia – a.potia@uq.edu.au

Project Overview:

This PhD project investigates the economic values and implications of community-based reintegration services and brain injury treatment, especially how these initiatives contribute to the long-term outcomes, quality of life, and societal productivity of individuals with brain injuries.

Background:

Brain injury have profound and long-lasting effects on individuals, families and their communities. While acute and medical treatments are critical, the role of rehabilitation and community reintegration services in enhancing the recovery process and improving long-term outcomes is crucial for optimal long-term outcomes. There is a gap in understanding the full economic value these community initiatives bring, not only in terms of cost savings but also in improving the quality of life and societal reintegration of brain injury survivors. By broadening the scope of traditional economic evaluations to include these community services, this study aims to provide a comprehensive assessment that can inform better resource allocation and policy decisions for brain injury.

Research Focus:

• Economic Value Assessment: Investigate the broader economic impacts of community-based initiatives and treatments for brain injury, beyond traditional cost-effectiveness analysis.
• Community Reintegration Services: Evaluate the role of services designed to reintegrate brain injury patients into society, their impacts on long-term outcomes, quality of life, and economic productivity of patients with brain injury.
• Quality of Life Measurement: Integrate health preference methodologies to connect economic evaluations with improvements in quality of life, considering both direct and indirect benefits of community integration.

Candidate Requirements:

• Honours or master’s degree in Economics, Health Economics, Public Health, or a related field.
• Strong analytical skills and experience with economic modelling.
• Interest in community health services, patient outcomes, and policy implications.
• Excellent communication and writing skills.

Desirable Skills:

• Experience in handling large datasets and conducting statistical analyses.
• Familiarity with health preference research and quality of life assessments.
• Knowledge of healthcare systems and policy impact evaluation

Location

The selected candidate will join a dynamic research team at the University of Queensland, working closely with leading experts in economic evaluation and brain injury research.

Application Process

Interested candidates should submit a CV, a cover letter outlining their research interests and experience, and two academic references to f.nasrallah@uq.edu.au or kim.h.nguyen@uq.edu.au.

Background

Concussion is difficult to diagnose and the current technology lacks reliability to detect the brain damage associated with such injury. Evidence suggests that brain recovery goes beyond the resolution of clinical/cognitive symptoms and existing biomarkers lack specificity and require validation. In this work, we have partnered with World Rugby, Rugby Australia, and the Greater Public Schools (GPS) association to study concussion in adolescents using novel blood-based biomarkers, cognitive data, and advanced magnetic resonance imaging (MRI) from teenage athletes who have sustained a sports-related concussion. The innovative data will allow precise diagnosis of concussion and explicit accuracy to inform recovery. The added benefit of advanced MRI will be explored.

Project aim

The overall objective is to investigate advanced neuroimaging methods to enhanced the diagnosis of concussion: The aims are to:

1. Study the structural changes that are induced by a concussion
2. investigate more advanced MRI methods for diagnosis of outcome.
3. Determine the temporal profile of neuroimaging changes over time.

The results from this study will provide objective information that will inform policies and guidelines for diagnosis of concussion.  

Your role

The student who takes part in this project will have a background in neuroscience, psychology, biomedical engineering, sports medicine, or any other relevant discipline. They will have the opportunity to engage with schools and other stakeholders including World Rugby and Rugby Australia. Students will have the opportunity to learn image processing methods, take place in field work with adolescence at GPS schools, build communication skills, and have the opportunity to engage with our industry partners through this project.  

Contact

Functional neuroimaging and brain injury laboratory
Group leader: Dr Fatima Nasrallah  Email: f.nasrallah@uq.edu.au      

Project Overview:

The Queensland Brain Institute (QBI) at the University of Queensland, in collaboration with the Royal Brisbane and Women's Hospital (RBWH), invites applications for a PhD project focusing on the evaluation of hyperacute rehabilitation following traumatic brain injury. This interventional prospective project aims to assess the efficacy of early physiotherapy interventions and their impact on long-term outcomes for patient recovery. The project will leverage cutting-edge research facilities and methodologies to explore innovative rehabilitation techniques that can be implemented shortly after injury.

Background:

Traumatic brain injury (TBI) is a leading cause of mortality and long-term disability worldwide, affecting millions annually. Early intervention in the form of physiotherapy has been identified as a potential factor in improving outcomes, yet the optimal timing and techniques remain underexplored. This PhD project seeks to fill this gap by systematically evaluating the effects of hyperacute rehabilitation strategies to establish best practices.

Research Focus:

The research will primarily focus on:

1. Developing and testing a range of physiotherapy interventions within the first hours following TBI.
2. Assessing the efficacy of these interventions in promoting motor and cognitive recovery over the long term.
3. Utilizing advanced imaging techniques and neuropsychological assessments to measure the outcomes of these interventions.
4. Comparing patient recovery trajectories between early intervention groups and standard care protocols.

Candidate Requirements:

Ideal candidates will have:

• A bachelor’s degree in physiotherapy or a closely related field.
• A demonstrated interest in rehabilitation medicine and a commitment to contributing to significant research that informs and optimizes rehabilitation strategies.
• Registration or eligibility for registration as a physiotherapist in Australia.

Desirable Skills:

Candidates should possess:

• Previous research experience, especially in clinical settings or with clinical trials.
• Excellent communication and interpersonal skills to effectively collaborate with a multidisciplinary team.
• The ability to work independently and drive the project forward, while also contributing to broader team goals.

Location:

The candidate will be based at the Queensland Brain Institute, University of Queensland, Brisbane, with clinical research conducted in collaboration with the Royal Brisbane and Women's Hospital. This placement provides an opportunity to engage with leading clinical researchers and practitioners in a dynamic and supportive environment
 

Application Process:

Interested candidates should submit a CV, a cover letter outlining their research interests and experience, and two academic references to f.nasrallah@uq.edu.au or kim.h.nguyen@uq.edu.au.

Background:

Chronic Traumatic Encephalopathy (CTE) is a progressive neurodegenerative condition associated with repeated head impacts, both in contact sports and non-sporting contexts (e.g., occupational injuries or accidents). Despite growing recognition of its cognitive, mood and behavioural symptoms, many questions remain about its prevalence and underlying pathophysiological mechanisms. Our flagship Symptomatology, Neurocognitive and Pathophysiological changes in Chronic Traumatic Encephalopathy (SNAP-CTE) study assesses individuals with a history of repeated head trauma every two years to track cognitive, mood and behavioural changes. A key aim of this project is to identify which types of head trauma—sporting or otherwise—carry the greatest risk for significant long-term effects.

Project Aim:

This PhD project will focus on developing and validating biomarkers to improve the early diagnosis, treatment and management of CTE. In particular, our research group seeks to establish whether neuroimaging techniques, blood-based markers or other physiological indicators can be routinely employed post-concussion to better predict outcomes. The long-term goal is to translate these findings into clinical practice to improve patient care for individuals at risk of CTE.

Your Role:

As a PhD candidate on this project, you will contribute to participant recruitment, longitudinal data collection and hands-on assessments of cognitive, mood and behavioural symptoms. You will gain experience in advanced neuroimaging protocols, blood biomarker analysis and interdisciplinary clinical research methods. You will be supported in developing expertise across multiple modalities—ranging from imaging to laboratory-based assays and clinical evaluations—to identify and validate reliable markers of CTE risk and progression.

Location:

The candidate will be based at the Queensland Brain Institute, University of Queensland, Brisbane, with clinical research conducted in collaboration with the Royal Brisbane and Women's Hospital. This placement provides an opportunity to engage with leading clinical researchers and practitioners in a dynamic and supportive environment

Application Process:

Interested candidates should submit a CV, a cover letter outlining their research interests and experience, and two academic references to f.nasrallah@uq.edu.au. 

Background

Understanding the brain and its neuronal networks is one of the greatest challenges in science. In our lab, we use the zebrafish model to elucidate key elements of this network. We image and record larval zebrafish neuronal activity over time, across the whole brain and in different environmental conditions.

Project aim

The proposed PHD will focus on the analysis of recordings using a combination of computational methods such as clustering, regression and graph theory to make sense of the dynamical changes of the network in different conditions. The candidate will also be encouraged to develop and explore new methods of analysis adapted to zebrafish model.

Your role

The prospective student will gain comprehensive skills in coding, knowledge in neuronal network and brain states, skills in oral and writing presentations through reports and group meeting attendance, and the opportunity to generate publications from their research.

Contact

Supervisor: Dr Itia Favre-Bulle  Email: i.favrebulle@uq.edu.au