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Dr Antonio Padilha L. Bo completed the BEng and MSc at the University of Brasília, Brazil, in 2004 and 2007, respectively, and he was awarded the PhD from the University of Montpellier, France, in 2011. From 2011 to 2019, he has been a tenured assistant professor in electrical engineering at the University of Brasilia, Brazil, where he coordinated Project EMA (Empowering Mobility and Autonomy), which is one of the teams that took part in the Cybathlon competition in 2016 and 2020. He has co-authored over 75 peer-reviewed publications, including awards from societies such as IFAC, IFESS, and MICCAI.

Over the past ten years, Dr Bo has been engaged in research projects concerning the development of technology dedicated to healthcare, particularly in the design of systems to be directly used by a patient in rehabilitation or assistive settings. Every effort featured strong experimental work and was conducted in close collaboration with local rehabilitation centers. In his work, tools from neuroengineering, robotics, control, virtual reality, and instrumentation are often integrated to create devices and algorithms to sense and control human motion. For instance, he has used wearable sensors to segment and estimate parameters of human movement in real-time, a technique that may lead to novel rehabilitation protocols. More importantly, his work has also focused on developing closed-loop control strategies for electrical stimulation applications and prosthetic/orthotic devices. Some examples include systems based on superficial electrical stimulation to enable persons with spinal cord injury to exercise using the lower limbs (e.g. in cycling or rowing) and to attenuate the effects of pathological tremor in essential tremor and Parkinson's Disease.

His long-term research goal is to develop and evaluate the use of noninvasive technology, including electrical stimulation, robotics, virtual reality, and wearable devices, for improving rehabilitation and assistance for persons with motor disabilities.

Dr Giovanni Pietrogrande obtained his PhD from the University of Newcastle. Here he explored how different brain processes are affected by the activation of microglia, the immune cells resident within our brain. In particular his work shows that microglia mediated inflammation has a pivotal role in neuronal loss following brain ischemic injury. He has developed an entirely new method to recreate the human brain in vitro using organoid technology and is utilizing these advanced organoids to gain novel insights into the pathophysiology of neuroinflammatory diseases.

In late 2019 he joined the Stem Cell Engineering lab at the Australian Institute for Bioengineering and Nanotechnology in Queensland. Now he uses and improves cutting-edge techniques for CRISPR-Cas9 mediated gene editing to modify the genome of induced pluripotent stem cells and generate brain and spinal cord organoids to model neurological diseases and evaluate potential treatments.

Dr. Pietrogrande has also established collaborations with biotechs and startups, employing genetic engineering to modify cells for product development and organoid-based compound screening. Additionally, he provides consultancy services for Stemcore and Phenomics Australia, both UQ-based facilities, driving advancements in stem cell research.

I graduated from The University of Tasmania, and received my PhD in Developmental Biology from The University of Queensland in 2003. My PhD, performed at the Institute for Molecular Bioscience with Prof. Melissa Little, centred on understanding the cellular and molecular mechanisms underlying embryonic kidney development. My first postdoc was performed with Prof. Christine Holt at The University of Cambridge, UK, where I studied the mechanisms by which axonal growth cones navigate to their targets in the brain, using the frog Xenopus laevis as a model system. In my second postdoctoral position, with Prof. Linda Richards at the Queensland Brain Institute at The University of Queensland, my work focussed on understanding the molecular mechanisms of neural progenitor cell specification in the developing cerebral cortex. In late 2010, I took up a joint position with the Queensland Brain Institute and The School of Biomedical Sciences (SBMS) to continue my research into the mechanisms underlying neural stem cell differentiation. I have held numerous fellowships during my career, including an NHMRC Howard Florey Fellowship, an NHMRC CDF and an ARC Future Fellowship. I currently hold a continuing Teaching and Research position within SBMS, and am currently the Director for Higher Degree Research Training at SBMS.

Dr Juan Carlos Polanco leads a research team on "Extracellular Vesicles and Neurodegenerative Disorders" at the Clem Jones Centre for Ageing Dementia Research (CJCADR), part of the Queensland Brain Institute (QBI) at the University of Queensland (UQ). He holds an MSc in Biochemistry from the National University of Colombia and a PhD in Molecular Bioscience from UQ. During his PhD, Dr Polanco made significant contributions to understanding how SOX genes are involved in XX disorders of sex development. He furthered his expertise during a postdoctoral fellowship at CSIRO, developing assays to detect unstable human-induced pluripotent stem cells prone to tumorigenesis.

In 2013, Dr Polanco joined Prof. Jürgen Götz's lab at CJCADR, where he began pioneering work on small extracellular vesicles, known as exosomes. His highly cited 2016 paper in the Journal of Biological Chemistry was the first to demonstrate that exosomes encapsulate 'Tau seeds' capable of inducing Tau aggregation in recipient cells. He also showed that exosomes can propagate between interconnected neurons and that some exosomes internalised by neurons are re-released by hijacking endogenous secretory endosomes, thereby increasing their pathogenicity (Acta Neuropathologica Communications, 2018). Since 2019, Dr Polanco has secured NHMRC grants and leads a research team within Prof. Götz's larger laboratory at CJCADR.

I received my Bachelor's in Biology (2001) from Yarmouk University in Jordan, followed by postgraduate degrees from the University of Houston in Houston-Texas (2002-2007). My studies are integrative in nature, joining the best of both the Neuroscience world and Circadian Biology (the study of biological clocks). In the laboratory of Prof. Arnold Eskin, I investigated how processes as complex as learning and memory are modulated by biological clocks i.e. the circadian (about 24 hours) system, using Aplysia californica as the experimental model. After completing my Master's in Science in 2005, my research focused on the mechanism by which biological clocks modulate learning and memory. This work was performed in the laboratories of Prof. Gregg Cahill and Prof. Greg Roman, experts in chronobiology and behavioral neuroscience, respectively. Using Zebrafish as a model system, I investigated the role of melatonin, a night-time restricted hormonal signal, in modulating long-term memory consolidation. My findings, published in Science in 2007, shows that the circadian system via the cyclic night-time confined synthesis/release of melatonin “the hormone of darkness” functions as a modulator, shaping daily variations in the efficiency by which memories are processed. After receiving my Ph.D. in 2007, I joined as a postdoctoral fellow the laboratory of the pharmacologist and melatonin researcher Prof. Margarita Dubocovich. My postdoctoral work engaged in elucidating the role of melatonin in circadian physiology and pharmacology during development and ageing in rodents (Mus musculus) and non-human primates (Macaca mulatta) at the Feinberg School of Medicine (Northwestern University-Chicago) and the State University of New York (SUNY). From 2010-2015, I held a teaching/research position in the Dr. Senckenbergische Anatomy and the Dept. of Neurology at the Goethe University in Frankfurt-Germany. During this time, I was involved in teaching gross human anatomy while continuing my endeavor in understanding the mechanistics involved in shaping memory processes (acquisition, consolidation and retrieval) by the circadian system.

I am a genetic epidemiologist specialising in the genetics of neurodegenerative diseases, with a particular focus on Parkinson’s disease, chronic pain, and other age-related conditions. I lead a dynamic team of scientists dedicated to understanding how genetic and environmental factors influence neurodegeneration, brain health, and related health outcomes. My research is interdisciplinary, integrating advanced statistical genetics, bioinformatics, and data science to unravel disease mechanisms, improve patient stratification, and identify potential therapeutic targets.

In 2020, I founded the Australian Parkinson’s Genetics Study (APGS), now the largest Parkinson’s cohort in Australia with over 10,000 participants. This landmark study has positioned Australia as a key contributor to global Parkinson’s genetics research. I am also actively involved in the Global Parkinson’s Genetics Program (GP2), where I contribute to large-scale data analysis and work within the underrepresented populations working group to enhance diversity in genetic research worldwide.

Committed to training the next generation of researchers, I have supervised over 16 students, including several PhD candidates who have gone on to successful careers in academia and industry. Two of my recent PhD graduates received the Outstanding Thesis Award, and another received the AIPS Florey Next Generation Award.

I have published consistently in prominent journals, including Nature, Nature Genetics, Nature Communications, BRAIN, Biological Psychiatry, and SLEEP. To date, I have authored over 100 academic articles, which have been widely cited, and I have secured competitive funding from NHMRC, MRFF, The Michael J. Fox Foundation for Parkinson’s Research, Shake It Up Australia Foundation, the US National Institutes of Health, and the Alzheimer’s Association. My work has been recognised with several prestigious awards, including the 2023 Al & Val Rosenstrauss Fellowship from the Rebecca L Cooper Medical Research Foundation, the 2021 Enrico Greppi International Migraine Research Award, and the 2024 Adele Green Emerging Leader Award from QIMR Berghofer Medical Research Institute. I am also a Global Atlantic Fellow for Equity in Brain Health, a program by the University of California San Francisco and Trinity College Dublin, which supports my commitment to promoting brain health equity worldwide.

I am a postdoc at the Computational Imaging Group, led by Steffen Bollmann. I recently finished my Ph.D. in Computational Imaging at UQ. Specifically, my Ph.D. work involved predicting the functional organization of the human visual cortex from underlying anatomy using geometric deep learning. To tackle this and other research questions, I am leveraging my interdisciplinary background in Biophysics (Bachelor's degree; University of Sao Paulo, Brazil), Neuroscience (Master's degree; Federal University of ABC, Brazil), and now the intersection of AI and imaging. I am interested in (geometric) deep learning, vision, neuroscience, and explainable and fair AI research.

I am an early career neuroscientist investigating the capacity for neural progenitor cell behaviour to shape neural circuit formation, maintenance and function during development and throughout adulthood. More specifically, the role of oligodendrocyte progenitors and myelin in brain circuit formation and maintenance. My research examines the brain under health and pathological conditions by performing manipulations relevant to autism spectrum disorder, multiple sclerosis and schizophrenia. While under the supervision of Prof Helen Cooper at the Queensland Brain Institute – University of Queensland - I studied how the WRC-Cyfip1-FMRP protein network impaired apical radial glial progenitor function and neural migration, leading to cortical malformation and Autism-like traits in mice. During my PhD at University of Tasmania and under the supervision of Prof Kaylene Young, I studied the effect of neuronal activity on cells of the oligodendrocyte lineage. I found that voltage-gated calcium channels are critical for oligodendrocyte progenitor cell survival and characterised the impact of kainite receptor dysfunction on neuropathology and behaviour in mice. Currently under the supervision of Dr Carlie Cullen I am using transgenic mice strategies to determine how aberrant myelination can contribute to onset of neuropsychiatric and neurodegenerative disorders. I am also using mouse models of demyelination to investigate the effect of infectious diseases such as COVID19 and influenza on oligodendrocyte lineage cell function and the impact for myelin repair and multiple sclerosis disease progression. I have a long-standing interest in neuroscience research, that extends from understanding how brain function is regulated during development and in healthy ageing, and the dysregulated signalling pathways that enable neurodevelopmental and neurodegenerative disorders.

Professor Pankaj Sah is Director of the Queensland Brain Institute (QBI) at The University of Queensland (UQ). He is renowned for his work in understanding the neural circuitry of the amygdala, an area of the brain that plays a central role in learning and memory formation. Dysfunction of the amygdala leads to a host of anxiety-related disorders. His laboratory uses a combination of molecular tools, electrophysiology, anatomical reconstruction, calcium imaging and behavioural studies to examine the electrophysiological signatures of different brain regions and their impact on disease. Recently, his laboratory has been working with patients undergoing electrode implantation for deep brain stimulation, which is used to treat a variety of disorders such as Parkinson's disease, Tourette's syndrome and essential tremor. Professor Sah trained in medicine at The University of New South Wales and, after completing his internship, gained a PhD from the Australian National University. Following postdoctoral work at the University of California, San Francisco, and UQ, he established his own laboratory at the University of Newcastle in 1994. He then joined the John Curtin School of Medical Research at the Australian National University as a group leader in 1997. He was recruited to QBI as a founding member in 2003, and has been Director since July 2015. Professor Sah has published over 110 papers in international peer-reviewed journals. He is also the Editor-in-Chief of the Nature Partner Journal npj Science of Learning, the first journal to bring together the findings of neuroscientists, psychologists, and education researchers to understand how the brain learns.

Leanne Sakzewski is an Associate Professor at the Queensland Cerebral Palsy and Rehabilitation Research Centre, Faculty of Medicine, The University of Queensland. Leanne completed her undergraduate training in the field of occupational therapy at the University of Queensland. Prior to entering research, she practiced as a senior occupational therapist for eighteen years in paediatric rehabilitation and child development. She completed her PhD in 2010 from The University of Queensland in the field of upper limb rehabilitation for children with cerebral palsy, and achieved a Dean's Commendation for outstanding Research Higher Degree.

Research interests

Leanne's research interests are in the conduct of randomised clinical trials in the field of cerebral palsy and childhood onset acquired brain injuries. In particular, she has focused on randomised controlled trials of:

* upper limb training approaches for infants and children with unilateral cerebral palsy;

* intensive models of motor training to improve gross motor and manual abilities for children with bilateral cerebral palsy;

* participation-focused intervention to increase physically active leisure for children with cerebral palsy;

* social skills group-based program for adolescents with brain injuries.

The human nervous system is no longer thought of has hard-wired, and is in fact capable of rapid change throughout life. This plasticity is important for learning, memory and recovery from brain injury. I am interested in using emerging brain stimulation and imaging techniques to "artificially" induce plasticity in the human brain, to ultimately improve the treatment outcomes for various neurological conditions, particularly stroke. These stimulation techniques include transcranial magnetic stimulation (TMS) and transcranial direct current stimulation (tDCS).

I completed a BSc in 1994 and received a First Class Honours in Physiology in 1995 from the University of Adelaide. I then completed a Bachelor of Physiotherapy Degree at the University of South Australia. Returning to research in 2005, I undertook a PhD at the University of Adelaide, which I completed in 2009. My doctoral studies focussed on a new and exciting area of neuroscience – neuroplasticity. At the time of commencing my PhD, it was becoming clear that various non-invasive brain stimulation techniques (such as TMS) were able to temporarily reorganise the circuitry in the human brain in a similar way to what happens when we learn something new or store a memory. I was interested in trying to understand why some people responded to these stimulation paradigms, and others didn’t. What I discovered was that it an important driver of plasticity in humans was when the stimulation was delivered. In effect, the brain seemed to learn better at night time compared to the morning. This has important clinical implications, as it suggests that rehabilitation might be more effective at a certain time of day.

I was awarded a University of Queensland Postdoctoral Fellowship in 2010, and then a NH&MRC Postdoctoral Research Fellowship in 2011 to investigate more intensely how the brains of stroke patients rewire. I am using state-of-the-art stimulation and imaging techniques such as TMS, magnetic resonance imaging (MRI) and electroencephalography (EEG) to understand how the brain reorganises when it stores information, and how we can boost this process.

I am currently an Associate Professor and Head of Physiotherapy within the School of Health and Rehabilitation Sciences at UQ. I head my own brain stimulation and imaging laboratory, and am conducting experiments in the following areas:

a) investigating the link between brain oscillations, sleep, plasticity and ageing;

b) improving hazard perception with brain sitmulation;

c) identifying factors that improve neuroplasticity induction in health and disease.

Dr Kirstine Shrubsole is an NHMRC Emerging Leadership Fellow at the Queensland Aphasia Research Centre. She holds a Bachelor of Speech Pathology (First Class Honours) from The University of Queensland, and completed her PhD in 2018. Kirstine has a research focus on improving implementation of evidence into practice in speech pathology and multidisciplinary services, with a special interest in stroke and aphasia rehabilitation. She has demonstrated that practice change is achievable for healthcare teams working in aphasia, leading to positive outcomes for patients, clinicians, and organisations.

Kirstine has published over 40 peer-reviewed journal articles, and has been awarded over $6 million in competitive research funding. Kirstine previously worked as the Conjoint Research Fellow in Speech Pathology (Princess Alexandra Hospital and The University of Queensland), providing research capacity building and mentoring to speech pathologists and supporting multidisciplinary research. Kirstine is the co-founder and Deputy Lead of the Collaboration of Aphasia Triallists’ Implementation Science in Aphasia working group, and a research affiliate of the Centre for Research Excellence in Aphasia Rehabilitation and Recovery.

Kirstine is completing a NHMRC Emerging Leadership Fellowship on the following topic:

• The Aphasia Implementation Toolkit Project: Developing an implementation intervention to improve services for stroke survivors with aphasia

She is a chief investigator on three MRFF grants, including:

• Unspoken, Unheard, Unmet: Improving Access to Preventative Health Care through Better Conversations about Care

• Bridging the Digital Divide: Building Health Self-Efficacy through Communication-Accessible Online Environments

• Enhancing utility of neuropsychological evaluation for earlier and effective diagnosis of dementia in Parkinson's disease

I am a biologist interested in the general question of how changes in developmental processes can lead to evolutionary variation and origin of complex traits (such as neural circuits). I study development and evolution of the brain of mammals. My doctoral thesis studied brain regions involved in olfactory and pheromonal communication in mammals. I discovered several events of parallel co-variation of sensory pathways in distantly related species sharing similar ecological niches, as cases of ontogenetic and phylogenetic plasticity. Currently, I study development and evolution of neocortical circuits by following two main lines of research: one aims to determine how early neuronal activity emerges during development and help shape brain connections, and the other one aims to understand what developmental processes led to evolutionary innovations in the mammalian brain. My research combines molecular development (electroporation, CRISPR), transcriptomics, sensory manipulations, neuroanatomy mapping (MRI, stereotaxic tracer injections, confocal and image analysis), optogenetics, and in vivo calcium imaging (multiphoton and widefield) in rodent pups and marsupial joeys.

Dr Daniel Sullivan is a Clinical Psychologist and Adjunct Lecturer in the Child Health Research Centre, The University of Queensland. In his clinical role, Dr Sullivan leads a program of research to design Australia's first psychology extended scope of practice model of care for limited pharmacotherapy management, with an emphasis on deprescribing hypnotic medicines in the public sector sleep psychology setting (ExPEDiTe Sleep project). As a member of the Let’s Yarn about Sleep group at the University of the Sunshine Coast, Dr Sullivan is working to improve sleep health equity for First Nations Australians through community co-designed, culturally responsive sleep programs which harmonise sleep science with Indigenous Australian perspectives and knowledges about sleep.

Dr Sullivan’s research and clinical expertise is in the behavioural aspects of sleep; he is an Editor of the journal Research Directions: Sleep Psychology (Cambridge University Press) and is board certified by the US-based Board of Behavioral Sleep Medicine. Dr Sullivan completed postgraduate training in sleep at the University of Sydney (MSc), and his PhD in Clinical Psychology at Griffith University, where his doctoral research examined psychological factors involved in sleep-related headaches.

Dr Hongfu Sun completed his PhD in Biomedical Engineering at the University of Alberta in 2015, followed by postdoctoral training in Calgary until 2018. He joined the Imaging, Sensing and Biomedical Engineering team in the School of ITEE at UQ in 2019 and was awarded the ARC DECRA fellowship in 2021. His research interests include developing novel magnetic resonance imaging (MRI) contrast mechanisms, e.g. Quantitative Susceptibility Mapping (QSM), fast and multi-parametric MRI acquisitions, and advanced image reconstruction techniques, including deep learning and artificial intelligence, to advance medical imaging techniques for clinical applications.

Dr Sun is currently recruiting graduate students. Check out Available Projects for details. Open to both Domestic and International students.