Honeybee Navigation: Low-level and Cognitive Mechanisms. Anyone watching a honeybee find its way back home effortlessly after flying several kilometres in search of nectar would know that these insects are excellent navigators, despite their diminutive brains and relatively simple nervous systems. The aim of this proposal is to gain a better understanding of the mechanisms by which bees navigate repeatedly to an attractive food source, and recruit their nestmates to visit it. The findings should ....Honeybee Navigation: Low-level and Cognitive Mechanisms. Anyone watching a honeybee find its way back home effortlessly after flying several kilometres in search of nectar would know that these insects are excellent navigators, despite their diminutive brains and relatively simple nervous systems. The aim of this proposal is to gain a better understanding of the mechanisms by which bees navigate repeatedly to an attractive food source, and recruit their nestmates to visit it. The findings should illuminate important principles of animal navigation, as well as suggest novel strategies for robot navigation.Read moreRead less
How do myelinating cells alter brain circuits to facilitate learning? This project aims to identify the brain circuits that receive new insulation and characterise the molecular mediators of this process. This project will apply innovative technologies to understand how the nervous system remains adaptable throughout life. This new knowledge, of the cellular mechanisms that allow brain circuits to remain adaptable throughout life, may have application in the development of interventions aimed at ....How do myelinating cells alter brain circuits to facilitate learning? This project aims to identify the brain circuits that receive new insulation and characterise the molecular mediators of this process. This project will apply innovative technologies to understand how the nervous system remains adaptable throughout life. This new knowledge, of the cellular mechanisms that allow brain circuits to remain adaptable throughout life, may have application in the development of interventions aimed at improving educational outcomes or counteracting age-related memory decline. Potential future benefits include facilitating the development of drugs to circumvent memory loss resulting from brain diseases, and improving the design of neuromorphic hardware for computing.Read moreRead less
To flee or not to flee: surviving on incomplete information. Even lowly animals, like the Australian fiddler crabs we will be investigating, are surprisingly competent in making the right decisions in complex situations. They actively acquire information and make good use of it to assure their immediate safety and their long term gains. Animals are exquisitely honed by evolution and we would benefit greatly by understanding what makes them so competent: on a theoretical level, we may learn about ....To flee or not to flee: surviving on incomplete information. Even lowly animals, like the Australian fiddler crabs we will be investigating, are surprisingly competent in making the right decisions in complex situations. They actively acquire information and make good use of it to assure their immediate safety and their long term gains. Animals are exquisitely honed by evolution and we would benefit greatly by understanding what makes them so competent: on a theoretical level, we may learn about efficient rules of good decision making and on a practical level, we may be able to design more flexible, robust and clever machines. Besides being useful in this wider context, the results of our research will thus also contribute to a new and 'sophisticated' appreciation of the cognitive design of animal.Read moreRead less
Honeybee Vision and navigation, and applications to robotics. Anyone observing a honeybee find its way home effortlessly after collecting nectar would know that these insects are excellent navigators, despite their diminutive brains and relatively simple nervous systems. One aim of this proposal is to gain a better understanding of the mechanisms underling honeybee navigation. Another aim is to apply some of these findings to the development of novel, biologically inspired naviagtion systems for ....Honeybee Vision and navigation, and applications to robotics. Anyone observing a honeybee find its way home effortlessly after collecting nectar would know that these insects are excellent navigators, despite their diminutive brains and relatively simple nervous systems. One aim of this proposal is to gain a better understanding of the mechanisms underling honeybee navigation. Another aim is to apply some of these findings to the development of novel, biologically inspired naviagtion systems for aircraft. The findings should illuminate important principles of animal navigation. They should also advance Australia's technology in the area of unmanned aerial vehicles (UAVs), which will have important applications in national defence and security.Read moreRead less
Learning and memory in the honeybee: Task-dependent brain development. We wish to explore whether the development of specific brain regions in young bees depends upon the nature of the learning task in which they are engaged. We will examine tasks that involve two sensory modalities: olfaction and vision, both of which are important to successful foraging. The relative ease with which bees can be trained, and their nervous systems accessed, make them a very attractive subject in which to study f ....Learning and memory in the honeybee: Task-dependent brain development. We wish to explore whether the development of specific brain regions in young bees depends upon the nature of the learning task in which they are engaged. We will examine tasks that involve two sensory modalities: olfaction and vision, both of which are important to successful foraging. The relative ease with which bees can be trained, and their nervous systems accessed, make them a very attractive subject in which to study fundamental principles of learning and memory that may span a variety of organisms.Read moreRead less
Higher cognitive functions emerging from a small brain. The honeybee is becoming one of the most attractive model systems in which to study processes of learning, memory and cognition, given its rich and flexible behaviour, its relatively simple nervous system, and a genome that is on the verge of being sequenced. We intend to examine how bees learn rules, associations, concepts and categories, and to uncover some of the underlying neuronal substrates. The results should illuminate fundamental p ....Higher cognitive functions emerging from a small brain. The honeybee is becoming one of the most attractive model systems in which to study processes of learning, memory and cognition, given its rich and flexible behaviour, its relatively simple nervous system, and a genome that is on the verge of being sequenced. We intend to examine how bees learn rules, associations, concepts and categories, and to uncover some of the underlying neuronal substrates. The results should illuminate fundamental principles of cognitive function across a variety of animal species, and suggest novel approaches to artificial intelligence.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100508
Funder
Australian Research Council
Funding Amount
$462,948.00
Summary
How predictions affect visual processing across the cortical hierarchy . Unlike traditional theories of visual perception, recent evidence suggests what a person expects can fundamentally change how they see the world. However, the neuronal mechanisms which would allow expectation to affect perception are poorly understood. This project will use revolutionary recording techniques to determine how multiple brain regions interact to use predictions about the future to change visual processing. The ....How predictions affect visual processing across the cortical hierarchy . Unlike traditional theories of visual perception, recent evidence suggests what a person expects can fundamentally change how they see the world. However, the neuronal mechanisms which would allow expectation to affect perception are poorly understood. This project will use revolutionary recording techniques to determine how multiple brain regions interact to use predictions about the future to change visual processing. The expected outcome is understanding a fundamental theory of brain function for the first time at the level of single neurons. This project will contribute to a new understanding of central theories of how the brain allows us to see which will significantly enhance basic vision science.Read moreRead less
ARC Centre of Excellence for Integrative Brain Function. The Centre of Excellence for Integrative Brain Function will address one of the greatest scientific challenges of the 21st century to understand how the brain works. We will investigate complex functions such as attention, prediction and decision-making, which require the coordination of information processing by many areas of the brain. This will require a highly collaborative approach involving neurobiologists, cognitive scientists, eng ....ARC Centre of Excellence for Integrative Brain Function. The Centre of Excellence for Integrative Brain Function will address one of the greatest scientific challenges of the 21st century to understand how the brain works. We will investigate complex functions such as attention, prediction and decision-making, which require the coordination of information processing by many areas of the brain. This will require a highly collaborative approach involving neurobiologists, cognitive scientists, engineers and physicists, allowing us to translate our discoveries into novel technologies for the social and economic benefit of all Australians. We will also train a new generation of multidisciplinary researchers, and contribute our expertise to a range of public education and awareness programs.Read moreRead less