Loading...
The University of Chicago Header Logo
Keywords
Last Name
Institution

Connection

Search Results to Melina E Hale

This is a "connection" page, showing the details of why an item matched the keywords from your search.

                     
                     

One or more keywords matched the following properties of Hale, Melina E

PropertyValue
overview My research integrates biomechanics and neurobiology to study how axial movements are generated and coordinated to respond to the physical properties of an organism's environment. Of particular interest to me are the startle response and rhythmic swimming behaviors of fishes. These behaviors provide excellent model systems for examining motor control and the mechanics of axial movement. Because the startle response involves a discrete behavior, large neurons and simple neural circuits, it has been important in studies of motor control. Because it is critical for survival and involves maximal performance, it has been important for work on muscle physiology and performance. Rhythmic axial and fin swimming has long been studied in lampreys and tadpoles to examine central pattern generation in spinal circuits and in a wide diversity fishes to understand the relationship between morphology and movement. The scope of questions I am asking can be divided into three interconnected research initiatives. The first explores the broad question: How do morphology, physiology and the physics of the aquatic environment interact to produce swimming movement? To address this question, I examine the scaling of locomotor performance through development with changes in the physics of movement such as the Reynolds number, a ratio of inertial to viscous forces. The second area examines the generation of swimming movements. Questions I am addressing include: How do reticulospinal and spinal neurons and circuits generate startle behavior? And, how are gate transitions due to the physics of movement mediated neurally? To address these questions I examine reticulospinal and spinal interneuron morphology and function in zebrafish and examine comparatively species that differ in components of their startle neural circuits. A third area of research examines the evolution of neural circuits and behaviors. Through this work I am addressing the general question: How are neural circuits and behaviors modified evolutionarily? I examine the startle neural circuit in fishes comparatively within a phylogenetic context. In addition, mutant and transgenic zebrafish are providing new ways of addressing evolutionary questions such as this. My approaches to these questions include using zebrafish as a model as well as comparative work on actinopterygian fishes. Larval zebrafish, in addition to being an excellent genetic system, are transparent which makes optical imaging of neuron morphology and activity as well as targeted neuron ablations possible in whole, in vivo preparations. With these techniques, we are able to combine functional imaging studies of neurons with behavior. In order to look simultaneously at neuron activity and fish movement, we label cells with calcium sensitive dyes and simultaneously image neurons firing with confocal microscopy and axial movements with high-speed video. With a complementary set of techniques, we kill neurons with cell targeted laser ablations and can compare behavior before and after the cells are removed. Because with such ablations we are able to very specifically remove cells without collateral damage, these techniques allow fine manipulation of the system.

One or more keywords matched the following items that are connected to Hale, Melina E

Item TypeName
Concept Neural Pathways
Academic Article Evolution of behavior and neural control of the fast-start escape response.
Academic Article Hox gene misexpression and cell-specific lesions reveal functionality of homeotically transformed neurons.
Academic Article Swimming of larval zebrafish: fin-axis coordination and implications for function and neural control.
Academic Article Grading movement strength by changes in firing intensity versus recruitment of spinal interneurons.
Academic Article Neural development of the zebrafish (Danio rerio) pectoral fin.
Academic Article Alternative startle motor patterns and behaviors in the larval zebrafish (Danio rerio).
Academic Article Movement and function of the pectoral fins of the larval zebrafish (Danio rerio) during slow swimming.
Academic Article Activity of pectoral fin motoneurons during two swimming gaits in the larval zebrafish (Danio rerio) and localization of upstream circuit elements.
Academic Article The function of fin rays as proprioceptive sensors in fish.
Academic Article Mapping circuits beyond the models: integrating connectomics and comparative neuroscience.
Academic Article Mechanics of the fast-start: muscle function and the role of intramuscular pressure in the escape behavior of amia calva and polypterus palmas
Academic Article Developmental change in the function of movement systems: Transition of the pectoral fins between respiratory and locomotor roles in zebrafish
Academic Article NSF workshop report: discovering general principles of nervous system organization by comparing brain maps across species.
Academic Article Developmental change in the function of movement systems: transition of the pectoral fins between respiratory and locomotor roles in zebrafish.
Academic Article Functional subdivision of fin protractor and retractor muscles underlies pelvic fin walking in the African lungfish Protopterus annectens.
Academic Article Neural circuits that drive startle behavior, with a focus on the Mauthner cells and spiral fiber neurons of fishes.
Academic Article Local Spinal Cord Circuits and Bilateral Mauthner Cell Activity Function Together to Drive Alternative Startle Behaviors.
Academic Article Making sense of sparse data with neural encoding strategies.

Search Criteria
  • Neural
  • circuit
  • function