Dr. lindsey glickfeld — tales of win
While Dr. Lindsey Glickfeld was thinking about science since she would be a kid, her entry into neuroscience particularly was serendipitous. Like a newcomer at Stanford College planning to study genetics, she became of see an intriguing email from the graduate student who had been searching for research help. Because it switched out, that graduate student is at Richard Tsien’s lab, and she or he soon found herself joining a neuroscience lab with hardly any understanding of neuroscience whatsoever. The graduate student she labored with was studying neurotransmission – an idea that they was formerly completely not really acquainted with – but she was rapidly enthralled through the techniques that enabled her to visualise neurotransmitters released right into a synapse instantly. After that, her desire for neuroscience only increased, and she or he remained within the Tsien lab studying synaptic transmission in the molecular and cellular levels during her whole time being an undergraduate. Little did she realize that answering that email like a newcomer would set her up for any full career in neuroscience, studying synaptic function completely from the amount of cells, to small-scale circuits, and lastly to full-scale cortical circuits processing visual information being an Assistant Professor of Neurobiology at Duke College.
While Dr. Lindsey Glickfeld was thinking about science since she would be a kid, her entry into neuroscience particularly was serendipitous. Like a newcomer at Stanford College planning to study genetics, she became of see an intriguing email from the graduate student who had been searching for research help. Because it switched out, that graduate student is at Richard Tsien’s lab, and she or he soon found herself joining a neuroscience lab with hardly any understanding of neuroscience whatsoever. The graduate student she labored with was studying neurotransmission – an idea that they was formerly completely not really acquainted with – but she was rapidly enthralled through the techniques that enabled her to visualise neurotransmitters released right into a synapse instantly. After that, her desire for neuroscience only increased, and she or he remained within the Tsien lab studying synaptic transmission in the molecular and cellular levels during her whole time being an undergraduate. Little did she realize that answering that email like a newcomer would set her up for any full career in neuroscience, studying synaptic function completely from the amount of cells, to small-scale circuits, and lastly to full-scale cortical circuits processing visual information being an Assistant Professor of Neurobiology at Duke College.As Lindsey transitioned from her undergrad lab to graduate school in the College of California – North Park, she desired to expand her understanding of synaptic transmission, she was particularly thinking about the way the anatomy and physiology of synapses affected their function. This brought her towards the laboratory of Massimo Scanziani, where she studied how synaptic mechanisms affect inhibition inside a hippocampal circuit. Lindsey loved the kinds of experiments she was doing in grad school but nonetheless found herself wondering how synaptic activity in the circuit level associated with processing details about the atmosphere.
After graduate school, Lindsey made the decision to review the visual system, where experiments can better link the physiology of merely one neuron towards the physical information which exists within the atmosphere. Like a postdoctoral fellow within the laboratory of Clay Reid at Harvard College, she fearlessly made the decision to tackle a very technical experiment that needed imaging and recording in the same neuron within the intact brain as well as in a slice preparation, correspondingly. Although this experiment was considered nearly impossible, she went after it hoping of focusing on how the physical response qualities of neurons within the visual cortex proportional for their connectivity. However, the work was showing to become a lot for an individual, and her effort was further challenged when another group printed is a result of a really similar group of experiments. Some might have quit at this time, but Lindsey, rather of having frustrated, required the chance to change gears and concentrate on another project that ultimately produced thrilling results. In this experience, she was advised of recommendation from her PhD consultant that “there isn’t any such factor to be scooped” since you always gain knowledge from the data. Lindsey has strongly taken this to heart her philosophy would be to perform the experiments you’re enthusiastic about with no anxiety about others doing exactly the same. She remarks that it’s a disservice to science not to verify that what others have proven is replicable. Furthermore, no two datasets are similar in order scientists we have to learn all we are able to in the data we collect. This philosophy has shown effective as Lindsey has completed and printed many influential studies in her own field.
In her own laboratory at Duke College, Lindsey uses a button like a model organism, which enables her to mix genetics, electrophysiology, imaging and behavior to know how visual details are transformed within the visual cortex. For instance, she would like to know how within the visual cortex simple receptive fields arrived at represent some thing complex, as an object. Her scientific accomplishments and impact were recognized at the start of her career using the NIH New Innovator Award.
Throughout Lindsey’s career, curiosity continues to be her driver. Curiosity drove her to reply to a job-defining email, to test a apparently impossible experiment, and also to pursue new questions without fear. Like a principal investigator, Dr. Lindsey Glickfeld now will get to savor the task of leading multiple exciting projects which are formed by her fearlessness and curiosity.
Pay attention to Megan’s full interview with Lindsey on March fifth, 2019 below!
Resourse: https://storiesofwin.org/profiles/2019/6/4/