Research in our laboratory focuses on the physiology of glial cells and on interactions between glia, neurons and blood vessels in the central nervous system. Glia have traditionally been viewed as passive, housekeeper cells in the brain. This view has been overturned in recent years as studies have demonstrated that glial cells have many essential functions in the CNS and may actively participate in information processing. We are studying several aspects of glial cell function, including i) neuronal activation of glial cells, ii) glial cell modulation of neuronal excitability and synaptic transmission, iii) calcium signaling within and between glial cells, and iv) glial cell regulation of blood flow.
We have demonstrated that astrocytes and Müller cells, the two macroglial cells of the retina, generate both spontaneous and neuron-evoked calcium signals. These calcium signals, in turn, lead to the release of transmitters from glial cells, resulting in the modulation of neuronal excitability. We are currently studying how these glial signals affect information processing in the retina. We are also studying how pathology affects glial calcium signaling.
We have shown that factors released from glial cells regulate blood flow in the retina. Light stimulation or direct activation of glial cells results in the release of arachidonic acid metabolites. Some of these metabolites constrict while others dilate vessels. We are studying how glia to vessel signaling is modulated and the role that glial cells play in controlling blood flow.
(For a comprehensive list of recent publications, refer to PubMed, a service provided by the National Library of Medicine.)
- Kuo SP, Chiang PP, Nippert AR, Newman EA. Spatial organization and dynamics of the extracellular space in the mouse retina. J Neurosci. 2020;40(41):7785-7794.
- Nippert AR, Newman EA. Regulation of blood flow in diabetic retinopathy. Vis Neurosci. 2020 Jul 20;37:E004.
- Srienc AI, Chiang PP, Schmitt AJ, Newman EA.Cortical spreading depolarizations induced by surgical field blood in a mouse model of neurosurgery. J Neurosurg. 2019 Apr 5:1-9.
- Nippert AR, Mishra A, Newman EA. Keeping the brain well fed: The role of capillaries and arterioles in orchestrating functional hyperemia. Neuron. 2018;99:248-250.
- Nippert AR, Biesecker KR, Newman EA. Mechanisms mediating functional hyperemia in the brain. Neuroscientist. 2018;24(1):73-83.
- Biesecker KR, Srienc AI, Shimoda AM, Agarwal A, Bergles DE, Kofuji P, Newman EA. Glial cell calcium signaling mediates capillary regulation of blood flow in the retina. J Neurosci. 2016;36:9435-9445.
- Srienc AI, Biesecker KR, Shimoda AM, Kur J, Newman EA. Ischemia-induced spreading depolarization in the retina. J Cereb Blood Flow Metab. 2016;36(9):1579-91
- Kornfield TE, Newman EA. Measurement of retinal blood flow using fluorescently labeled red blood cells. Eneuro. 2015 Mar-Apr;2(2).
- Newman EA. Glial cell regulation of neuronal activity and blood flow in the retina by release of gliotransmitters. Philos Trans R Soc Lond B Biol Sci. 2015 Jul 5;370(1672).
- MacVicar BA, Newman EA. Astrocyte regulation of blood flow in the brain. Cold Spring Harb Perspect Biol. 2015 Mar 27;7(5).
- Kornfield TE, Newman EA. Regulation of blood flow in the retinal trilaminar vascular network. J Neurosci. 2014 Aug 20;34(34):11504-13.
- Kur J, Newman EA. Purinergic control of vascular tone in the retina. J Physiol. 2014;592(Pt 3):491-504.
Current Graduate Students:
Chloe Cable (Neuroscience, University of Minnesota)
Armani Del Franco (Neuroscience, University of Minnesota)
Amy Nippert (Neuroscience, University of Minnesota)
Former Graduate Students:
Kyle Biesecker (Ph.D. 2016, Neuroscience, University of Minnesota)
Tess Kornfield (Ph.D. 2015, Neuroscience, University of Minnesota).
Anja Srienc (Ph.D. 2015, Neuroscience, University of Minnesota).
Anusha Mishra (Ph.D. 2011, Neuroscience, University of Minnesota).
Benjamin Clark (Ph.D. 2009, Neuroscience, University of Minnesota).
Zeb Kurth-Nelson (Ph.D. 2009, Neuroscience, University of Minnesota).
Monica Metea (Ph.D. 2006, Neuroscience, University of Minnesota).