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Tutorial: Converting Between Plateau and Pseudo-Plateau Bursting Richard Bertram Department of Mathematics and Programs in Neuroscience and Molecular Biophysics Florida State University, Tallahassee, FL. Modelling Electrical Activity in Physiological Systems, 2012. Coworkers and Collaborators.
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Tutorial: Converting Between Plateau and Pseudo-Plateau BurstingRichard BertramDepartment of MathematicsandPrograms in Neuroscience and Molecular Biophysics Florida State University, Tallahassee, FL. Modelling Electrical Activity in Physiological Systems, 2012
Coworkers and Collaborators Joël Tabak (FSU) Krasimira Tsaneva-Atanasova (Univ. Bristol) Wondimu Teka (FSU) Funding: NSF-DMS0917664 and NIH-DK043200
Two Classes of Bursting Oscillations Plateau bursting Pseudo-plateau bursting Guinea pig trigeminal motoneuron (Del Negro et al., J. Neurophysiol., 81(4): 1478, 1999) S. S. Stojilkovic, Biol. Res., 39(3): 403 , 2006
These are Associated with Different Fast-Slow Bifurcation Structures Fast-slow analysis of plateau or square-wave bursting
These are Associated with Different Fast-Slow Bifurcation Structures Fast-slow analysis of pseudo-plateau or pituitary bursting
How Can Neuron-Like Plateau Bursting be Converted to Pituitary-Like Pseudo-Plateau Bursting? Published in Teka et al., Bull. Math. Biol., 73:1292, 2011
The Chay-Keizer Model T. R. Chay and J. Keizer, Biophys. J., 42:181, 1983 This well-studied model was developed to describe plateau bursting in pancreatic β-cells, but it has also been used as a template for this type of bursting in other cells, such as neurons. We use a variation of this that includes a K(ATP) current and that has lower dimensionality.
The Chay-Keizer Model V=voltage (mV) t= time (msec) n= fraction of open delayed rectifying K+ channels ICa = Ca2+ current IK = delayed rectifying K+ current IK(Ca) = Ca2 +-activated K+ current IK(ATP) = ATP-sensitive K+ current
The Chay-Keizer Model: Ca2+ Dynamics c = free calcium concentration in the cytosol c activates the K(Ca) channels;
Plateau Bursting with Standard Parameter Values c is the slow variable, turning spiking on and off as it varies The bursting can be analyzed by examining the subsystem of fast variables (V and n) with c treated as a parameter
Moving From Plateau to Pseudo-Plateau 1. Make the slow variable, c , much faster. This results in short burst duration and the burst trajectory moves rapidly along the fast subsystem bifurcation structure. To get this, just increase fcyt . • Modify parameter values that change the upper part of the fast subsystem bifurcation structure. This requires changing • appropriate fast subsystem parameters.
Make the Delayed Rectifier Activate at a Higher Voltage Increasing vn shifts the n curve to the right. Red = old curve Blue = new curve vn
Bifurcation Structure for Pseudo-Plateau Bursting Achieved by Increasing vn vn increased from -20 mV to -12 mV, and c speeded up by increasing fcyt from 0.00025 to 0.0135.
Bursting Types Depend on the Order of Bifurcations • c-values at the bifurcation points: • plateau bursting: • supHB < LSN < HM < USN • Transtion bursting: • LSN < subHB < HM < USN • Pseudo-plateau bursting: • LSN < HM < subHB < USN • By using a two-parameter bifurcation diagram, we can determine the parameter regions for these bursting patterns.
Other Approaches 2. Shift the Ca2+ activation curve leftward 3. Decrease the delayed rectifier channel conductance 4. Increase Ca2+ channel conductance In all four approaches, making the cell more excitable converts the plateau bursting to pseudo-plateau bursting.
WhyDoes it Work? If one treats V as the sole fast variable and n and c as slow variables, then in the singular limit a folded node singularity is created. Teka et al., J. Math. Neurosci., 1:12, 2011