Difference between revisions of "Neuroenergetics: Importance of transport for the regulation of energy substrate fluxes in brain cells"

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== Description of the project ==
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'''Background''': Brain cells were shown to rely on two energy subtrates to sustain their activity: glucose and lactate. Each of these substrates are taken up by brain cells via specific transporters and metabolized in classical biochemical pathways. The critical question remains: Between metabolism and transport, what is the limiting step for the utilization of each energy substrate under resting vs. activated condition?
 
'''Background''': Brain cells were shown to rely on two energy subtrates to sustain their activity: glucose and lactate. Each of these substrates are taken up by brain cells via specific transporters and metabolized in classical biochemical pathways. The critical question remains: Between metabolism and transport, what is the limiting step for the utilization of each energy substrate under resting vs. activated condition?
  
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'''Supervisors''': [[User:LucPellerin|Luc Pellerin]] & [[Aitana Morton de Lachapelle]]
 
'''Supervisors''': [[User:LucPellerin|Luc Pellerin]] & [[Aitana Morton de Lachapelle]]
  
'''Reference''': Barros, LF, Porras OH and Bittner CX (2005) Why glucose transport in the brain matters for PET. Trends Neurosci 28(3):117-119.
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'''Reference''': <biblio>#barros pmid=15749163</biblio>
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== Course outline ==
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'''1st meeting''': Fr. 27/2/09 ([[Luc Pellerin]] & [[Aitana Morton de Lachapelle]])
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* Biological introduction + literature to read. Discussion of the goals of the project.
  
 
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----
Midterm presentation : [[Media:Neuroenergetics_midterm_presentation.ppt]]
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'''2nd meeting''': Fr. 6/3/09 ([[Luc Pellerin]] & [[Aitana Morton de Lachapelle]])
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* Introduction to derivatives, ordinary differential equations and analytical vs numerical resolution.
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* Glucose metabolism: irreversible Michaelis-Menten kinetics.
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* Graphical representation of the metabolic flux as a function of neuronal glucose, in Matlab.
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 +
----
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'''3rd meeting''': Fr. 13/3/09 ([[Aitana Morton de Lachapelle]])
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* Glucose transport: reversible Michaelis-Menten kinetics.
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* Graphical representation of the net transport- and metabolic fluxes as a function of neuronal glucose, in Matlab.
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* Discussion on whether transport and/or metabolism are rate-limiting for glucose consumption by the neurons.
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'''4th meeting''': Fr. 20/3/09 ([[Aitana Morton de Lachapelle]])
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* Exercises on Matlab to solve ordinary differential equations numerically.
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* Outline of the mid-term presentation.
 +
 +
----
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'''5th meeting''': Fr. 27/3/09 ([[Luc Pellerin]] & [[Aitana Morton de Lachapelle]])
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* Discussion of the paper by Barros ''et al.'' <cite>barros</cite>.
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* Small visit of the [http://www.unil.ch/physiologie/page14426.html Physiology Institute] to have an overview of the experimental techniques used (group of [[Luc Pellerin]])
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* Preparation of the mid-term presentation.
 +
 +
----
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'''6th meeting - Midterm presentation''': Fr. 3/4/09
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[[Media:Neuroenergetics_midterm_presentation.ppt]]
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 +
----
 
(Project in [[Course: "Solving Biological Problems that require Math"]])
 
(Project in [[Course: "Solving Biological Problems that require Math"]])
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Revision as of 17:53, 3 April 2009

Description of the project

Background: Brain cells were shown to rely on two energy subtrates to sustain their activity: glucose and lactate. Each of these substrates are taken up by brain cells via specific transporters and metabolized in classical biochemical pathways. The critical question remains: Between metabolism and transport, what is the limiting step for the utilization of each energy substrate under resting vs. activated condition?

Goal: The goal of the project is to determine whether transport of the main energy substrates for the brain, glucose and lactate, can become rate-limiting following an increase in cerebral activity.

Mathematical tools: The student will learn to use a mathematical software (Matlab) in order to conduct simulations from a given set of parameters and equations derived from Michaelis-Menten kinetics.

Biological or Medical aspects: The “biology supervisor” will provide background of the main aspects related to brain energy metabolism and Michaelis-Menten kinetics.

Supervisors: Luc Pellerin & Aitana Morton de Lachapelle

Reference: <biblio>#barros pmid=15749163</biblio>

Course outline

1st meeting: Fr. 27/2/09 (Luc Pellerin & Aitana Morton de Lachapelle)

  • Biological introduction + literature to read. Discussion of the goals of the project.

2nd meeting: Fr. 6/3/09 (Luc Pellerin & Aitana Morton de Lachapelle)

  • Introduction to derivatives, ordinary differential equations and analytical vs numerical resolution.
  • Glucose metabolism: irreversible Michaelis-Menten kinetics.
  • Graphical representation of the metabolic flux as a function of neuronal glucose, in Matlab.

3rd meeting: Fr. 13/3/09 (Aitana Morton de Lachapelle)

  • Glucose transport: reversible Michaelis-Menten kinetics.
  • Graphical representation of the net transport- and metabolic fluxes as a function of neuronal glucose, in Matlab.
  • Discussion on whether transport and/or metabolism are rate-limiting for glucose consumption by the neurons.

4th meeting: Fr. 20/3/09 (Aitana Morton de Lachapelle)

  • Exercises on Matlab to solve ordinary differential equations numerically.
  • Outline of the mid-term presentation.

5th meeting: Fr. 27/3/09 (Luc Pellerin & Aitana Morton de Lachapelle)

  • Discussion of the paper by Barros et al. barros.
  • Small visit of the Physiology Institute to have an overview of the experimental techniques used (group of Luc Pellerin)
  • Preparation of the mid-term presentation.

6th meeting - Midterm presentation: Fr. 3/4/09 Media:Neuroenergetics_midterm_presentation.ppt


(Project in Course: "Solving Biological Problems that require Math")