Difference between revisions of "MiPNet27.05 Schroecken BEC tutorial-Living Communications pmP"
(42 intermediate revisions by 4 users not shown) | |||
Line 1: | Line 1: | ||
{{ | {{BEC}} | ||
{{Publication | {{Publication | ||
|title=[[File:BEC-logo.png|right|120px|link=Gnaiger 2020 BEC MitoPathways]] | |title=[[File:BEC-logo.png|right|120px|link=Gnaiger 2020 BEC MitoPathways]] | ||
'''Schroecken AT''', 2022 Sep 30-Oct 02. BEC-Living Communications | '''Schroecken AT''', 2022 Sep 30-Oct 02. BEC tutorial-Living Communications: ''pmF'' — pre '''IOC155'''. | ||
|authors=Oroboros | |authors=Oroboros | ||
|year=2022-09-30 | |year=2022-09-30 | ||
|journal=Mitochondr Physiol Network | |journal=Mitochondr Physiol Network | ||
|abstract= | |abstract= | ||
'''BEC-Living Communications | '''BEC tutorial-Living Communications. Mitochondrial membrane potential and Peter Mitchell’s protonmotive force: elements of the science of bioenergetics. | ||
Preceding the '''Oroboros O2k-Workshop on high-resolution respirometry'''. Schroecken, Austria; 2022. | Preceding the '''[[MiPNet27.04 IOC155 Schroecken AT |Oroboros O2k-Workshop on high-resolution respirometry]]'''. Schroecken, Austria; 2022. | ||
[[File:Gnaiger 2020 BEC MitoPathways.jpg|left|100px|link=Gnaiger_2020_BEC_MitoPathways|Gnaiger 2020 BEC MitoPathways]] | [[File:Gnaiger 2020 BEC MitoPathways.jpg|left|100px|link=Gnaiger_2020_BEC_MitoPathways|Gnaiger 2020 BEC MitoPathways]] | ||
The mitochondrial membrane potential is an element of the science of bioenergetics, linked to the control of respiratory flux and related mitochondrial functions. A PubMed search on ‘mitochondrial membrane potential’ yields nearly 40 000 results and 3442 for 2021 (search 2022-07-04), with a linear increase during the past 20 years. [[Gnaiger_2020_BEC_MitoPathways#Chapter_8._Protonmotive_pressure_and_respiratory_control |Chapter 8]] on ‘Protonmotive pressure and respiratory control’ of [[Mitochondrial Pathways]] (Gnaiger 2020) introduces a novel perspective on Peter Mitchell’s protonmotive force, which incorporates the mitochondrial membrane potential. If you find the reading is tough, you are not alone. Join this BEC-Living Communications | The [[mitochondrial membrane potential]] is an element of the science of bioenergetics, linked to the control of respiratory flux and related mitochondrial functions. A PubMed search on ‘mitochondrial membrane potential’ yields nearly 40 000 results and 3442 for 2021 (search 2022-07-04), with a linear increase during the past 20 years. [[Gnaiger_2020_BEC_MitoPathways#Chapter_8._Protonmotive_pressure_and_respiratory_control |Chapter 8]] on ‘Protonmotive pressure and respiratory control’ of [[Mitochondrial Pathways]] (Gnaiger 2020) introduces a novel perspective on Peter Mitchell’s protonmotive force, which incorporates the mitochondrial membrane potential. If you find the reading is tough, you are not alone. Join this BEC tutorial-Living Communications for a fundamental introduction into the relevant concepts of physical chemistry, which differ from [[Force#Thermodynamic_ignorance |misleading chapters in bioenergetics textbooks]]. A retreat with plenty of informal discussions and group interactions takes you on a journey to visit chemical potential differences versus potential gradients, Gibbs [[energy]] versus Gibbs [[force]], quantities of capacity versus intensity, protonmotive force and [[motive unit]]s, [[flow]]s and [[force]]s, and finally protonmotive [[pressure]]. This will introduce students (and teachers) to a new understanding of mitochondrial membrane potential and the protonmotive force, connecting the ideal gas equation, osmotic pressure, the [[Boltzmann constant]] and [[gas constant]] with [[Fick 1855 Pogg Ann |Fick’s]] and [[Einstein 1905 Ann Physik 549 |Einstein’s diffusion equation]]. If theory gets dry and grey, join for a swim in lake Körbersee, for a Walk&Talk in the colorful alpine environment of the Schröcken-Tannberg region, and a visit to the [https://www.alpmuseum.at/ Alpmuseum ufm Tannberg]. | ||
|mipnetlab=AT_Innsbruck_Oroboros | |mipnetlab=AT_Innsbruck_Oroboros | ||
}} | }} | ||
[[File:Vector flux and velocity.jpg|right|330px |Vector flux and velocity|link=Gnaiger_2020_BEC_MitoPathways#Chapter_8._Protonmotive_pressure_and_respiratory_control|thumb|Figure 8.9. Vector flux and velocity: stationary state of diffusion in a linear concentration gradient.]] | |||
__TOC__ | |||
Last update: 2022-07-17 | |||
== Venue == | |||
[[File:Schroecken Wiki.JPG|right|330px]] | |||
:::: Hotel Körbersee, Schröcken, AT | |||
:::: Information on travel and venue: '''[[IOC Schroecken]]'''. | |||
== Program == | |||
[[File:Hydrogen ion circuit.jpg|right|330px|thumb|Figure 1.1. Coupling in oxidative phosphorylation is mediated by the protonmotive force ''pmF''.]] | |||
::::* '''BEC tutorial''': program for 2022 Sep 30-Oct 02 (Fr to Su) | |||
::::::* Preceding the [[MiPNet27.04 IOC155 Schroecken AT |Oroboros O2k-Workshop on high-resolution respirometry]], 2022 Oct 03-08 (Mo to Fr). | |||
=== ''pmF'': a unifying theory of biology - from metabolism to physical chemistry === | |||
::::* Peter Mitchell's concept of the protonmotive force ''pmF'' is one of the grand unifying theories of biology, on par with Charles Darwin's theory of evolution, Gregor Mendel's rules of inheritance and classical genetics, and the structure of DNA resolved by Francis Crick, James Watson, and Rosalind Franklin. The ''pmF'' combines the disciplines of biochemistry (metabolism), cell biology (cellular ultrastructure), physiology (energy transformation), thermodynamics (chemical potential, Gibbs energy), and physical chemistry (diffusion, electrochemistry). | |||
::::* This BEC tutorial links different disciplines and describes different processes (transformations) by the same principles and relations of isomorphic quantities: | |||
::::::# metabolic reactions and translocation (scalar and vectorial) | |||
::::::# diffusion (from Fick's law to Einstein's diffusion equation) | |||
::::::# electrochemical potentials (compartmental differences versus gradients) and motive forces (of physics and thermodynamics - from the Boltzmann constant and gas constant to the electromotive constant) | |||
::::::# osmotic pressure (from the gas law to protonmotive pressure) | |||
''' | ::::* '''Remember ZEN, ''zeNA''''' — Section 8.2.8 - <big>∞</big>2<big>∞</big> | ||
:::: | :::::::: RM Pirsig (1974) <span style="color:#0000FF"> ''Zen and the art of motorcycle maintenance. An inquiry into values.''</span style> William Morrow & Company:418 pp. | ||
:::::::: <span style="color:#0000FF">Thermodynamics</span style> (''motorcycle maintenance'') may be dull and tedious drudgery (<span style="color:#0000FF">without curiosity beyond “[[≡]]”</span style>) or a valuable and exciting art (if you seek for “=” ZEN). Transformation of dumb, dry and frigid equations into eloquent formulae radiating meaning and sparkling knowledge depends on motivation, skill and persistence (''zeNA''). | |||
::::::::» Compare numerical [[equivalence]] (symbol ≡) and physicochemical [[equality]] (symbol =). | |||
== | === Why? === | ||
[[ | ::::* Why are mitochondria small? Why is [[LEAK respiration]] a non-linear (non-Ohmic) function of the [[mitochondrial membrane potential]] difference Δ''Ψ''<sub>p<sup>+</sup></sub>? | ||
:::: | ::::* Why is the [[mitochondrial membrane potential]] difference Δ''Ψ''<sub>p<sup>+</sup></sub> — the chemical part of the ''pmF'' — not a force of physics? Similarly, the protonmotive force is not a force of physics. Why '[[isomorphic]]' forces? | ||
::::* Why can we start a chemical reaction (in a homogenous [[system]]) or compartmental diffusion (in a [[discontinuous system]]) at an infinitely large [[force]] - without the system exploding? | |||
:::: | === Consider some fundamental quantities === | ||
::::: | [[File:Gibbs energy advancement.png|right|330px|link=Gnaiger_2020_BEC_MitoPathways#Chapter_8._Protonmotive_pressure_and_respiratory_control |Gibbs energy and advancement|thumb|Figure 8.5. Gibbs energy as a function of advancement of transformation in a closed isothermal system at constant pressure.]] | ||
::::* Among the key isomorphic quantities are: | |||
::::::# [[advancement]] and [[stoichiometry]] as the determinants of transformation [[flow]]s | |||
::::::# [[motive entity]] - this is what flows | |||
::::::# [[motive unit]]s for [[count]], [[amount]], and [[charge]] | |||
::::::# chemical and electric partial forces of the ''[[pmF]]'' | |||
:::: | ::::* Important distinctions: | ||
::::::# [[system]]s: closed, compartmental, open | |||
::::::# transformations: [[vector |vectoral]] (along continuous gradients), vectorial (across discontinuous boundaries between compartments), scalar (within systems, without spatial direction) | |||
::::::# Gibbs [[energy]] ([[exergy]]), [[chemical potential]], and metabolic [[force]] (Gibbs force) | |||
::::::# potential gradients versus potential differences | |||
::::::# [[proton]]s p<sup>+</sup> and [[hydrogen ion]]s H<sup>+</sup> | |||
::::::# (chemiosmotic) [[pressure]] versus (protonmotive) [[force]] | |||
{{Keywords: Force and membrane potential}} | |||
: | |||
=== Gibberish === | |||
::::* Forget all gibberish that you have learned — if not forgotten already — on textbook thermodynamics. If you are surprised by this suggestion, take a look at specific examples from | |||
::::::» [[Advancement#Advancement_versus_amount |a fundamental textbook on physical chemistry]] | |||
::::::» [[Force#Thermodynamic_ignorance |bioenergetics]]. | |||
{{Template:Force and pressure}} | |||
== Lecturer and participants == | |||
== Lecturer == | |||
<gallery mode=default perrow=9 widths="140px" heights="150px"> | <gallery mode=default perrow=9 widths="140px" heights="150px"> | ||
File:Erich Gnaiger.jpg|'''[[Gnaiger E |Erich Gnaiger]]''', PhD., Oroboros Instruments - | File:Erich Gnaiger.jpg|'''[[Gnaiger E |Erich Gnaiger]]''', PhD., Oroboros Instruments - author of | ||
File:Gnaiger 2020 BEC MitoPathways.jpg|'''[[Gnaiger_2020_BEC_MitoPathways|Mitochondrial pathways and respiratory control. An introduction to OXPHOS analysis.]] | |||
File:Odra Noel-Mitchell's dream.png|'''[[Gnaiger_2020_BEC_MitoPathways#Chapter_8._Protonmotive_pressure_and_respiratory_control|Chapter 8. Protonmotive pressure and respiratory control.]] | |||
|- | |- | ||
</gallery> | </gallery> | ||
<big>'''Participants'''</big> | |||
::: ''preliminary'' | ::: ''preliminary'' | ||
<gallery mode=default perrow=9 widths="140px" heights="150px"> | <gallery mode=default perrow=9 widths="140px" heights="150px"> | ||
File:CardosoLHD.JPG|'''[[Cardoso | File:BaglivoE.jpg|'''[[Baglivo Eleonora|Eleonora Baglivo]]''', MSc, Oroboros Instruments, ''Biomedical Pixie'' | ||
File:Cristiane Cecatto.jpg|'''[[Cecatto C|Cristiane Cecatto]]''', PhD | File:CardosoLHD.JPG|'''[[Cardoso Luiza HD|Luiza HD Cardoso]]''', PhD, Oroboros Instruments, ''Mitochondrial Wizard'' | ||
File:Erich Gnaiger.jpg|'''[[Gnaiger E |Erich Gnaiger]]''', PhD | File:Cristiane Cecatto.jpg|'''[[Cecatto C|Cristiane Cecatto]]''', PhD, Oroboros Instruments, ''Mitochondrial Phoenix'' | ||
File:Mateus.jpg|'''[[Grings Mateus|Mateus Grings ]]''', PhD | File:Donnellyc.jpg|'''[[Donnelly Chris |Chris Donnelly]]''', Institute of Sport Sciences, University of Lausanne, CH | ||
File:SchmittS.jpg|'''[[Schmitt S|Sabine Schmitt]]''', | File:Erich Gnaiger.jpg|'''[[Gnaiger E |Erich Gnaiger]]''', PhD, Oroboros Instruments - CEO, ''Innovation Alchemist'' | ||
File:Mateus.jpg|'''[[Grings Mateus|Mateus Grings ]]''', PhD, Oroboros Instruments, ''Mitochondrial Jedi'' | |||
File:Profile-icon-9.png|'''[[Leo Elettra|Elettra Leo]]''', PhD, Oroboros Instruments | |||
File:SchmittS.jpg|'''[[Schmitt S|Sabine Schmitt]]''', PhD, Oroboros Instruments, ''Mitochondrial Detective'' | |||
File:Timon-Gomez_A.jpg|'''[[Timon-Gomez Alba|Alba Timon-Gomez]]''', PhD, Oroboros Instruments | |||
|- | |||
</gallery> | |||
<gallery mode=default perrow=2 widths="400px" heights="300px"> | |||
File:Pressure-force Maxwell.png | |||
File:Pressure-force van't Hoff.png | |||
File:Pressure-force Nernst.png | |||
File:Pressure-force Einstein.png | |||
File:Pressure-force Prigogine.png | |||
File:Pressure-force Mitchell.png | |||
|- | |- | ||
</gallery> | </gallery> | ||
== Contact = | == Registration and general information == | ||
:::* This event is taking place immediately before the [[MiPNet27.04 IOC155 Schroecken AT|O2k-Workshop - IOC155]]. | |||
:::: Download registration form: '''[https://wiki.oroboros.at/images/1/1f/Registration_BEC_and_IOC155.pdf download pdf]''' | |||
<big>'''Contact'''</big> | |||
[[Image:Logo OROBOROS INSTRUMENTS.jpg|right|120px|link=http://www.oroboros.at|Oroboros]] | |||
:::: [mailto:instruments@oroboros.at| instruments@oroboros.at] | :::: [mailto:instruments@oroboros.at| instruments@oroboros.at] | ||
Line 73: | Line 123: | ||
:::: '''Mitochondria and Cell Research''' | :::: '''Mitochondria and Cell Research''' | ||
<big>'''Hotel Koerbersee'''</big> | |||
:::: » Please note that the hotel has a limited number of rooms and space is not guaranteed. Therefore, we ask you to confirm beforehand if you intend to bring accompanying guests with you. | |||
:::: » As there is no ATM close to the hotel, we recommend withdrawing money at Bregenz train station. Please make sure to bring some cash in EUROs with you, in case you need it. | |||
::::: The hotel accepts payment by credit card. | |||
<big>'''COVID-19'''</big> | |||
:::: The event will be held in accordance with current COVID regulations. A primary concern must be the safety of our participants and staff, which is why we reserve the right to cancel the event if there are any concerns/restrictions. Refunds will be issued exclusively for registration fees. | |||
== Recommended reading == | == Recommended reading == | ||
[[File:OXPHOS-coupled energy cycles.jpg|right|330px |Hydrogen ion circuit and coupling in OXPHOS |link=Gnaiger_2020_BEC_MitoPathways#Chapter_8._Protonmotive_pressure_and_respiratory_control]] | |||
[[File:Gnaiger 2020 BEC MitoPathways.jpg|left|66px|link=Gnaiger_2020_BEC_MitoPathways|Gnaiger 2020 BEC MitoPathways]] | [[File:Gnaiger 2020 BEC MitoPathways.jpg|left|66px|link=Gnaiger_2020_BEC_MitoPathways|Gnaiger 2020 BEC MitoPathways]] | ||
:::# Mitchell P (1966) Chemiosmotic coupling in oxidative and photosynthetic phosphorylation. https://doi.org/10.1016/j.bbabio.2011.09.018 | |||
:::# Gnaiger E (2020) Mitochondrial pathways and respiratory control. An introduction to OXPHOS analysis. 5th ed. https://doi.org/10.26124/bec:2020-0002 - Chapter 8 | :::# Gnaiger E (2020) Mitochondrial pathways and respiratory control. An introduction to OXPHOS analysis. 5th ed. https://doi.org/10.26124/bec:2020-0002 - Chapter 8 | ||
:::# Gnaiger E (2021) The elementary unit — canonical reviewer's comments on: Bureau International des Poids et Mesures (2019) The International System of Units (SI) 9th ed. https://doi.org/10.26124/mitofit:200004.v2 | :::# Gnaiger E (2021) The elementary unit — canonical reviewer's comments on: Bureau International des Poids et Mesures (2019) The International System of Units (SI) 9th ed. https://doi.org/10.26124/mitofit:200004.v2 | ||
[[Image:MitoPedia-text.jpg|left|100px|link=MitoPedia|MitoPedia]] | |||
<br> | |||
<br> | |||
» [[MitoPedia: Ergodynamics]] | |||
<br> | |||
<br> | |||
[[Image:MitoGlobal.jpg|right|80px|link=MitoGlobal|MitoGlobal]] | [[Image:MitoGlobal.jpg|right|80px|link=MitoGlobal|MitoGlobal]] | ||
BEC | BEC tutorials are listed as [[MitoGlobal Events]]. | ||
{{Labeling | {{Labeling | ||
|additional=ORO, IOC, 2022, MitoGlobal, Next | |additional=ORO, IOC, 2022, MitoGlobal, NextGen-O2k, Next | ||
}} | }} | ||
[[Category:O2k-Workshops]] | [[Category:O2k-Workshops]] |
Revision as of 21:38, 29 July 2022
Schroecken AT, 2022 Sep 30-Oct 02. BEC tutorial-Living Communications: pmF — pre IOC155. |
Oroboros (2022-09-30) Mitochondr Physiol Network
Abstract: BEC tutorial-Living Communications. Mitochondrial membrane potential and Peter Mitchell’s protonmotive force: elements of the science of bioenergetics. Preceding the Oroboros O2k-Workshop on high-resolution respirometry. Schroecken, Austria; 2022.
The mitochondrial membrane potential is an element of the science of bioenergetics, linked to the control of respiratory flux and related mitochondrial functions. A PubMed search on ‘mitochondrial membrane potential’ yields nearly 40 000 results and 3442 for 2021 (search 2022-07-04), with a linear increase during the past 20 years. Chapter 8 on ‘Protonmotive pressure and respiratory control’ of Mitochondrial Pathways (Gnaiger 2020) introduces a novel perspective on Peter Mitchell’s protonmotive force, which incorporates the mitochondrial membrane potential. If you find the reading is tough, you are not alone. Join this BEC tutorial-Living Communications for a fundamental introduction into the relevant concepts of physical chemistry, which differ from misleading chapters in bioenergetics textbooks. A retreat with plenty of informal discussions and group interactions takes you on a journey to visit chemical potential differences versus potential gradients, Gibbs energy versus Gibbs force, quantities of capacity versus intensity, protonmotive force and motive units, flows and forces, and finally protonmotive pressure. This will introduce students (and teachers) to a new understanding of mitochondrial membrane potential and the protonmotive force, connecting the ideal gas equation, osmotic pressure, the Boltzmann constant and gas constant with Fick’s and Einstein’s diffusion equation. If theory gets dry and grey, join for a swim in lake Körbersee, for a Walk&Talk in the colorful alpine environment of the Schröcken-Tannberg region, and a visit to the Alpmuseum ufm Tannberg.
• O2k-Network Lab: AT_Innsbruck_Oroboros
Last update: 2022-07-17
Venue
- Hotel Körbersee, Schröcken, AT
- Information on travel and venue: IOC Schroecken.
Program
- BEC tutorial: program for 2022 Sep 30-Oct 02 (Fr to Su)
- Preceding the Oroboros O2k-Workshop on high-resolution respirometry, 2022 Oct 03-08 (Mo to Fr).
pmF: a unifying theory of biology - from metabolism to physical chemistry
- Peter Mitchell's concept of the protonmotive force pmF is one of the grand unifying theories of biology, on par with Charles Darwin's theory of evolution, Gregor Mendel's rules of inheritance and classical genetics, and the structure of DNA resolved by Francis Crick, James Watson, and Rosalind Franklin. The pmF combines the disciplines of biochemistry (metabolism), cell biology (cellular ultrastructure), physiology (energy transformation), thermodynamics (chemical potential, Gibbs energy), and physical chemistry (diffusion, electrochemistry).
- This BEC tutorial links different disciplines and describes different processes (transformations) by the same principles and relations of isomorphic quantities:
- metabolic reactions and translocation (scalar and vectorial)
- diffusion (from Fick's law to Einstein's diffusion equation)
- electrochemical potentials (compartmental differences versus gradients) and motive forces (of physics and thermodynamics - from the Boltzmann constant and gas constant to the electromotive constant)
- osmotic pressure (from the gas law to protonmotive pressure)
- Remember ZEN, zeNA — Section 8.2.8 - ∞2∞
- RM Pirsig (1974) Zen and the art of motorcycle maintenance. An inquiry into values. William Morrow & Company:418 pp.
- Thermodynamics (motorcycle maintenance) may be dull and tedious drudgery (without curiosity beyond “≡”) or a valuable and exciting art (if you seek for “=” ZEN). Transformation of dumb, dry and frigid equations into eloquent formulae radiating meaning and sparkling knowledge depends on motivation, skill and persistence (zeNA).
- » Compare numerical equivalence (symbol ≡) and physicochemical equality (symbol =).
Why?
- Why are mitochondria small? Why is LEAK respiration a non-linear (non-Ohmic) function of the mitochondrial membrane potential difference ΔΨp+?
- Why is the mitochondrial membrane potential difference ΔΨp+ — the chemical part of the pmF — not a force of physics? Similarly, the protonmotive force is not a force of physics. Why 'isomorphic' forces?
- Why can we start a chemical reaction (in a homogenous system) or compartmental diffusion (in a discontinuous system) at an infinitely large force - without the system exploding?
Consider some fundamental quantities
- Among the key isomorphic quantities are:
- advancement and stoichiometry as the determinants of transformation flows
- motive entity - this is what flows
- motive units for count, amount, and charge
- chemical and electric partial forces of the pmF
- Important distinctions:
- systems: closed, compartmental, open
- transformations: vectoral (along continuous gradients), vectorial (across discontinuous boundaries between compartments), scalar (within systems, without spatial direction)
- Gibbs energy (exergy), chemical potential, and metabolic force (Gibbs force)
- potential gradients versus potential differences
- protons p+ and hydrogen ions H+
- (chemiosmotic) pressure versus (protonmotive) force
- Bioblast links: Force and membrane potential - >>>>>>> - Click on [Expand] or [Collapse] - >>>>>>>
- Fundamental relationships
- mt-Membrane potential and protonmotive force
- O2k-Potentiometry
- » O2k-Catalogue: O2k-TPP+ ISE-Module
- » O2k-Manual: MiPNet15.03 O2k-MultiSensor-ISE
- » TPP - O2k-Procedures: Tetraphenylphosphonium
- » Specifications: MiPNet15.08 TPP electrode
- » Poster
- » Unspecific binding of TPP+
- » TPP+ inhibitory effect
- O2k-Potentiometry
- O2k-Fluorometry
- » O2k-Catalogue: O2k-FluoRespirometer
- » O2k-Manual: MiPNet22.11 O2k-FluoRespirometer manual
- » Safranin - O2k-Procedures: MiPNet20.13 Safranin mt-membranepotential / Safranin
- » TMRM - O2k-Procedures: TMRM
- O2k-Fluorometry
- O2k-Publications
Gibberish
- Forget all gibberish that you have learned — if not forgotten already — on textbook thermodynamics. If you are surprised by this suggestion, take a look at specific examples from
Force or pressure? - The linear flux-pressure law
- "For many decades the pressure-force confusion has blinded the most brilliant minds, reinforcing the expectation that Ohm’s linear flux-force law should apply to the hydrogen ion circuit and protonmotive force. .. Physicochemical principles explain the highly non-linear flux-force relation in the dependence of LEAK respiration on the pmF. The explanation is based on an extension of Fick’s law of diffusion and Einstein’s diffusion equation, representing protonmotive pressure ― isomorphic with mechanical pressure, hydrodynamic pressure, gas pressure, and osmotic pressure ― which collectively follow the generalized linear flux-pressure law."
- Gnaiger E (2020) Mitochondrial pathways and respiratory control. An introduction to OXPHOS analysis. 5th ed. Bioenerg Commun 2020.2. https://doi.org/10.26124/bec:2020-0002
- » pressure = force × free activity
Lecturer and participants
Erich Gnaiger, PhD., Oroboros Instruments - author of
Participants
- preliminary
Eleonora Baglivo, MSc, Oroboros Instruments, Biomedical Pixie
Luiza HD Cardoso, PhD, Oroboros Instruments, Mitochondrial Wizard
Cristiane Cecatto, PhD, Oroboros Instruments, Mitochondrial Phoenix
Chris Donnelly, Institute of Sport Sciences, University of Lausanne, CH
Erich Gnaiger, PhD, Oroboros Instruments - CEO, Innovation Alchemist
Mateus Grings , PhD, Oroboros Instruments, Mitochondrial Jedi
Elettra Leo, PhD, Oroboros Instruments
Sabine Schmitt, PhD, Oroboros Instruments, Mitochondrial Detective
Alba Timon-Gomez, PhD, Oroboros Instruments
Registration and general information
- This event is taking place immediately before the O2k-Workshop - IOC155.
- Download registration form: download pdf
Contact
- Oroboros Instruments
- High-Resolution Respirometry
- Schoepfstrasse 18
- A-6020 Innsbruck, Austria
- Tel: +43 512 566796
- Fax: +43 512 566796 20
- Mitochondria and Cell Research
Hotel Koerbersee
- » Please note that the hotel has a limited number of rooms and space is not guaranteed. Therefore, we ask you to confirm beforehand if you intend to bring accompanying guests with you.
- » As there is no ATM close to the hotel, we recommend withdrawing money at Bregenz train station. Please make sure to bring some cash in EUROs with you, in case you need it.
- The hotel accepts payment by credit card.
- » As there is no ATM close to the hotel, we recommend withdrawing money at Bregenz train station. Please make sure to bring some cash in EUROs with you, in case you need it.
COVID-19
- The event will be held in accordance with current COVID regulations. A primary concern must be the safety of our participants and staff, which is why we reserve the right to cancel the event if there are any concerns/restrictions. Refunds will be issued exclusively for registration fees.
Recommended reading
- Mitchell P (1966) Chemiosmotic coupling in oxidative and photosynthetic phosphorylation. https://doi.org/10.1016/j.bbabio.2011.09.018
- Gnaiger E (2020) Mitochondrial pathways and respiratory control. An introduction to OXPHOS analysis. 5th ed. https://doi.org/10.26124/bec:2020-0002 - Chapter 8
- Gnaiger E (2021) The elementary unit — canonical reviewer's comments on: Bureau International des Poids et Mesures (2019) The International System of Units (SI) 9th ed. https://doi.org/10.26124/mitofit:200004.v2
BEC tutorials are listed as MitoGlobal Events.
Labels:
ORO, IOC, 2022, MitoGlobal, NextGen-O2k, Next