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Difference between revisions of "Eggelbusch 2022 Abstract Bioblast"

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{{Abstract
{{Abstract
|title=Eggelbusch M, Hendrickse P, Schoonen R, Giakoumaki I, Kerkhoff TJ, Grootemaat AE, Rittweger J, Ganse B, Weeghel van M, Mulder ER, Degens H, Wüst RCI (2022) Nutrient overload and insulin resistance precede reductions in mitochondrial respiration in skeletal muscle after bed rest
|title=Eggelbusch M, Hendrickse P, Schoonen R, Giakoumaki I, Kerkhoff TJ, Grootemaat AE, Rittweger J, Ganse B, Weeghel van M, Mulder ER, Degens H, Wüst RCI (2022) Nutrient overload and insulin resistance precede reductions in mitochondrial respiration in skeletal muscle after bed rest. Bioblast 2022: BEC Inaugural Conference.
|info=
|info=[https://wiki.oroboros.at/index.php/Bioblast_2022#Submitted_abstracts Bioblast 2022: BEC Inaugural Conference]
|authors=Eggelbusch M, Hendrickse P, Schoonen R, Giakoumaki I, Kerkhoff TJ, Grootemaat AE, Rittweger J, Ganse B, Weeghel van M, Mulder ER, Degens H, Wuest Rob CI
|authors=Eggelbusch M, Hendrickse P, Schoonen R, Giakoumaki I, Kerkhoff TJ, Grootemaat AE, Rittweger J, Ganse B, Weeghel van M, Mulder ER, Degens H, Wuest Rob CI
|year=2022
|year=2022
|event=[[Bioblast 2022]]
|abstract=Physical inactivity contributes to insulin resistance and the development of type 2 diabetes [1].Metabolic flexibility, the ability to efficiently adapt substrate oxidation depending on demand and supply, decreases in response to bed rest [1,2]. A mismatch between nutrient uptake and utilization rates likely underlies these metabolic alterations [3], but it is unknown if glycogen and lipid accumulation, or mitochondrial dysfunction occur before insulin resistance develops. Here, we determined nutrient load, insulin sensitivity, metabolite concentrations and mitochondrial function in skeletal muscle in humans undergoing short- and long-term bed rest, and assess the order of occurrence of events.


|event=[[Bioblast 2022]]
24 healthy individuals (23-54 years, 8 women) participated in the 60-days artificial gravity bed rest study by ESA (AGBRESA). Oroboros respirometry, metabolomics and lipidomics (on a subset) were performed on vastus lateralis muscle biopsies before, after 6 (short-), and 55 (long-term) days of bed rest. Glycogen and intramyocellular lipid deposits were assessed in electron microscopy images, and fasted blood glucose and insulin levels determined for the calculation of the HOMA-IR score.
|abstract=


Physical inactivity contributes to insulin resistance and the development of type 2 diabetes [1].Metabolic flexibility, the ability to efficiently adapt substrate oxidation depending on demand and supply, decreases in response to bed rest [1,2]. A mismatch between nutrient uptake and utilization rates likely underlies these metabolic alterations [3], but it is unknown if glycogen and lipid accumulation, or mitochondrial dysfunction occur before insulin resistance develops. Here, we determined nutrient load, insulin sensitivity, metabolite concentrations and mitochondrial function in skeletal muscle in humans undergoing short- and long-term bed rest, and assess the order of occurrence of events.<br>
Blood glucose remained constant throughout bed rest, but HOMA-IR scores were higher after short- and did not further change after long-term bed rest. Short-term bed rest did not cause significant changes in mitochondrial respiration, whilst long-term bed rest significantly reduced NADH- and oxidative phosphorylation capacity. Glycogen content and lipid droplets significantly increased after 6 days but only lipid droplets further accumulated after day 55. Metabolomics and lipidomics revealed reduced fatty acid oxidation and increased glucose metabolism after short-term bed rest, which manifested throughout the bed rest duration, suggestive of continuous alterations in skeletal muscle metabolism.
24 healthy individuals (23-54 years, 8 women) participated in the 60-days artificial gravity bed rest study by ESA (AGBRESA). Oroboros respirometry, metabolomics and lipidomics (on a subset) were performed on vastus lateralis muscle biopsies before, after 6 (short-), and 55 (long-term) days of bed rest. Glycogen and intramyocellular lipid deposits were assessed in electron microscopy images, and fasted blood glucose and insulin levels determined for the calculation of the HOMA-IR score.<br>
Blood glucose remained constant throughout bed rest, but HOMA-IR scores were higher after short- and did not further change after long-term bed rest. Short-term bed rest did not cause significant changes in mitochondrial respiration, whilst long-term bed rest significantly reduced NADH- and oxidative phosphorylation capacity. Glycogen content and lipid droplets significantly increased after 6 days but only lipid droplets further accumulated after day 55. Metabolomics and lipidomics revealed reduced fatty acid oxidation and increased glucose metabolism after short-term bed rest, which manifested throughout the bed rest duration, suggestive of continuous alterations in skeletal muscle metabolism.<br>


Short-term bed rest caused nutrient overload, a shift from fatty acid metabolism to glycolysis, and insulin insensitivity before a reduction in oxidative phosphorylation capacity was observed after long-term bed rest.
Short-term bed rest caused nutrient overload, a shift from fatty acid metabolism to glycolysis, and insulin insensitivity before a reduction in oxidative phosphorylation capacity was observed after long-term bed rest.
====References====
[1] Rudwill F, et al (2018) Metabolic inflexibility is an early marker of bed-rest–induced glucose intolerance even when fat mass is stable. J Clin Endocrinol Metab 103(5):1910-1920. doi.org/10.1210/jc.2017-02267.<br>
[2] Smith RL, Soeters MR, Wüst RCI, & Houtkooper RH (2018) Metabolic flexibility as an adaptation to energy resources and requirements in health and disease. Endocrine reviews 39(4):489-517. doi.org/10.1210/er.2017-00211.<br>
[3] Picard M, et al. (2012). Mitochondrial dysfunction and lipid accumulation in the human diaphragm during mechanical ventilation. Am J Respir Crit Care Med 186(11):1140-1149. doi.org/10.1164/rccm.201206-0982OC.
|keywords=bed rest, skeletal muscle, nutrient overload, insulin resistance, mitochondrial respiration
|keywords=bed rest, skeletal muscle, nutrient overload, insulin resistance, mitochondrial respiration
|mipnetlab=NL Amsterdam Wuest RC
|mipnetlab=NL Amsterdam Wuest RC
|journal=
|articletype=Abstract
}}
{{Labeling
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|articletype=Abstract
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__NOTOC__
== Affiliations ==
== Affiliations and author contributions ==
::::Eggelbusch M(1,2,3), Hendrickse P<sup>4</sup>, Schoonen R<sup>1</sup>, Giakoumaki I<sup>4</sup>, Kerkhoff TJ<sup>1</sup>, Grootemaat AE<sup>5</sup>, Rittweger J<sup>6</sup>, Ganse B<sup>4</sup>, Weeghel van M<sup>7</sup>, Mulder ER<sup>6</sup>, Degens H<sup>4</sup> and Wüst RCI<sup>1</sup>
Eggelbusch M<sup>1,2,3</sup>, Hendrickse P<sup>4</sup>, Schoonen R<sup>1</sup>, Giakoumaki I<sup>4</sup>, Kerkhoff TJ<sup>1</sup>, Grootemaat AE<sup>5</sup>, Rittweger J<sup>6</sup>, Ganse B<sup>4</sup>, Weeghel van M<sup>7</sup>, Mulder ER<sup>6</sup>, Degens H<sup>4</sup> and Wüst RCI<sup>1</sup><br>
::::#Lab for Myology, Dept of Human MVMT Sci, Fac of Behav and MVMT Sci, Vrije Univ Amsterdam, Amsterdam MVMT Sci
 
::::#Dept of Nutrition and Dietetics, Amsterdam UMC, Loc VUmc, Amsterdam MVMT Sciences
1 Lab for Myology, Dept of Human MVMT Sci, Fac of Behav and MVMT Sci, Vrije Univ Amsterdam, Amsterdam MVMT Sci<br>
::::#Fac of Sports and Nutrition, Ctr of Expertise Urban Vitality, Amsterdam Univ of Appl Sci
 
::::#Manchester Metropolitan Univ, Res Ctr for MSK Sci & Sports Med, Fac of Sci and Engrg
2 Dept of Nutrition and Dietetics, Amsterdam UMC, Loc VUmc, Amsterdam MVMT Sciences<br>
::::#Electron Microsc Ctr Amsterdam, Dept of Med Biol, Acad Med Ctr
 
::::#Inst of Aerospace Med, German Aerospace Ctr (DLR)
3 Fac of Sports and Nutrition, Ctr of Expertise Urban Vitality, Amsterdam Univ of Appl Sci<br>
::::#Amsterdam UMC, Univ of Amsterdam, Lab Genetic Metab Diseases, Amsterdam Cardiovasc Sci. -m.eggelbusch@amsterdamumc.nl
 
4 Manchester Metropolitan Univ, Res Ctr for MSK Sci & Sports Med, Fac of Sci and Engrg<br>
 
5 Electron Microsc Ctr Amsterdam, Dept of Med Biol, Acad Med Ctr<br>
 
6 Inst of Aerospace Med, German Aerospace Ctr (DLR)<br>
 
7 Amsterdam UMC, Univ of Amsterdam, Lab Genetic Metab Diseases, Amsterdam Cardiovasc Sci.<br>
 
m.eggelbusch@amsterdamumc.nl


== References ==
::::#Rudwill F, et al (2018) Metabolic inflexibility is an early marker of bed-rest–induced glucose intolerance even when fat mass is stable. J Clin Endocrinol Metab 103(5):1910-1920. doi.org/10.1210/jc.2017-02267.<br>
::::#Smith RL, Soeters MR, Wüst RCI, & Houtkooper RH (2018) Metabolic flexibility as an adaptation to energy resources and requirements in health and disease. Endocrine reviews 39(4):489-517. doi.org/10.1210/er.2017-00211.<br>
::::#Picard M, et al. (2012). Mitochondrial dysfunction and lipid accumulation in the human diaphragm during mechanical ventilation. Am J Respir Crit Care Med 186(11):1140-1149. doi.org/10.1164/rccm.201206-0982OC.


== Help ==
== Help ==
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Revision as of 14:41, 21 April 2022

Eggelbusch M, Hendrickse P, Schoonen R, Giakoumaki I, Kerkhoff TJ, Grootemaat AE, Rittweger J, Ganse B, Weeghel van M, Mulder ER, Degens H, Wüst RCI (2022) Nutrient overload and insulin resistance precede reductions in mitochondrial respiration in skeletal muscle after bed rest. Bioblast 2022: BEC Inaugural Conference.

Link: Bioblast 2022: BEC Inaugural Conference

Eggelbusch M, Hendrickse P, Schoonen R, Giakoumaki I, Kerkhoff TJ, Grootemaat AE, Rittweger J, Ganse B, Weeghel van M, Mulder ER, Degens H, Wuest Rob CI (2022)

Event: Bioblast 2022

Physical inactivity contributes to insulin resistance and the development of type 2 diabetes [1].Metabolic flexibility, the ability to efficiently adapt substrate oxidation depending on demand and supply, decreases in response to bed rest [1,2]. A mismatch between nutrient uptake and utilization rates likely underlies these metabolic alterations [3], but it is unknown if glycogen and lipid accumulation, or mitochondrial dysfunction occur before insulin resistance develops. Here, we determined nutrient load, insulin sensitivity, metabolite concentrations and mitochondrial function in skeletal muscle in humans undergoing short- and long-term bed rest, and assess the order of occurrence of events.

24 healthy individuals (23-54 years, 8 women) participated in the 60-days artificial gravity bed rest study by ESA (AGBRESA). Oroboros respirometry, metabolomics and lipidomics (on a subset) were performed on vastus lateralis muscle biopsies before, after 6 (short-), and 55 (long-term) days of bed rest. Glycogen and intramyocellular lipid deposits were assessed in electron microscopy images, and fasted blood glucose and insulin levels determined for the calculation of the HOMA-IR score.

Blood glucose remained constant throughout bed rest, but HOMA-IR scores were higher after short- and did not further change after long-term bed rest. Short-term bed rest did not cause significant changes in mitochondrial respiration, whilst long-term bed rest significantly reduced NADH- and oxidative phosphorylation capacity. Glycogen content and lipid droplets significantly increased after 6 days but only lipid droplets further accumulated after day 55. Metabolomics and lipidomics revealed reduced fatty acid oxidation and increased glucose metabolism after short-term bed rest, which manifested throughout the bed rest duration, suggestive of continuous alterations in skeletal muscle metabolism.

Short-term bed rest caused nutrient overload, a shift from fatty acid metabolism to glycolysis, and insulin insensitivity before a reduction in oxidative phosphorylation capacity was observed after long-term bed rest.

Keywords: bed rest, skeletal muscle, nutrient overload, insulin resistance, mitochondrial respiration

O2k-Network Lab: NL Amsterdam Wuest RC


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Affiliations

Eggelbusch M(1,2,3), Hendrickse P4, Schoonen R1, Giakoumaki I4, Kerkhoff TJ1, Grootemaat AE5, Rittweger J6, Ganse B4, Weeghel van M7, Mulder ER6, Degens H4 and Wüst RCI1
  1. Lab for Myology, Dept of Human MVMT Sci, Fac of Behav and MVMT Sci, Vrije Univ Amsterdam, Amsterdam MVMT Sci
  2. Dept of Nutrition and Dietetics, Amsterdam UMC, Loc VUmc, Amsterdam MVMT Sciences
  3. Fac of Sports and Nutrition, Ctr of Expertise Urban Vitality, Amsterdam Univ of Appl Sci
  4. Manchester Metropolitan Univ, Res Ctr for MSK Sci & Sports Med, Fac of Sci and Engrg
  5. Electron Microsc Ctr Amsterdam, Dept of Med Biol, Acad Med Ctr
  6. Inst of Aerospace Med, German Aerospace Ctr (DLR)
  7. Amsterdam UMC, Univ of Amsterdam, Lab Genetic Metab Diseases, Amsterdam Cardiovasc Sci. -m.eggelbusch@amsterdamumc.nl

References

  1. Rudwill F, et al (2018) Metabolic inflexibility is an early marker of bed-rest–induced glucose intolerance even when fat mass is stable. J Clin Endocrinol Metab 103(5):1910-1920. doi.org/10.1210/jc.2017-02267.
  2. Smith RL, Soeters MR, Wüst RCI, & Houtkooper RH (2018) Metabolic flexibility as an adaptation to energy resources and requirements in health and disease. Endocrine reviews 39(4):489-517. doi.org/10.1210/er.2017-00211.
  3. Picard M, et al. (2012). Mitochondrial dysfunction and lipid accumulation in the human diaphragm during mechanical ventilation. Am J Respir Crit Care Med 186(11):1140-1149. doi.org/10.1164/rccm.201206-0982OC.

Help