Thermodynamic assessment of allocation of energy and exergy of the nutrients for the life processes during pregnancy

Br J Nutr. 2020 Oct 14;124(7):742-753. doi: 10.1017/S0007114520001646. Epub 2020 May 8.

Abstract

Thermodynamic analyses are performed to quantify allocation of the nutritional energy and exergy to most of the life processes by pregnant mice. In these analyses, 'internal work performance' is calculated for the first time in the literature for metabolism during pregnancy and found substantially higher than the 'external work performance'. Variation of the daily entropy generation rates and the daily internal work performance rates during the course of pregnancy showed a highly similar phasic behaviour. With the progression of the pregnancy, external work performance decreased and second law efficiency increased significantly. On the 13th day of pregnancy, net energy extracted from the food at the cellular energy metabolism subsystem was 15·0 kJ; approximately 3 kJ of it was employed for daily internal work performance, 0·8 kJ was allocated to daily external work performance and 0·8 kJ was stored in the adipose tissue without entering into the cellular energy metabolism subsystem. Heat generation in association with internal and external work performance was 9·1 and 2·2 kJ, respectively. Energy, pertinent to the first law, and exergy (useful energy), pertinent to the second law, balances are described graphically, and comparison of these plots showed that the total exergy of the nutrients allocated to internal and external work performance and heat generation is substantially smaller in magnitude when compared with those of energy balance.

Keywords: Allocation of nutrient energy; Life processes; Pregnant mice; Thermodynamic analyses.

MeSH terms

  • Animal Nutritional Physiological Phenomena / physiology
  • Animals
  • Eating / physiology*
  • Energy Metabolism / physiology*
  • Female
  • Maternal Nutritional Physiological Phenomena / physiology*
  • Mice
  • Nutrients / metabolism*
  • Pregnancy
  • Thermodynamics*