Quantification of body fluid compartmentalization by combined time-domain nuclear magnetic resonance and bioimpedance spectroscopy.
Jeffrey L SegarKirthikaa BalapattabiJohn J RehoConnie C GrobeColin M L BurnettJustin L GrobePublished in: American journal of physiology. Regulatory, integrative and comparative physiology (2020)
The measurement of fluid compartmentalization, or the distribution of fluid volume between extracellular (ECF) and intracellular (ICF) spaces, historically requires complicated, burdensome, and often terminal methodologies that do not permit repeated or longitudinal experiments. New technologies including time-domain nuclear magnetic resonance (TD-NMR)-based methods allow for highly accurate measurements of total body water (TBW) within minutes in a noninvasive manner, but do not permit dissection of ECF versus ICF reservoirs. In contrast, methods such as bioimpedance spectroscopy (BIS) allow dissection of ECF versus ICF reservoirs but are hampered by dependence on many nuanced details in data collection that undermine confidence in experimental results. Here, we present a novel combinatorial use of these two technologies (NMR/BIS) to improve the accuracy of BIS-based assessments of ECF and ICF, while maintaining the advantages of these minimally invasive methods. Briefly, mice undergo TD-NMR and BIS-based measures, and then fat masses as derived by TD-NMR are used to correct BIS outputs. Mice of the C57BL/6J background were studied using NMR/BIS methods to assess the effects of acute furosemide injection and diet-induced obesity on fluid compartmentalization, and to examine the influence of sex, body mass and composition, and diet on TBW, ECF, and ICF. We discovered that in mice, sex and body size/composition have substantial and interactive effects on fluid compartmentalization. We propose that the combinatorial use of NMR/BIS methods will enable a revisioning of the types of longitudinal, kinetic studies that can be performed to understand the impact of various interventions on body fluid homeostasis.
Keyphrases
- magnetic resonance
- solid state
- high resolution
- ionic liquid
- high fat diet induced
- contrast enhanced
- minimally invasive
- metabolic syndrome
- body composition
- physical activity
- insulin resistance
- adipose tissue
- weight loss
- type diabetes
- liver failure
- single molecule
- hepatitis b virus
- respiratory failure
- artificial intelligence
- contrast enhanced ultrasound
- deep learning
- acute respiratory distress syndrome