Intestinal Water Absorption Varies with Expected Dietary Water Load among Bats but Does Not Drive Paracellular Nutrient Absorption

Price, Edwin R.; Brun, Antonio; Gontero-Fourcade, Manuel N.; Fernández-Marinone, Guido; Cruz‐Neto, Ariovaldo P.; Karasov, William H.; Caviedes‐Vidal, Enrique

doi:10.1086/683114

Cited by 5 publications

(4 citation statements)

References 26 publications

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“…Our whole-animal measurements on L. yerbabuenae are consistent with those made by intestinal perfusion in situ in nectarivorous G. soricina (Price et al, 2015b), and the data on both species and methodologies underscore the importance of paracellular absorption in supporting the sugar oxidation cascade in nectarivorous bats. In the perfusion study, paracellular sugar absorption rates were high and could account for an estimated 93% (±10%, N=2; E.R.P., personal observation) of total 3OMD-glucose absorption at a luminal concentration of 10 mmol l −1 , and this percentage would be higher at higher, more transportersaturating luminal concentrations.…”

Section: Resultssupporting

confidence: 80%

“…Moreover, the measured permeability of the in situ perfused intestine was high enough to account for the rate of glucose oxidation during hovering flight, which was about 2.2 µmol min −1 g −1 body mass (see Introduction). The passive clearance of the paracellular probe during in situ perfusion corresponded to a D-glucose clearance of 12.9 µl min −1 cm −2 (Price et al, 2015b), or 6.45 µl min −1 g −1 body mass, assuming 0.5 cm 2 g −1 body mass for a bat of its size (Price et al, 2015a). Thus, the necessary luminal glucose concentration for passive absorption rate to equal the rate at which dietary glucose was apparently absorbed and oxidized would be 0.34 µmol µl −1 (=2.2 µmol min −1 g −1 /6.45 µl min −1 g −1 ), or 340 mmol l −1 glucose.…”

Section: Resultsmentioning

confidence: 99%

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Intestinal paracellular absorption is necessary to support the sugar oxidation cascade in nectarivorous bats

Rodríguez-Peña

Price

Caviedes‐Vidal

et al. 2016

Journal of Experimental Biology

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We made the first measurements of the capacity for paracellular nutrient absorption in intact nectarivorous bats. Leptonycteris yerbabuenae (20 g mass) were injected with or fed inert carbohydrate probes L-rhamnose and D(+)-cellobiose, which are absorbed exclusively by the paracellular route, and 3-O-methyl-Dglucose (3OMD-glucose), which is absorbed both paracellularly and transcellularly. Using a standard pharmacokinetic technique, we collected blood samples for 2 h after probe administration. As predicted, fractional absorption ( f ) of paracellular probes declined with increasing M r in the order of rhamnose ( f=0.71)>cellobiose ( f=0.23). Absorption of 3OMD-glucose was complete ( f=0.85; not different from unity). Integrating our data with those for glucose absorption and oxidation in another nectarivorous bat, we conclude that passive paracellular absorption of glucose is extensive in nectarivorous bat species, as in other bats and small birds, and necessary to support high glucose fluxes hypothesized for the sugar oxidation cascade.

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Section: Resultssupporting

confidence: 80%

Section: Resultsmentioning

confidence: 99%

Intestinal paracellular absorption is necessary to support the sugar oxidation cascade in nectarivorous bats

Rodríguez-Peña

Price

Caviedes‐Vidal

et al. 2016

Journal of Experimental Biology

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“…These paracellular pores can also have different charge-selectivity, based on the claudin proteins (a large family of proteins that modulate paracellular permeability [59,60]. More research is required on the mechanisms that underlie differences in paracellular absorption for drugs of different sizes (g/mol), both within and between species (Figure 4A,B) [58,61]. Although we have some information on the roles of individual claudins, some of which are thought to form charge- and size-selective tight-junction pores for smaller molecules, relatively little is known about their interactions [62].…”

Section: Intestinal Membrane Transportmentioning

confidence: 99%

Intestinal Permeability and Drug Absorption: Predictive Experimental, Computational and In Vivo Approaches

2019

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The main objective of this review is to discuss recent advancements in the overall investigation and in vivo prediction of drug absorption. The intestinal permeability of an orally administered drug (given the value Peff) has been widely used to determine the rate and extent of the drug’s intestinal absorption (Fabs) in humans. Preclinical gastrointestinal (GI) absorption models are currently in demand for the pharmaceutical development of novel dosage forms and new drug products. However, there is a strong need to improve our understanding of the interplay between pharmaceutical, biopharmaceutical, biochemical, and physiological factors when predicting Fabs and bioavailability. Currently, our knowledge of GI secretion, GI motility, and regional intestinal permeability, in both healthy subjects and patients with GI diseases, is limited by the relative inaccessibility of some intestinal segments of the human GI tract. In particular, our understanding of the complex and highly dynamic physiology of the region from the mid-jejunum to the sigmoid colon could be significantly improved. One approach to the assessment of intestinal permeability is to use animal models that allow these intestinal regions to be investigated in detail and then to compare the results with those from simple human permeability models such as cell cultures. Investigation of intestinal drug permeation processes is a crucial biopharmaceutical step in the development of oral pharmaceutical products. The determination of the intestinal Peff for a specific drug is dependent on the technique, model, and conditions applied, and is influenced by multiple interactions between the drug molecule and the biological membranes.

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“…The stomach forms a U shape blind-ending tube extremely long and thin ( Rouk and Glass, 1970 ). Furthermore, the main functions of this organ are storage of large volume of blood and high water absorption ( Mitchell and Tigner, 1970 ; Price et al, 2015 ).…”

Section: Bacteriamentioning

confidence: 99%

An overview of bats microbiota and its implication in transmissible diseases

Federici

Masulli²,

Laurenzi³

et al. 2022

Front. Microbiol.

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Recent pandemic events have raised the attention of the public on the interactions between human and environment, with particular regard to the more and more feasible transmission to humans of micro-organisms hosted by wild-type species, due to the increasing interspecies contacts originating from human’s activities. Bats, due to their being flying mammals and their increasing promiscuity with humans, have been recognized as hosts frequently capable of transmitting disease-causing microorganisms. Therefore, it is of considerable interest and importance to have a picture as clear as possible of the microorganisms that are hosted by bats. Here we focus on our current knowledge on bats microbiota. We review the most recent literature on this subject, also in view of the bat’s body compartments, their dietary preferences and their habitat. Several pathogenic bacteria, including many carrying multidrug resistance, are indeed common guests of these small mammals, underlining the importance of preserving their habitat, not only to protect them from anthropogenic activities, but also to minimize the spreading of infectious diseases.

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Intestinal Water Absorption Varies with Expected Dietary Water Load among Bats but Does Not Drive Paracellular Nutrient Absorption

Cited by 5 publications

References 26 publications

Intestinal paracellular absorption is necessary to support the sugar oxidation cascade in nectarivorous bats

Intestinal paracellular absorption is necessary to support the sugar oxidation cascade in nectarivorous bats

Intestinal Permeability and Drug Absorption: Predictive Experimental, Computational and In Vivo Approaches

An overview of bats microbiota and its implication in transmissible diseases

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