Effects of membrane transport activity and cell metabolism on the unbound drug concentrations in the skeletal muscle and liver of drugs: A microdialysis study in rats

Shuyao Wang; Chun Chen; Chi Guan; Liping Qiu; Lei Zhang; Shaofeng Zhang; Hongyu Zhou; Hongwen Du; Chen Li; Yaqiong Wu; Hang Chang; Tao Wang

doi:10.1002/prp2.879

Effects of membrane transport activity and cell metabolism on the unbound drug concentrations in the skeletal muscle and liver of drugs: A microdialysis study in rats

Pharmacol Res Perspect. 2021 Oct;9(5):e00879. doi: 10.1002/prp2.879.

Authors

Shuyao Wang¹, Chun Chen¹, Chi Guan¹, Liping Qiu¹, Lei Zhang¹, Shaofeng Zhang¹, Hongyu Zhou¹, Hongwen Du¹, Chen Li¹, Yaqiong Wu¹, Hang Chang¹, Tao Wang¹

Affiliation

¹ DMPK Department, Pharmaron Inc., Beijing, China.

Abstract

The unbound concentrations of 14 commercial drugs, including five non-efflux/uptake transporter substrates-Class I, five efflux transporter substrates-class II and four influx transporter substrates-Class III, were simultaneously measured in rat liver, muscle, and blood via microanalysis. K_puu,liver and K_puu,muscle were calculated to evaluate the membrane transport activity and cell metabolism on the unbound drug concentrations in the skeletal muscle and liver. For Class I compounds, represented by antipyrine, unbound concentrations among liver, muscle and blood are symmetrically distributed when compound hepatic clearance is low. And when compound hepatic clearance is high, unbound concentrations among liver, muscle and blood are asymmetrically distributed, such as Propranolol. For Class II and III compounds, overall, the unbound concentrations among liver, muscle, and blood are asymmetrically distributed due to a combination of hepatic metabolism and efflux and/or influx transporter activity.

Keywords: asymmetrically distributed; cell metabolism; membrane transport; microanalysis; unbound drug concentration.

© 2021 Pharmaron Beijing Co Ltd. Pharmacology Research & Perspectives published by British Pharmacological Society and American Society for Pharmacology and Experimental Therapeutics and John Wiley & Sons Ltd.

MeSH terms

Animals
Antipyrine / blood
Antipyrine / metabolism
Atenolol / blood
Atenolol / metabolism
Carbamazepine / blood
Carbamazepine / metabolism
Cell Membrane / metabolism*
Digoxin / blood
Digoxin / metabolism
Diltiazem / blood
Diltiazem / metabolism
Diphenhydramine / blood
Diphenhydramine / metabolism
Drug Elimination Routes
Gabapentin / blood
Gabapentin / metabolism
Lamotrigine / blood
Lamotrigine / metabolism
Liver / metabolism*
Memantine / blood
Memantine / metabolism
Membrane Transport Proteins / metabolism*
Microdialysis
Muscle, Skeletal / metabolism*
Ofloxacin / blood
Ofloxacin / metabolism
Pharmaceutical Preparations / blood
Pharmaceutical Preparations / metabolism*
Propranolol / blood
Propranolol / metabolism
Pyrilamine / blood
Pyrilamine / metabolism
Quinidine / blood
Quinidine / metabolism
Rats
Terfenadine / analogs & derivatives
Terfenadine / blood
Terfenadine / metabolism

Substances

Membrane Transport Proteins
Pharmaceutical Preparations
Carbamazepine
Atenolol
Gabapentin
Digoxin
Terfenadine
Diphenhydramine
Propranolol
Ofloxacin
fexofenadine
Diltiazem
Pyrilamine
Quinidine
Antipyrine
Lamotrigine
Memantine