Determination and correlation of in vitro viability for hairless mouse and human neonatal whole skin and stratum corneum/epidermis

Determination and correlation of in vitro viability for hairless mouse and human neonatal whole skin and stratum corneum/epidermis

Viable tissue is essential to assess the rate and extent of biotransformation during percutaneous absorption in vitro. We assessed the viability of hairless mouse whole skin (WS) and stratum corneum/epidermis (SCE) and human neonatal SCE following separation from the dermis by EDTA phosphate-buffere...

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Bibliographic Details
Published in:Archives of Dermatological Research Vol. 289; no. 3; pp. 170 - 173
Main Authors: BHATT, R. H, MICALI, G, GALINKIN, J, PALICHARLA, P, KOCH, R. L, WEST, D. P, SOLOMON, L. M
Format: Journal Article
Language:English
Published: Berlin Springer 01-02-1997
Subjects:
Animals
Animals, Newborn - physiology
Biological and medical sciences
Buffers
Edetic Acid - pharmacology
Epidermis - drug effects
Epidermis - metabolism
Epidermis - physiology
Fundamental and applied biological sciences. Psychology
Hot Temperature
Humans
Infant, Newborn - physiology
Lactic Acid - biosynthesis
Mice
Phosphates - pharmacology
Skin - drug effects
Skin - metabolism
Skin Physiological Phenomena
Sodium Chloride - pharmacology
Tissue Survival
Vertebrates: skin, associated glands, phaneres, light organs, various exocrine glands (salt gland, uropygial gland...), adipose tissue, connective tissue
Human
Vertebrata
Mammalia
Stratum corneum
Mouse
Animal
Rodentia
Epidermis
Skin
In vitro
Viability
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Summary:Viable tissue is essential to assess the rate and extent of biotransformation during percutaneous absorption in vitro. We assessed the viability of hairless mouse whole skin (WS) and stratum corneum/epidermis (SCE) and human neonatal SCE following separation from the dermis by EDTA phosphate-buffered saline (EDTA-PBS) incubation or by heat treatment by measuring the conversion of dextrose to lactate. Lactate concentrations in receptor fluid samples were determined using a Sigma diagnostic lactate determination kit. A standard curve was prepared and samples assayed spectrophotometrically at 340 nm using a lambda 2 beta spectrophotometer. Standard curves were prepared for each experiment and correlation coefficient values (r) were calculated. Our results showed that hairless mouse SCE was associated with glucose conversion to lactic acid at an increased rate if incubated in EDTA-PBS for 4 h and used immediately. Lactate production was greater with the dermis present (EDTA-PBS WS). The rate of glucose to lactate conversion in hairless mouse SCE was 20-25% of that found in WS. Compared with Dulbecco's modified PBS (DMPBS)-treated WS controls, the rate of lactate production in EDTA-PBS-treated WS was nearly a 50% less. Heat treatment in water at 60 degrees C to separate SCE from hairless mouse WS appeared to eliminate viability. Viability of hairless mouse SCE, as measured by glucose conversion to lactate, was comparable to human neonatal SCE. These results suggest that the dermis is a significant contributor to glucose metabolism and that incubation in EDTA-PBS is a contributing factor to the overall decrease in metabolic capacity of the tissue. As a result of these findings, hairless mouse SCE appears to be useful as a model for human neonatal SCE in percutaneous absorption studies.
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ISSN:0340-3696
1432-069X
DOI:10.1007/s004030050174