Skin Diseases in Laboratory Mice: Approaches to Drug Target Identification and Efficacy Screening

Sundberg, John P.; Silva, Kathleen A.; McPhee, Caroline G.; King, Lloyd E.

doi:10.1007/978-1-4939-3661-8_12

Cited by 4 publications

(2 citation statements)

References 96 publications

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“…The truncal pigmentation of rodents is entirely dependent on their follicular melanocytes. Pigment production is active only during the follicle growth (anagen) phase (Park et al 2007;Sundberg et al 2010;Sundberg and Silva 2012). In pigmented mice, rapid hair regrowth after clipping is grossly evident as dark gray/black discoloration of the skin ( Figure 5) due to hair follicles entering the anagen phase.…”

Section: Normal Anatomical Variationmentioning

confidence: 97%

Dermal Toxicity Studies

et al. 2014

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The field of dermal toxicity continues to evolve in order to accurately predict dermal (and systemic) responses in humans to topically applied chemicals. Although the testing methods have undergone extensive refinements, idiosyncrasies and unexpected issues during the conduct of these studies are not unusual due to the plethora of new vehicles available for formulating test substances, changing regulatory requirements, and introducting new strain and/or species of laboratory animals as no single species or method seems to suffice for evaluating skin toxicity. The objective of this article is to illustrate some pragmatic issues that should be considered during the conduct as well as interpretation of dermal toxicity studies. Routine procedure-related issues such as hair clipping, tape stripping, and wrapping the animal's torso to prevent oral ingestion can influence the interpretation. Excipients used in dermal toxicity studies may be nontoxic when used alone but complex dermal formulations can result in unexpected irritation and toxicity. In conclusion, interpretation and risk assessment of dermal toxicity studies should be done in a comprehensive manner, taking into account procedure-related impact on study results, unique species susceptibility, limitation of gross visual (naked eye) observation for evidence of toxicity, and normal anatomical variation.

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Section: Normal Anatomical Variationmentioning

confidence: 97%

Dermal Toxicity Studies

et al. 2014

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“…Current studies including our previous report involve the use of rodents due to its simplicity and mammalian structure. However, unlike human wounds that heal via re‐epithelialization and granulation tissue formation, skin in mice uniquely possess a panniculus carnosus layer which enables the skin to slide and retract over subcutaneous fascia for prompt contraction of the upper strata epidermis . This rapid initiation of primary closure can exaggerate the rate of re‐epithelialization, making histological assessment less adequate .…”

mentioning

confidence: 99%

Examination of endothelial cell‐induced epidermal regeneration in a mice‐based chimney wound model

Seo

Park

Choi

et al. 2016

Wound Repair Regeneration

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As wound contraction in the cutaneous layer occurs rapidly in mice, mechanical means are typically used to deliberately expose the wound to properly investigate healing by secondary intention. Previously, silicon rings and splinting models were attempted to analyze histological recovery but prevention of surrounding epidermal cell migration and subsequent closure was minimal. Here, we developed an ideal chimney wound model to evaluate epidermal regeneration in murine under hESC-EC transplantation through histological analysis encompassing the three phases of regeneration: migration, proliferation, and remodeling. Human embryonic stem cell derived endothelial cells (hESC-EC) were transplanted due to possessing a well-known therapeutic effect in angiogenesis which also enhances epidermal repair to depict the process of regeneration. Following a standard 1 mm biopsy punch, a chimney manufactured by modifying a 1.7 mL microtube was simply inserted into the excisional wound to complete the modeling process. Under this model, the excisional wound remained fully exposed for 14 days and even after 4 weeks, only a thin transparent layer of epidermal tissue covered the wound site. This approach is able to more accurately depict epidermal repair in relation to histology while also being a user-friendly and cost-effective way to mimic human recovery in rodents and evaluate epithelial repair induced by a form of therapy.

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Pathology of Juvenile Animals

Picut

Remick

2019

Toxicologic Pathology for Non-Pathologists

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Skin Diseases in Laboratory Mice: Approaches to Drug Target Identification and Efficacy Screening

Cited by 4 publications

References 96 publications

Dermal Toxicity Studies

Dermal Toxicity Studies

Examination of endothelial cell‐induced epidermal regeneration in a mice‐based chimney wound model

Pathology of Juvenile Animals

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