Long-term Time-lapse Multimodal Intravital Imaging of Regeneration and Bone-marrow-derived Cell Dynamics in Skin

Overview

Journal Technology

Date 2014 Aug 5

PMID 25089085

Citations 14

Authors

Benedikt W Graf

Eric J Chaney

Marina Marjanovic

Steven G Adie

Michael DE Lisio

M Carmen Valero

Marni D Boppart

Stephen A Boppart

Affiliations

Soon will be listed here.

Abstract

A major challenge for translating cell-based therapies is understanding the dynamics of cells and cell populations in complex environments. Intravital microscopy has shown great promise for directly visualizing cell behavior . However, current methods are limited to relatively short imaging times (hours), by ways to track cell and cell population dynamics over extended time-lapse periods (days to weeks to months), and by relatively few imaging contrast mechanisms that persist over extended investigations. We present technology to visualize and quantify complex, multifaceted dynamic changes in natural deformable skin over long time periods using novel multimodal imaging and a non-rigid image registration method. These are demonstrated in green fluorescent protein (GFP) bone marrow (BM) transplanted mice to study dynamic skin regeneration. This technology provides a novel perspective for studying dynamic biological processes and will enable future studies of stem, immune, and tumor cell biology .

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