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A guide for optimal iodine staining and high‐throughput diceCT scanning in snakes

Authors :
Ramon S. Nagesan
Jaimi A. Gray
Alison R. Davis Rabosky
Sean Callahan
Jenna M. Crowe-Riddell
Source :
Ecology and Evolution, Ecology and Evolution, Vol 11, Iss 17, Pp 11587-11603 (2021)
Publication Year :
2021
Publisher :
Wiley, 2021.

Abstract

Diffusible iodine‐based contrast‐enhanced computed tomography (diceCT) visualizes soft tissue from micro‐CT (µCT) scans of specimens to uncover internal features and natural history information without incurring physical damage via dissection. Unlike hard‐tissue imaging, taxonomic sampling within diceCT datasets is currently limited. To initiate best practices for diceCT in a nonmodel group, we outline a guide for staining and high‐throughput µCT scanning in snakes. We scanned the entire body and one region of interest (i.e., head) for 23 specimens representing 23 species from the clades Aniliidae, Dipsadinae, Colubrinae, Elapidae, Lamprophiidae, and Viperidae. We generated 82 scans that include 1.25% Lugol's iodine stained (soft tissue) and unstained (skeletal) data for each specimen. We found that duration of optimal staining time increased linearly with body size; head radius was the best indicator. Postreconstruction of scans, optimal staining was evident by evenly distributed grayscale values and clear differentiation among soft‐tissue anatomy. Under and over stained specimens produced poor contrast among soft tissues, which was often exacerbated by user bias during “digital dissections” (i.e., segmentation). Regardless, all scans produced usable data from which we assessed a range of downstream analytical applications within ecology and evolution (e.g., predator‐prey interactions, life history, and morphological evolution). Ethanol destaining reversed the known effects of iodine on the exterior appearance of physical specimens, but required substantially more time than reported for other destaining methods. We discuss the feasibility of implementing diceCT techniques for a new user, including approximate financial and temporal commitments, required facilities, and potential effects of staining on specimens. We present the first high‐throughput workflow for full‐body skeletal and diceCT scanning in snakes, which can be generalized to any elongate vertebrates, and increases publicly available diceCT scans for reptiles by an order of magnitude.<br />We present the first high‐throughput workflow for full‐body skeletal and soft‐tissue (dice) CT scans in preserved snakes. These methods increase publicly available diceCT scans for reptiles by an order of magnitude and can be generalized to any elongate vertebrates.

Details

ISSN :
20457758
Volume :
11
Database :
OpenAIRE
Journal :
Ecology and Evolution
Accession number :
edsair.doi.dedup.....9f1acc2cc0f710c6ea5e9979cc626686
Full Text :
https://doi.org/10.1002/ece3.7467