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Abstract

Zebrafish, an established model organism in developmental biology, is also a valuable tool for imaging wound healing in space and time with cellular resolution. However, long-term imaging of wound healing poses technical challenges as wound healing occurs over multiple temporal scales. The traditional strategy of larval encapsulation in agarose successfully limits sample movement but impedes larval development and tissue regrowth and is therefore not amenable to long-term imaging of wound healing. To overcome this challenge, we engineered a functionally compartmentalized device, the zebrafish Wounding and Entrapment Device for Growth and Imaging (zWEDGI), to orient larvae for high-resolution microscopy, including confocal and second harmonic generation (SHG), while allowing unrestrained tail development and regrowth. In this device, larval viability was maintained and tail regrowth was improved over embedding in agarose. The quality of tail fiber SHG images collected from larvae in the device was similar to fixed samples but provided the benefit of time lapse data collection. Furthermore, we show that this device was amenable to long-term (>24 h) confocal microscopy of the caudal fin. Finally, the zWEDGI was designed and fabricated using readily available techniques so that it can be easily modified for diverse experimental imaging protocols.

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References

Ueno

, Hunt

, Hopf

. Using physiology to improve surgical wound outcomes. Plast Reconstr Surg, 2006; 117(7 Suppl):59S–71S.

Martin

, Feng

. Inflammation: wound healing in zebrafish. Nature, 2009; 459:921–923.

Midwood

, Williams

, Schwarzbauer

. Tissue repair and the dynamics of the extracellular matrix. Int J Biochem Cell Biol, 2004; 36:1031–1037.

LeBert

, Squirrell

, Rindy

, Broadridge

, Lui

, Zakrzewska

, et al. Matrix metalloproteinase 9 modulates collagen matrices and wound repair. Development, 2015; 142:2136–2146.

Kanno

, Fukuda

. Fibronectin and tenascin in rat tracheal wound healing and their relation to cell proliferation. Pathol Int, 1994; 44:96–106.

Frykberg

, Banks

. Challenges in the treatment of chronic wounds. Adv Wound Care, 2015; 4:560–582.

Yoo

, Freisinger

, LeBert

, Huttenlocher

. Early redox, Src family kinase, and calcium signaling integrate wound responses and tissue regeneration in zebrafish. J Cell Biol, 2012; 199:225–234.

Marston

, Dermagraft Diabetic Foot Ulcer Study Group. Risk factors associated with healing chronic diabetic foot ulcers: The importance of hyperglycemia. Ostomy Wound Manage, 2006; 52:26–28, 30, 32 passim.

Trent

, Falabella

, Eaglstein

, Kirsner

. Venous ulcers: Pathophysiology and treatment options. Ostomy Wound Manage, 2005; 51:38–54; quiz 55–56.

10.

Petzold

, Bedell

, Boczek

, Essner

, Balciunas

, Clark

, et al. SCORE imaging: Specimen in a corrected optical rotational enclosure. Zebrafish, 2010; 7:149–154.

11.

Kawakami

, Fukazawa

, Takeda

. Early fin primordia of zebrafish larvae regenerate by a similar growth control mechanism with adult regeneration. Dev Dyn, 2004; 231:693–699.

12.

Meeker

, Trede

. Immunology and zebrafish: Spawning new models of human disease. Dev Comp Immunol, 2008; 32:745–757.

13.

Lawson

, Weinstein

. In vivo imaging of embryonic vascular development using transgenic zebrafish. Dev Biol, 2002; 248:307–318.

14.

Centonze

, White

. Multiphoton excitation provides optical sections from deeper within scattering specimens than confocal imaging. Biophys J, 1998; 75:2015–2024.

15.

Squirrell

, Wokosin

, White

, Bavister

. Long-term two-photon fluorescence imaging of mammalian embryos without compromising viability. Nat Biotechnol, 1999; 17:763–767.

16.

Campagnola

, Millard

, Terasaki

, Hoppe

, Malone

, Mohler

. Three-dimensional high-resolution second-harmonic generation imaging of endogenous structural proteins in biological tissues. Biophys J, 2002; 82(Pt 1):493–508.

17.

Lakowicz

, Szmacinski

, Nowaczyk

, Johnson

. Fluorescence lifetime imaging of free and protein-bound NADH. Proc Natl Acad Sci U S A, 1992; 89:1271–1275.

18.

Bischel

, Mader

, Green

, Huttenlocher

, Beebe

. Zebrafish Entrapment By Restriction Array (ZEBRA) device: A low-cost, agarose-free zebrafish mounting technique for automated imaging. Lab Chip, 2013; 13:1732–1736.

19.

Harvie

, Green

, Neely

, Huttenlocher

. Innate immune response to Streptococcus iniae infection in zebrafish larvae. Infect Immun, 2013; 81:110–121.

20.

Andersen

, Asuri

, Halloran

. In vivo imaging of cell behaviors and F-actin reveals LIM-HD transcription factor regulation of peripheral versus central sensory axon development. Neural Dev, 2011; 6:27.

21.

LeBert

, Squirrell

, Huttenlocher

, Eliceiri

. Second harmonic generation microscopy in zebrafish. Methods in Cell Biology, 2016; 133:56–68.

22.

Schindelin

, Arganda-Carreras

, Frise

, Kaynig

, Longair

, Pietzsch

, et al. Fiji: An open-source platform for biological-image analysis. Nat Methods, 2012; 9:676–682.

23.

Thevenaz

, Ruttimann

, Unser

. A pyramid approach to subpixel registration based on intensity. IEEE Trans Image Process, 1998; 7:27–41.

24.

Conklin

, Provenzano

, Eliceiri

, Sullivan

, Keely

. Fluorescence lifetime imaging of endogenous fluorophores in histopathology sections reveals differences between normal and tumor epithelium in carcinoma in situ of the breast. Cell Biochem Biophys, 2009; 53:145–157.

25.

Vincent

WJB

, Freisinger

, Lam

, Huttenlocher

, Sauer

J-D

. Macrophages mediate flagellin induced inflammasome activation and host defense in zebrafish. Cell Microbiol, 2016; 18:591–604.

26.

Dane

, Tucker

. Modulation of epidermal cell shaping and extracellular matrix during caudal fin morphogenesis in the zebrafish Brachydanio rerio. Development, 1985; 87:145–161.

27.

Duran

, Mari-Beffa

, Santamaria

, Becerra

, Santos-Ruiz

. Actinotrichia collagens and their role in fin formation. Dev Biol, 2011; 354:160–172.

28.

Sullivan

, Kim

. Zebrafish as a model for infectious disease and immune function. Fish Shellfish Immunol, 2008; 25:341–350.

29.

Quint

, Smith

, Avaron

, Laforest

, Miles

, Gaffield

. Bone patterning is altered in the regenerating zebrafish caudal fin after ectopic expression of sonic hedgehog and bmp2b or exposure to cyclopamine. Proc Natl Acad Sci U S A, 2002; 99:8713–8718.

30.

Pang

, Ge

. Epidermal growth factor and TGFalpha promote zebrafish oocyte maturation in vitro: potential role of the ovarian activin regulatory system. Endocrinology, 2002; 143:47–54.

31.

Berman

. 3-D printing: The new industrial revolution. Bus Horiz, 2012; 55:155–162.

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zWEDGI: Wounding and Entrapment Device for Imaging Live Zebrafish Larvae

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