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Abstract

Purpose:

Given that porcine and human retinas have similar structures and characteristics, ex vivo culture of porcine neuroretina provides an attractive model for studying mechanisms of human retinal injury and degenerative disease. Here, we describe the method that was used to establish and characterize an adult porcine retina culture system as a rapid screening tool for retinal survival in real time.

Methods:

Neuroretina explants 8 mm in diameter were harvested from adult swine and cultured on porous cell culture inserts with adjustable heights. Retina explant viability was evaluated at 1, 4, 7, 11, and 14 days of culture using a resazurin-based metabolic assay. The explants were analyzed morphologically through immunohistochemistry for glial activation and apoptosis. Morphometric analysis was also performed on hematoxylin and eosin-stained retina sections from each time point.

Results:

The viability of retina explants gradually decreased over time in culture. The laminar structure of the neuroretina was well preserved during the first 7 days. However, by day 14, most explants showed significant loss of cells in each laminar layer and obvious thinning. Overall, the progressive loss of retinal lamination and thickness, and increase in apoptotic nuclei with activated hypertrophic Müller cells were well correlated with the metabolic activity of the ex vivo neuroretina explants.

Conclusions:

This study was the first report to describe the use of a high-throughput and quantitative method for monitoring retina explant viability in real time. Ex vivo neuroretina cultures closely mimic the functional dynamics of the organ, and can be used efficiently to screen novel therapeutics for retinal neurodegenerative disease.

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References

Lev

Molecular aspects of retinal degenerative diseases. Cell. Mol. Neurobiol. 21:575–589, 2001.

Zarbin

Cell-based therapy for degenerative retinal disease. Trends Mol. Med., 22:115–134, 2016.

Bull

N.D.

, Johnson

T.V.

, Welsapar

, DeKorver

N.W.

, Tomarev

S.I.

, and Martin

K.R.

Use of an adult rat retinal explant model for screening of potential retinal ganglion cell neuroprotective therapies. Invest. Ophthalmol. Vis. Sci., 52:3309–3320, 2011.

Johnson

T.V.

, and Martin

K.R.

Development and characterization of an adult retinal explant organotypic tissue culture system as an in vitro intraocular stem cell transplantation model. Invest. Ophthalmol. Vis. Sci., 49:3503–3512, 2008.

Mack

A.F.

, Uhlmann

, Germer

, Szel

, Enzmann

, and Reichenbach

Differentiation of cones in cultured rabbit retina: effects of retinal pigment epithelial cell-conditioned medium. Neurosci. Lett., 341:53–56, 2003.

Wang

S.W.

, Mu

, Bowers

W.J.

, and Klein

W.H.

Retinal ganglion cell differentiation in cultured mouse retinal explants. Methods. 28:448–456, 2002.

Zhang

S.S.

, Fu

X.Y.

, and Barnstable

C.J.

Tissue culture studies of retinal development. Methods. 28:439–447, 2002.

Manabe

, Kashii

, Honda

, Yamamoto

, Katsuki

, and Akaike

Quantification of axotomized ganglion cell death by explant culture of the rat retina. Neurosci. Lett., 334:33–36, 2002.

Xin

, Yannazzo

J.A.

, Duncan

R.S.

, Gregg

E.V.

, Singh

, and Koulen

A novel organotypic culture model of the postnatal mouse retina allows the study of glutamate-mediated excitotoxicity. J. Neurosci. Methods., 159:35–42, 2007.

10.

Pattamatta

, McPherson

, and White

A mouse retinal explant model for use in studying neuroprotection in glaucoma. Exp. Eye Res., 151:38–44, 2016.

11.

White

A.J.

, Heller

J.P.

, Leung

, Tassoni

, and Martin

K.R.

Retinal ganglion cell neuroprotection by an angiotensin II blocker in an ex vivo retinal explant model. J. Renin. Angiotensin. Aldosterone. Syst., 16:1193–1201, 2015.

12.

McKinnon

S.J.

, Schlamp

C.L.

, and Nickells

R.W.

Mouse models of retinal ganglion cell death and glaucoma. Exp. Eye Res., 88:816–824, 2009.

13.

Donovan

S.L.

, and Dyer

M.A.

Preparation and square wave electroporation of retinal explant cultures. Nat. Protoc., 1:2710–2718, 2006.

14.

Hatakeyama

, and Kageyama

Retrovirus-mediated gene transfer to retinal explants. Methods. 28:387–395, 2002.

15.

Caffe

A.R.

, Visser

, Jansen

H.G.

, Sanyal

Histotypic differentiation of neonatal mouse retina in organ culture. Curr. Eye Res., 8:1083–1092, 1989.

16.

Ogilvie

J.M.

, Speck

J.D.

, and Lett

J.M.

Growth factors in combination, but not individually, rescue rd mouse photoreceptors in organ culture. Exp. Neurol., 161:676–685, 2000.

17.

Ogilvie

J.M.

, Speck

J.D.

, Lett

J.M.

, and Fleming

T.T.

A reliable method for organ culture of neonatal mouse retina with long-term survival. J. Neurosci. Methods., 87:57–65, 1999.

18.

Fernandez-Bueno

, Fernandez-Sanchez

, Gayoso

M.J.

, Garcia-Gutierrez

M.T.

, Pastor

J.C.

, and Cuenca

Time course modifications in organotypic culture of human neuroretina. Exp. Eye Res., 104:26–38, 2012.

19.

Perrot

, Dutertre-Catella

, Martin

, Warnet

J.M.

, and Rat

A new nondestructive cytometric assay based on resazurin metabolism and an organ culture model for the assessment of corneal viability. Cytometry A. 55:7–14, 2003.

20.

Ren

, Tapias

L.F.

, Jank

B.J.

, Mathisen

D.J.

, Lanuti

, and Ott

H.C.

Ex vivo non-invasive assessment of cell viability and proliferation in bio-engineered whole organ constructs. Biomaterials. 52:103–112, 2015.

21.

Sonnaert

, Papantoniou

, Luyten

F.P.

, and Schrooten

J.I.

Quantitative validation of the presto blue metabolic assay for online monitoring of cell proliferation in a 3D perfusion bioreactor system. Tissue Eng. Part. C. Methods. 21:519–529, 2015.

22.

Lone

A.G.

, Atci

, Renslow

, Beyenal

, Noh

, Fransson

, Abu-Lail

, Park

J.J.

, Gang

D.R.

, and Call

D.R.

Staphylococcus aureus induces hypoxia and cellular damage in porcine dermal explants. Infect. Immun., 83:2531–2541, 2015.

23.

Mustafa

, Shamsuddin

H.S.

, Ideris

, Ibrahim

, Jaafar

, Ali

A.M.

, and Abdullah

J.M.

Viability reduction and Rac1 gene downregulation of heterogeneous ex-vivo glioma acute slice infected by the oncolytic Newcastle disease virus strain V4UPM. Biomed. Res. Int., 2013:248507, 2013.

24.

Ahmed

S.A.

, Gogal

R.M.

Jr. , and Walsh

J.E.

A new rapid and simple non-radioactive assay to monitor and determine the proliferation of lymphocytes: an alternative to [3H]thymidine incorporation assay. J. Immunol. Methods., 170:211–224, 1994.

25.

Gloeckner

, Jonuleit

, and Lemke

H.D.

Monitoring of cell viability and cell growth in a hollow-fiber bioreactor by use of the dye Alamar Blue. J. Immunol. Methods., 252:131–138, 2001.

26.

Larson

E.M.

, Doughman

D.J.

, Gregerson

D.S.

, and Obritsch

W.F.

A new, simple, nonradioactive, nontoxic in vitro assay to monitor corneal endothelial cell viability. Invest. Ophthalmol. Vis. Sci., 38:1929–1933, 1997.

27.

Squatrito

R.C.

, Connor

J.P.

, and Buller

R.E.

Comparison of a novel redox dye cell growth assay to the ATP bioluminescence assay. Gynecol. Oncol., 58:101–105, 1995.

28.

Taylor

, Arner

, Taylor

I.H.

, and Ghosh

Feet on the ground: physical support of the inner retina is a strong determinant for cell survival and structural preservation in vitro. Invest. Ophthalmol. Vis. Sci., 55:2200–2213, 2014.

29.

Wang

, Kolomeyer

A.M.

, Zarbin

M.A.

, and Townes-Anderson

Organotypic culture of full-thickness adult porcine retina. J. Vis. Exp., 20:2655, 2011.

30.

Koizumi

, Zeck

, Ben

, Masland

R.H.

, and Jakobs

T.C.

Organotypic culture of physiologically functional adult mammalian retinas. PLoS One. 2:e221, 2007.

31.

Engelsberg

, and Ghosh

Transplantation of cultured adult porcine full-thickness retina. Cell. Transplant., 16:31–39, 2007.

32.

Ghosh

, Taylor

, and Arner

Exogenous glutamate modulates porcine retinal development in vitro. Dev. Neurosci., 34:428–439, 2012.

33.

Fernandez-Bueno

, Pastor

J.C.

, Gayoso

M.J.

, Alcalde

, and Garcia

M.T.

Muller and macrophage-like cell interactions in an organotypic culture of porcine neuroretina. Mol. Vis., 14:2148–2156, 2008.

34.

Kaempf

, Walter

, Salz

A.K.

, and Thumann

Novel organotypic culture model of adult mammalian neurosensory retina in co-culture with retinal pigment epithelium. J. Neurosci. Methods., 173:47–58, 2008.

35.

Kobuch

, Herrmann

W.A.

, Framme

, Sachs

H.G.

, Gabel

V.P.

, and Hillenkamp

Maintenance of adult porcine retina and retinal pigment epithelium in perfusion culture: characterisation of an organotypic in vitro model. Exp. Eye Res., 86:661–668, 2008.

36.

Taylor

, Arner

, Engelsberg

, and Ghosh

Effects of glial cell line-derived neurotrophic factor on the cultured adult full-thickness porcine retina. Curr. Eye Res., 38:503–515, 2013.

37.

Mollick

, Mohlin

, and Johansson

Human neural progenitor cells decrease photoreceptor degeneration, normalize opsin distribution and support synapse structure in cultured porcine retina. Brain Res. 1646:522–534, 2016.

38.

Guduric-Fuchs

, Ringland

L.J.

, Gu

, Dellett

, Archer

D.B.

, and Cogliati

Immunohistochemical study of pig retinal development. Mol. Vis., 15:1915–1928, 2009.

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Quantitative Assessment of Retina Explant Viability in a Porcine Ex Vivo Neuroretina Model

Abstract

Abstract

Purpose:

Methods:

Results:

Conclusions:

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References

Supplementary Material