Retinal Organoids

Retinal Organoid Model Highlights

Accelerate your lead compound selection by understanding their mode of action in functional retinal tissue

Complex functional human retina model

Well-characterised and reproducible

Ready-to-use

Light responsive retinal organoids for accurate prediction of clinical outcomes

The retinal organoids recapitulate the complex structure of the human retina with laminar cell organisation mimicking embryonic development. They contain the outer photoreceptor segment of the retina that responds to light.

Applications

Gene therapy vector assessment
Disease modelling
Investigational drug safety and efficacy

Available analytical readouts for our services with retinal organoids

Immunofluorescence analyses
mRNA quantification by RT-qPCR
Transcriptomic analysis by single-cell RNA sequencing
Cytotoxicity assays
Cytokine release
Flow cytometry
Electron microscopy

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A microscope image of retinal organoids — Cone photoreceptor cells labelled with anti-Opsin (Red/Green) antibody.

Origin

Healthy donor

Multiple cell types

3D structure

Lead Time

4-6 Weeks

Products

Fresh retinal organoids
Retinal organoid cell pellets
Frozen sections of retinal organoids
Standard offering at Day 150 (D150)
Customisable time points available D30, D60, D90, D120, D180, D210

Cell Types

Rod and cone photoreceptors
Retinal ganglion cells
Bipolar cells
Horizontal cells
Amacrine cells
Müller glial cells

Origin

Human iPSCs (Healthy donor)

How to use our retinal organoid model?

Order organoids for use in your lab

Newcells provides on demand supply of fresh retinal organoids through regular batch release every 4-6 weeks. We also provide retinal organoids as cell pellets, total RNA sample and frozen sections slides to suit multiple applications.

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Outsource your experiments to us

Take advantage of our expertise: with a fast and reliable service, the Newcells team of experts design the experiments with you to answer your questions and give you the results within 2 months. the studies are carried out with Newcells validated retinal organoids. Alternatively, Newcells has the capability to generate organoids from customer's cells, and perform the assays. All bespoke projects are carried out in state-of-the-art UK facilities.

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Newcells Retinal Organoids

Hannah Steward, Associate Scientist

Applications for retinal organoids Close Open

Gene therapy, including in vitro viral vector evaluation
Disease modelling
Investigational drug safety and efficacy

Retinal Organoid Characterisation Close Open

In vitro retinal organoid differentiation follows the embryonic development timeline, spanning 150 to 210 days. The temporal order of retinogenesis is comparable to in vivo, recapitulating critical features of foetal retinal tissue including the laminar organisation of cell types.

The organoids include retinal ganglion cells, horizontal cells, amacrine cells and photoreceptors (including cone and rod photoreceptors). Depending on the cell type of interest, the retinal organoids can be used at different stages of development (usually between D60 and D210). For example, retinal ganglion cells are more prevalent at D60 whereas the photoreceptors have a peak expression at later time points.

Schematic representation of the retina

The differentiation process is fully characterised and monitored through the analysis of biomarkers specific for each cell type. For example, for cone photoreceptors, we monitor the expression of OPNSW, OPNMW, OPNLW, ARR3, RXRG; for rod photoreceptors we use RHO and NRL and for retinal ganglion cells we follow MATH5 (ATOH7) and BRN3 (POU4F2). Our organoids are validated for many applications.

Cell type	Gene	Timepoint of appearance	Timepoint of peak expression
Retinal ganglion cells	MATH5 (ATOH7)	d30 - d180	d60
Retinal ganglion cells	BRN3 (POU4F2)	d30 - d210	d60
Horizontal and amacrine cells	TFAP2A	d30 - d210	d150
Horizontal and amacrine cells	PROX1	d30 - d210	d150
Bipolar cells	GRIK1	d30 - d210	d150
Bipolar cells	CADPS	d30 - d210	d150
Photoreceptors	RCVRN	d60 - d210	d210
	RBP3	d60 - d210	d210
	IMPG1	d120 - d210	d210
	CRX	d60 - d210	d210
Cone photoreceptors	OPN1SW	d120 - d210	d210
	OPN1MW	d150 - d210	d210
	OPN1LW	d120 - d210	d210
	ARR3	d60 - d210	d180
	RXRG	d60 - d210	d150
Rod photoreceptors	RHO	d120 - d210	d210
Rod photoreceptors	NRL	d90 - d210	d180
RPE	RPE65	d60 - d210	d210
Muller glia	RLBP1	d90 - d210	d210
Muller glia	CRYM	d30 - d210	d210

Cell type	Cell marker	Protein expression at d150	Protein expression at d180	Protein localisation at d150-d180
Photoreceptors	RCVRN	✓	✓	ONL
Retinal ganglion cells	SNCG and Huc/D	✓	✓	INL/GCL
Cone photoreceptors	OPN1MW/LW	✓*	✓	ONL
Rod photoreceptors	RHO	✓*	✓	ONL
Bipolar cells	PKC-α	**	✓	INL
Amacrine cells	AP-2α	✓	✓	INL
Horizontal cells	PROX1	✓	✓	INL
Muller glia	CRALBP	✓	✓	All layers

*Small number of developing rods and cones

**Expressed at transcriptional level

Retinal organoids description Close Open

Characteristics of iPSC-derived retinal organoids:

Size: ~1.3 mm in diameter
Number of cells: ~ 40,000
Cell types: retinal ganglion cells, horizontal cells, amacrine cell and photoreceptors (including cone and rod photoreceptors)
Structure: fully-stratified, similar to the human retina
Main characteristics: formation of primitive photoreceptor outer segments, recapitulate retinogenesis in vitro
Other characteristics: responsive to known toxins, functional and responsive to light, all cell layers allow drug permeation

Light-driven spiking activity recorded from presumed ON-Centre retinal ganglion cells (RGCs) and OFF-Centre RGCs. In the raster plot, each small vertical bar indicates the time stamp of a spike, where each row represents a different RGC. The left half illustrates the activity before stimulus onset and separated by the red line, the right half illustrates the activity when exposed to light.

Retinal organoids available to order as Close Open

Fresh retinal organoids

Supplied at D150 of differentiation as standard
Custom time points available : D60, D180
Optimized cell culture medium
Origin : human iPSCs (healthy donor)

Retinal organoids cell pellets

Supplied at D150 of differentiation as standard
Custom time points available: D30, D60, D90, D120, D180, D210
Origin : human iPSCs (healthy donor)

Frozen sections of retinal organoids

10μm frozen sections of retinal organoids
ready for immunofluorescence staining
Supplied at D150 of differentiation as standard
Custom time points : D30, D60, D90, D120, D180, D210
Origin : human iPSCs (healthy donor)

Catalogue reference Close Open

Model	Sku no.	Species	Readouts
Retinal Organoid Services
iPSC reprogramming (n=3 vials with 1x106 cells per vial shipped to the customer)	RSDR0000RO	Human	Brightfield imaging. Confirmation of Sendai virus clearance via PCR. Flow cytometry for OCT4 and TRA-1-60. Trilineage differentiation assessment.Karyotyping for genetic stability
iPSCs differentiation to retinal organoids	RSDD0000RO	Human	Brightfield imaging
iPSCs differentiation to retinal organoids	RSDD0000RO	Human	Brightfield imaging. Quantitative IF for VSX2, Recoverin,and SNCG
iPSCs differentiation to retinal organoids	RSDD0000RO	Human	Brightfield imaging. Quantitative IF for Recoverin. RT-PCR for retinal markers
Retinal Toxicity	RST00000RO	Human	Brightfield Imaging. ATP/LDH (basic)
Retinal Toxicity	RST00000RO	Human	Brightfield Imaging, ATP/LDH. Qualitative IF (3 markers). TUNEL (comprehensive)
Retina Disease Modelling	RSD00000RO	Human	Brightfield imaging
Retina Disease Modelling	RSD00000RO	Human	Brightfield imaging. Quantitative IF for VSX2, Recoverin and SNCG
Retina Disease Modelling	RSD00000RO	Human	Brightfield imaging. Quantitative IF for Recoverin. RT-PCR for retinal markers
Retina Gene Therapy Evaluation	RSG00000RO	Human	Brightfield imaging. Fluorescence imaging on live organoids
Retina Gene Therapy Evaluation	RSG00000RO	Human	Brightfield imaging. Fluorescence imaging on live organoids. ATP, LDH and Flow Cytometry for Annexin V for cell viability and apoptosis.Qualitative IF with co-staining for GFP and retinal markers. Flow cytometry for analysing transduction efficiency. RT-PCR for key retina makers
Live Retinal Organoids Product
Human iPSC-derived retinal organoids (n=10) in 5 ml vial filled with organoid culture medium	RP000D60RO, RP000D90RO,RP00D120RO, RP00D150RO, RP00D180RO, RP00D210RO	Human	N/A
Retinal Organoid Frozen Pellets
Human iPSC-derived retinal organoids (N=10) lysed and frozen in 5 ml microcentrifuge tube	RP0D60ROFP, RP0D90ROFP, RPD120ROFP, RPD150ROFP, RPD180ROFP, RPD210ROFP	Human	N/A
Retinal Organoid Frozen Sections
Human iPSC-derived retinal organoids frozen sections (10 μm thickness, 6 sections/slide, up to 12 organoids per section) on a microscopic slide	RP0D60ROFP, RP0D90ROFP, RPD120ROFP, RPD150ROFP, RPD180ROFP, RPD210ROFP	Human	N/A
Retinal Organoid Culture Medium
Human iPSC-derived retinal organoid culture medium. 500 mL in 1 bottle	RP0000M500	Human	N/A

Services

Disease Modelling

We ethically source patient lines or use gene editing to produce models of retinopathies.

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Retinal toxicity evaluation

High throughput in vitro drug screening for retinal safety/toxicity and efficacy testing.

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Gene therapy

Rapid in vitro preclinical evaluation of viral vectors for retinal therapy development.

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Images

DAPI RCVRN SNCG — Localization and distribution of photoreceptors (RCVRN, green) and retinal ganglion cells (SNCG, red) in retinal organoids at d150. Nuclear DAPI staining (blue)

Localization and distribution of Müller glia cells (CRALBP, red) in retinal organoids. Nuclear DAPI staining (blue). — Localization and distribution of Müller glia cells (CRALBP, red) in retinal organoids at d180. Nuclear DAPI staining (blue).

Rod photoreceptors — Presence of rod photoreceptors (RHO+) at different stages of development in iPSC-derived retinal organoids. ‘d’ refers to ‘days of differentiation’.

Cone photoreceptors — Presence of green and red cone photoreceptors (OPN1MW/LW+) at different stages of development in iPSC-derived retinal organoids. ‘d’ refers to ‘days of differentiation’.

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