Presentation is loading. Please wait.

Presentation is loading. Please wait.

Stanford Cornea Project 1. 2 Laura Hartman, Dale Waters, Rachel Parke- Houben, Curtis W. Frank Stayce Beck, Luo Luo Zheng, Yuhua Hu Jennifer Cochran Resmi.

Published byWendy Allen Modified over 9 years ago

Similar presentations

Presentation on theme: "Stanford Cornea Project 1. 2 Laura Hartman, Dale Waters, Rachel Parke- Houben, Curtis W. Frank Stayce Beck, Luo Luo Zheng, Yuhua Hu Jennifer Cochran Resmi."— Presentation transcript:

1 Stanford Cornea Project 1

2 2 Laura Hartman, Dale Waters, Rachel Parke- Houben, Curtis W. Frank Stayce Beck, Luo Luo Zheng, Yuhua Hu Jennifer Cochran Resmi Charalel, Phil Huie, Vijay Vanchinathan Roopa Dalal, Michael Carrasco, Jaan Noolandi Christopher N. Ta

3 Who needs an artificial cornea? In the United States, over 33,000 corneal transplants are performed each year Worldwide, 10 million people are blind due to corneal disease. Most of these people do not have access to corneal transplants and remain blind due to a lack of donor tissue supply and distribution. trachoma corneal ulcer trachoma corneal ulcer

4 Current available keratoprosthesis 4 Boston keratoprosthesis (PMMA) AlphaCor device (PHEMA) ≈1,200 devices implanted to date (still requires donor corneas) ≈ 300 devices implanted to date; limited use Osteo-odonto keratoprosthesis 224 devices implanted with surprisingly high success rates. requires complex surgery and is only performed by a select few surgeons throughout the world Falcinelli, G., et al. Arch Ophthalmol, 2005. 123(10): p. 1319-29.

5 Properties of an Artificial Cornea Biocompatible Optically clear centrally Nutrient permeable Mechanically strong Surface epithelialization Peripheral tissue integration CAD model acknowledgement: L. Kourtis, Stanford Dept. of Mechanical Engineering

6 Epithelium hydrogel Stroma hydrogel Stroma The Stanford Approach 6 high diffusion + stable, optically clear hydrogel  “invisible” material 1. protein modification (Collagen and EGF)  Epithelium grows back 2.

7 Material 7 Single NetworkDouble Network Single NetworkDouble Network 1 st network swollen in monomeric building blocks of 2 nd network polymerization of 2 nd network no chemical linkage two interpenetrating networks (IPNs) highly improved mechanical properties J.P. Gong, et al., Advanced Materials 2003

8 Mechanical Stability 8 1 st network: Poly(ethylene glycol) (PEG) ‏ 2 nd network: Poly(acrylic acid) (PAA)‏ IPN 0 1 2 3 4 5 6 7 8 Maximum Tensile Stress [MPa] PEG (4.6kDa)‏PEG (8kDa)‏PEG (14kDa)‏ PAA IPN water content: ~90% tunable material mechanical stability (contact lens vs. inlay) pore size: diffusion (nutrient vs. drug delivery) longterm stability (implant vs. tissue scaffold)

9 Diffusion 9 glucose ascorbic acid sodium bicarbonate lactic acid urea amino acids A high rate of small molecule diffusion through the hydrogel is required to maintain a healthy epithelium Hydrogel (~100 μm) Flap edge Epithelium Stroma

10 Protein Tethering: Cell Re-Growth 10 no de-swelling of the gel washing in buffer possible no denaturation of proteins

11 Protein Tethering: Qualitative 11 Using fluorescently-labeled collagen, we have shown that this tethering method supports a stable binding of ECM protein. PEG Diacrylamide Hydrogel Control (adsorption) BINDING OF COLLAGEN NHS/EDC (covalent linkage) PEG Diacrylamide Hydrogel

12 12 Phalloidin (red) and Nuclear (DAPI(blue)) staining of primary rabbit corneal fibroblast cells grown on PEGacrylate/PAA Hydrogel tethered with A)Control, B) Collagen, C)Fibronectin, D)Laminin and E) 1:1 mixture of collagen and Fibronectin. D E Protein Tethering: Cell Re-Growth Corneal Fibroblast Cells Attach to ECM-Tethered Hydrogels A) control DC B

13 In vivo experiments 13 rabbit # 2 - post-op 50 days

14 Future Work 14 MATERIAL Determine diffusion coefficients for other proteins through human cornea Apply principles to development of artificial cornea Modify refractive index for inlay application (presbyopia) DEVICE Protein tethering Optimize the ECM content tethered to the hydrogel Use time-lapse microscopy to study cell migration on the hydrogel Addition of enhanced growth factor (EGF) to the protein layer Tissue Integration Fine-tuning is still needed to reduce the pore diameter to 50 – 100 μm Confocal fluorescence microscopy will be used to demonstrate that the channels are interconnected Tether proteins to the channel walls and test for fibroblast growth IN VIVO EXPERIMENTS Implant hydrogel-onlays/inlays Implant artificial cornea

15 Funding National Institutes of Health / National Eye Institute – R01 EY016987 – NIH Grant 5T90 DK070103-03. Singapore Eye Research Institute (SERI) BioX Stanford Office of Technology Licensing Stanford MedScholar Program Fight for Sight Visx 15

16 16

Download ppt "Stanford Cornea Project 1. 2 Laura Hartman, Dale Waters, Rachel Parke- Houben, Curtis W. Frank Stayce Beck, Luo Luo Zheng, Yuhua Hu Jennifer Cochran Resmi."

Similar presentations

Forefront Researches of Computational Material Science Monday, 10/28/2002 Tissue Engineering Self-Assembly.

Forefront Researches of Computational Material Science Monday, 10/28/2002 Tissue Engineering Self-Assembly.
Therapeutic use of hair follicle-derived epithelial stem cells using a murine stem cell deficiency model Slide 1 The authors have no financial interest.

Therapeutic use of hair follicle-derived epithelial stem cells using a murine stem cell deficiency model Slide 1 The authors have no financial interest.
Chp 4 Transport of Solutes and Water. Review 1- The intracellular and extracellular fluids are similar in osmotic concentration but very different in.

Chp 4 Transport of Solutes and Water. Review 1- The intracellular and extracellular fluids are similar in osmotic concentration but very different in.
The Lens is implanted into the corneal stroma of the non-dominant eye, inside a pocket created using femtosecond laser Intracorneal Inlays for Presbyopia.

The Lens is implanted into the corneal stroma of the non-dominant eye, inside a pocket created using femtosecond laser Intracorneal Inlays for Presbyopia.
Intracorneal Inlays for Presbyopia Moderator Ioannis Pallikaris Instructors Stephen Slade John Vukich Dimitrios Bouzoukis Insructional Course 59 19/9/2011.

Intracorneal Inlays for Presbyopia Moderator Ioannis Pallikaris Instructors Stephen Slade John Vukich Dimitrios Bouzoukis Insructional Course 59 19/9/2011.
Optical Prosthetics Technology Mimicking the Eye.

Optical Prosthetics Technology Mimicking the Eye.
Tissue Engineering: a new healthcare technology. Biomaterials Biomaterials science may be the most multidisciplinary of all the sciences which encompasses.

Tissue Engineering: a new healthcare technology. Biomaterials Biomaterials science may be the most multidisciplinary of all the sciences which encompasses.
Live tissue imaging (cornea) Optical imaging of tissue  cells Histology and Electron Microscopy can image ECM. Requires sectioning and staining. Stroma.

Live tissue imaging (cornea) Optical imaging of tissue  cells Histology and Electron Microscopy can image ECM. Requires sectioning and staining. Stroma.
Virtual Screening Methods for Biomaterial Surface Functionalization Behavioral Analysis Cervical Lateral Hemisection – Rodent Model Abstract Over 200,000.

Virtual Screening Methods for Biomaterial Surface Functionalization Behavioral Analysis Cervical Lateral Hemisection – Rodent Model Abstract Over 200,000.
E XTRACELLULAR C OMPONENTS AND C ONNECTIONS B ETWEEN C ELLS H ELP C OORDINATE C ELLULAR A CTIVITIES Kate Rowe, Kylina John, Jacqueline Enriquez.

E XTRACELLULAR C OMPONENTS AND C ONNECTIONS B ETWEEN C ELLS H ELP C OORDINATE C ELLULAR A CTIVITIES Kate Rowe, Kylina John, Jacqueline Enriquez.
Celeste Riley Mentor: Dr. Robert Peattie

Celeste Riley Mentor: Dr. Robert Peattie
Hydrogels.

Hydrogels.
CHAPTER 3 A TOUR OF THE CELL Cell Surfaces and Junctions 1.Plant cells are encased by cell walls 2. The extracellular matrix (ECM) of animal cells functions.

CHAPTER 3 A TOUR OF THE CELL Cell Surfaces and Junctions 1.Plant cells are encased by cell walls 2. The extracellular matrix (ECM) of animal cells functions.
Cornea Implants Topics: Structure of the cornea

Cornea Implants Topics: Structure of the cornea
Richelle C. Thomas, Christine E. Schmidt University of Texas at Austin.

Richelle C. Thomas, Christine E. Schmidt University of Texas at Austin.
Hydrogels for Coating Medical Devices University of Wisconsin BME 400.

Hydrogels for Coating Medical Devices University of Wisconsin BME 400.
Basic Contact Lenses COT/COMT Review.

Basic Contact Lenses COT/COMT Review.
Rheology of Biological Systems Ref. Book: Applied Physical Pharmacy. Ed. Mansour M. Amiji, Beverly J. Sandmann, McGRAW-Hill, 2003 Rheological properties.

Rheology of Biological Systems Ref. Book: Applied Physical Pharmacy. Ed. Mansour M. Amiji, Beverly J. Sandmann, McGRAW-Hill, 2003 Rheological properties.
Anionic polyacrylamides – soil conditioners Jozef Kollár.

Anionic polyacrylamides – soil conditioners Jozef Kollár.
Chapter 17 Beyond the Cell: Extracellular Structures, Cell Adhesion, and Cell Junctions.

Chapter 17 Beyond the Cell: Extracellular Structures, Cell Adhesion, and Cell Junctions.

Similar presentations

Ads by Google