Development of a conjunctival tissue substitute on the basis of plastic compressed collagen

Drechsler, C. C.; Kunze, Alexander; Kureshi, Alvena; Grobe, Gesa Maria; Reichl, Stephan; Geerling, Gerd; Daniels, Julie T.; Schrader, Stefan

doi:10.1002/term.1991

Cited by 33 publications

(29 citation statements)

References 37 publications

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“…Biomechanical properties of CS and γDCS were examined by a stretch-stress test (Drechsler et al, 2015) using a Zwick/Roell Z 0.5 static material testing machine with a 10 N load cell. The CS and γDCS were spread onto a PBS soaked filter membrane, kept wet, and cut into 10 × 10 mm pieces.…”

Section: Biomechanical Propertiesmentioning

confidence: 99%

Decellularized human corneal stromal cell sheet as a novel matrix for ocular surface reconstruction

Mertsch

Hasenzahl

Reichl

et al. 2020

J Tissue Eng Regen Med

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The shortage of donor corneas as well as the limitations of tissue substitutes leads to the necessity to develop alternative materials for ocular surface reconstruction. Corneal surface substitutes must fulfill specific requirements such as high transparency, low immunogenicity, and mechanical stability combined with elasticity. This in vitro study evaluates a decellularized matrix secreted from human corneal fibroblasts (HCF) as an alternative material for ocular surface reconstruction. HCF from human donors were cultivated with the supplementation of vitamin C to form a stable and thick matrix. Furthermore, due to enhanced cultivation time, a three‐dimensional like multilayered construct which partly mimics the complex structure of the corneal stroma could be generated. The formed human cell‐based matrices (so‐called cell sheets [CS]) were subsequently decellularized. The complete cell removal, collagen content, ultrastructure, and cell toxicity of the decellularized CS (DCS) as well as biomechanical properties were analyzed. Surgical feasibility was tested on enucleated porcine eyes. After decellularization and sterilization, a transparent, thick, cell free, and sterile tissue substitute resulted, which allowed expansion of limbal epithelial stem cells with no signs of cytotoxicity, and good surgical feasibility. DCS seem to be a promising new corneal tissue substitute derived from human cells without the limitation of donor material; however, future in vivo studies are necessary to further elucidate its potential for ocular surface reconstruction.

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Section: Biomechanical Propertiesmentioning

confidence: 99%

Decellularized human corneal stromal cell sheet as a novel matrix for ocular surface reconstruction

Mertsch

Hasenzahl

Reichl

et al. 2020

J Tissue Eng Regen Med

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“…Schrader and colleagues report a commercial-grade CE-marked type I porcine dermal atelocollagen used to create a mechanically compressed collagen matrix that is more dense and robust compared to typical hydrogel-based scaffolds, while retaining high tensile strength and elasticity. 55 The compressed collagen scaffold, however, was not crosslinked and is therefore prone to degradation. In a first clinical case, the compressed collagen matrix was used to fill the ulcerated defect region (as a corneal inlay) while a second identical matrix was used to cover the cornea as a bandage (onlay).…”

Section: Bioengineered Acellular Corneal Stromamentioning

confidence: 99%

Corneal Stromal Regeneration: Current Status and Future Therapeutic Potential

Lagali

2019

Current Eye Research

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The corneal stroma comprises 90% of the corneal thickness and is critical for the cornea's transparency and refractive function necessary for vision. When the corneal stroma is altered by disease, injury, or scarring, however, an irreversible loss of transparency can occur. Corneal stromal pathology is the cause of millions of cases of blindness globally, and although corneal transplantation is the standard therapy, a severe global deficit of donor corneal tissue and eye banking infrastructure exists, and is unable to meet the overwhelming need. An alternative approach is to harness the endogenous regenerative ability of the corneal stroma, which exhibits self-renewal of the collagenous extracellular matrix under appropriate conditions. To mimic endogenous stromal regeneration, however, is a challenge. Unlike the corneal epithelium and endothelium, the corneal stroma is an exquisitely organized extracellular matrix containing stromal cells, proteoglycans and corneal nerves that is difficult to recapitulate in vitro. Nevertheless, much progress has recently been made in developing stromal equivalents, and in this review the most recent approaches to stromal regeneration therapy are described and discussed. Novel approaches for stromal regeneration include human or animal corneal and/or non-corneal tissue that is acellular or is decellularized and/or recellularized, acellular bioengineered stromal scaffolds, tissue adhesives, 3D bioprinting and stromal stem cell therapy. This review highlights the techniques and advances that have achieved first clinical use or are close to translation for eventual therapeutic application in repairing and regenerating the corneal stroma, while the potential of these novel therapies for achieving effective stromal regeneration is discussed. ARTICLE HISTORY

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“…Conjunctival tissue substitutes based on compressed collagen gels may be useful for this purpose; these serve as good substrates for conjunctival cells and display favorable biomechanics due the compression process, resulting in very good surgical handling. 412 While much of the work on ocular surface bioengineering is still in the preclinical stage (particularly for conjunctival reconstruction), there are many exciting developments that may lead to future clinical trials and integration into the management for severe DED.…”

Section: Ivb3b Bioengineered Ocular Surface Substitutesmentioning

confidence: 99%

Report of the Inaugural Meeting of the TFOS i2 = initiating innovation Series: Targeting the Unmet Need for Dry Eye Treatment

et al. 2016

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On March 21, 2015, a meeting was held in London, United Kingdom, to address the progress in targeting the unmet need for dry eye disease (DED) treatment. The meeting, which launched the i(2) = initiating innovation series, was sponsored by the Tear Film & Ocular Surface Society (TFOS; www.TearFilm.org) and supported by Dompé. The TFOS i(2) meeting was designed to review advances in the understanding of DED since publication of the 2007 TFOS International Dry Eye WorkShop (DEWS) report, and to help launch the highly anticipated sequel, DEWS II. The meeting was structured to discuss the scope of the DED problem, to review the clinical challenges of DED, and to consider the treatment challenges of DED. This article provides a synopsis of the presentations of this TFOS i(2) meeting.

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Development of a conjunctival tissue substitute on the basis of plastic compressed collagen

Cited by 33 publications

References 37 publications

Decellularized human corneal stromal cell sheet as a novel matrix for ocular surface reconstruction

Decellularized human corneal stromal cell sheet as a novel matrix for ocular surface reconstruction

Corneal Stromal Regeneration: Current Status and Future Therapeutic Potential

Report of the Inaugural Meeting of the TFOS i2 = initiating innovation Series: Targeting the Unmet Need for Dry Eye Treatment

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