A study protocol for a multicentre randomised clinical trial evaluating the safety and feasibility of a bioengineered human allogeneic nanostructured anterior cornea in patients with advanced corneal trophic ulcers refractory to conventional treatment

González‐Andrades, Miguel; Mata, Rosario; González-Gallardo, María del Carmen; Medialdea, Santiago; Arias‐Santiago, Salvador; Martínez‐Atienza, Juliana; Ruiz-Garcia, A.; Pérez-Fajardo, Lorena; Lizana-Moreno, A.; Garzón, Ingrid; Campos, Antonìo; Alaminos, Miguel; Carmona, Gloria; Cuende, Natividad

doi:10.1136/bmjopen-2017-016487

Cited by 35 publications

(23 citation statements)

References 31 publications

(30 reference statements)

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“…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). 56 While the bandage onlay degraded within the first postoperative week, it facilitated coverage of the entire ulcerated region by recipient corneal epithelium, with the inlay portion remaining intact. During the following six month period, the inlay also degraded but with epithelium remaining intact without signs of inflammation or immune rejection.…”

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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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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“…However, one of the limitations of the present study is the need of performing all quality control analyses required by national Medicines Agencies for clinical translation of advanced therapies medicinal products generated by tissue engineering, including biomechanical, biodegradation, porosity, vascularization, and biocompatibility characterization once grafted in vivo. The fact that the basic biomaterial used in the present work fulfilled all these requirements and is currently approved for clinical use [22,23] supports the future clinical usefulness of F-FAOM, but future in vivo analyses should determine the real potential of these novel functionalized tissues. Another limitation is the lack of long-term follow-up, as tissues were analyzed up to 3 weeks.…”

Section: Discussionmentioning

confidence: 64%

“…From a technical standpoint, we found that novel F-FAOM could be easily generated in the laboratory by combining small oral mucosa biopsies with fibrin-agarose biomaterials previously used in tissue engineering [17,18,20], without the need of establishing primary cell cultures previously. Nonfunctionalized fibrin-agarose biomaterials have previously shown adequate biomechanical properties [16] and very good in vivo biocompatibility in animal models [13,21], which allowed us to use these biomaterials in patients [22,23] with promising preliminary results. However, it is well known that previous non-functionalized bioartificial periodontal tissue models typically require several weeks of culture to obtain adequate numbers of stromal cells, followed by a maturation time of the bioartificial tissue of ~3 weeks once the tissue construct is generated [5].…”

Section: Discussionmentioning

confidence: 99%

In Vitro Generation of Novel Functionalized Biomaterials for Use in Oral and Dental Regenerative Medicine Applications

et al. 2020

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Recent advances in tissue engineering offer innovative clinical alternatives in dentistry and regenerative medicine. Tissue engineering combines human cells with compatible biomaterials to induce tissue regeneration. Shortening the fabrication time of biomaterials used in tissue engineering will contribute to treatment improvement, and biomaterial functionalization can be exploited to enhance scaffold properties. In this work, we have tested an alternative biofabrication method by directly including human oral mucosa tissue explants within the biomaterial for the generation of human bioengineered mouth and dental tissues for use in tissue engineering. To achieve this, acellular fibrin–agarose scaffolds (AFAS), non-functionalized fibrin-agarose oral mucosa stroma substitutes (n-FAOM), and novel functionalized fibrin-agarose oral mucosa stroma substitutes (F-FAOM) were developed and analyzed after 1, 2, and 3 weeks of in vitro development to determine extracellular matrix components as compared to native oral mucosa controls by using histochemistry and immunohistochemistry. Results demonstrate that functionalization speeds up the biofabrication method and contributes to improve the biomimetic characteristics of the scaffold in terms of extracellular matrix components and reduce the time required for in vitro tissue development.

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“…En los últimos años, el hidrogel de fibrina-agarosa se ha utilizado con éxito para generar modelos similares a tejidos con bioingeniería para aplicaciones clínicas (27)(28)(29). Después de estudios ex vivo y en estudios vivo-preclínicos, los modelos basados en fibrina agarosa de córnea y piel se elaboraron como productos médicos avanzados en condiciones GMP(Good manufacturing practices) para uso clínico (30). Estudios recientes demostraron la posibilidad de mejorar las propiedades estructurales, biomecánicas y biológicas de la fibrina agarosa mediante el uso de la técnica de nano-estructuración, el uso de agentes reticulantes químicos o la combinación de ambos (31,32).…”

Section: Discussionunclassified

Substitute therapy of the sclera. Identification of the patologies and methodologies in the University Hospital of Granada (2014-2019)

Hermoso-Fernández¹,

García-Serrano²,

González-Gallardo³

et al. 2019

Actual. Med.

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Introducción: La esclera es un tejido avascular compuesto por tejido conectivo denso cuya función principal es proteger las estructuras intraoculares. Existen diversas patologías que ponen en riesgo la integridad de dicho tejido y, en consecuencia, pueden provocar terribles secuelas con un pronóstico nefasto. El tratamiento sustitutivo forma parte de la terapia de dicha patología, siendo el injerto de esclerótica cadáver una opción biocompatible y biomimética a valorar. El injerto de esclerótica de cadáver es un tejido de fácil acceso y con buenos resultados post-quirúrgicos por lo que no solo es usado en el ámbito de la patología escleral, sino que también es utilizado para cirugía de oculoplástica, glaucoma o de retina. No obstante, el peligro de transmisión de priones o el déficit de suministro en algunos países hacen que este tejido sea suplantado por otros tejidos o técnicas quirúrgicas. Métodos: Los objetivos de este estudio son identificar la patología esclerótica susceptible de terapia sustitutiva en los últimos 5 años en el complejo hospitalario universitario de Granada, identificar los métodos empleados como terapéutica sustitutiva en dicha patología y evaluar la práctica de dicha terapia en el contexto de la bibliografía existente al respecto. Para ello, se aplicó un diseño retrospectivo en el que se realizó una búsqueda en los archivos de la unidad de documentación clínica del Hospital Clínico San Cecilio y Hospital Virgen de las Nieves, de los cuales se obtuvieron 9 casos clínicos. Resultados: Entre los 9 casos clínicos, solo 4 fueron sometidos a tratamiento quirúrgico, y de estos, 3 de ellos a terapia sustitutiva por membrana amniótica o injerto escleral. En los 5 casos restantes no se llevó a cabo ninguna técnica quirúrgica, no obstante, podría ser de gran valor el uso del refuerzo con injerto de esclerótica en los casos con escleromalacia para evitar complicaciones futuras. La esclerótica procedente de cadáver se postula como una opción con unos resultados prometedores; sin embargo, las líneas de investigación actuales apuestan por el desarrollo de un sustituto basado en las ventajas de la fibrina agarosa que supla los puntos negativos del tejido donante.

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A study protocol for a multicentre randomised clinical trial evaluating the safety and feasibility of a bioengineered human allogeneic nanostructured anterior cornea in patients with advanced corneal trophic ulcers refractory to conventional treatment

Cited by 35 publications

References 31 publications

Corneal Stromal Regeneration: Current Status and Future Therapeutic Potential

Corneal Stromal Regeneration: Current Status and Future Therapeutic Potential

In Vitro Generation of Novel Functionalized Biomaterials for Use in Oral and Dental Regenerative Medicine Applications

Substitute therapy of the sclera. Identification of the patologies and methodologies in the University Hospital of Granada (2014-2019)

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