Expression of Basement Membrane Molecules by Wharton Jelly Stem Cells (WJSC) in Full-Term Human Umbilical Cords, Cell Cultures and Microtissues.

Wharton's jelly stem cells (WJSC) from the human umbilical cord (UC) are one of the most promising mesenchymal stem cells (MSC) in tissue engineering (TE) and advanced therapies. The cell niche is a key element for both, MSC and fully differentiated tissues, to preserve their unique features. The basement membrane (BM) is an essential structure during embryonic development and in adult tissues. Epithelial BMs are well-known, but similar structures are present in other histological structures, such as in peripheral nerve fibers, myocytes or chondrocytes. Previous studies suggest the expression of some BM molecules within the Wharton's Jelly (WJ) of UC, but the distribution pattern and full expression profile of these molecules have not been yet elucidated. In this sense, the aim of this histological study was to evaluate the expression of main BM molecules within the WJ, cultured WJSC and during WJSC microtissue (WJSC-MT) formation process. Results confirmed the presence of a pericellular matrix composed by the main BM molecules-collagens (IV, VII), HSPG2, agrin, laminin and nidogen-around the WJSC within UC. Additionally, ex vivo studies demonstrated the synthesis of these BM molecules, except agrin, especially during WJSC-MT formation process. The WJSC capability to synthesize main BM molecules could offer new alternatives for the generation of biomimetic-engineered substitutes where these molecules are particularly needed.

Implementación de un modelo de aula invertida para el autoaprendizaje de la ingeniería tisular en el grado de Farmacia / Implementation of a flipped learning classroom model for self-learning of tissue engineering in the Pharmacy degree

Introducción: El presente trabajo describe y evalúa la implementación de un modelo de aula invertida en la materia de Histología para el aprendizaje de ingeniería tisular en el grado de Farmacia con el objetivo de incorporar dichos conocimientos ante su escasa presencia en dicho grado. Sujetos y métodos: El modelo consiste en intercalar en el curso ordinario de Histología del grado de Farmacia un módulo de autoaprendizaje inverso. Participan 110 alumnos que responden a un cuestionario sobre ámbitos conceptuales, procedimentales y actitudinales al comienzo y al final del proceso. Los resultados se analizan estadísticamente. Resultados: Los resultados muestran valores superiores en la evaluación final con respecto a la evaluación inicial. Esta diferencia fue estadísticamente significativa (p < 0,05) tanto en mujeres y hombres como en el total de estudiantes. Los valores obtenidos fueron decrecientes desde el componente actitudinal hasta el componente conceptual. En el componente procedimental, se obtienen valores intermedios. Conclusión: Los valores más elevados observados en los componentes actitudinal y procedimental, tras la implementación del modelo propuesto, ponen de relieve la necesidad de incrementar el componente conceptual en la formación de la ingeniería tisular en el currículo de farmacia.(AU)

Introduction: This paper describes and evaluates the implementation of a flipped learning model in the discipline of histology for learning tissue engineering contents in the Pharmacy degree, with the aim of incorporating this knowledge for the scarce presence of such matter in that degree. Subjects and methods: The model consists of inserting in the ordinary course of Histology of the pharmacy degree an inverse self-learning module. A questionnaire on conceptual, procedural and attitudinal fields was answered by the 110 students involved in the study at the beginning and end of the process. Results were statistically analysed. Results: The results after the implementation of the flipped learning model show statistically significant higher values (p < 0.05) in the final evaluation both in female and male and in all the students with decreasing values from those reached for the attitudinal component to those reached by the conceptual component. In the procedural component, intermediate values are obtained. Conclusion: The highest values observed in the attitudinal and procedural components, after the implementation of the proposed model, highlight the need to increase the conceptual component in the formation of tissue engineering in the pharmacy curriculum.(AU)

Ex Vivo Generation and Characterization of Human Hyaline and Elastic Cartilaginous Microtissues for Tissue Engineering Applications.

Considering the high prevalence of cartilage-associated pathologies, low self-repair capacity and limitations of current repair techniques, tissue engineering (TE) strategies have emerged as a promising alternative in this field. Three-dimensional culture techniques have gained attention in recent years, showing their ability to provide the most biomimetic environment for the cells under culture conditions, enabling the cells to fabricate natural, 3D functional microtissues (MTs). In this sense, the aim of this study was to generate, characterize and compare scaffold-free human hyaline and elastic cartilage-derived MTs (HC-MTs and EC-MTs, respectively) under expansion (EM) and chondrogenic media (CM). MTs were generated by using agarose microchips and evaluated ex vivo for 28 days. The MTs generated were subjected to morphometric assessment and cell viability, metabolic activity and histological analyses. Results suggest that the use of CM improves the biomimicry of the MTs obtained in terms of morphology, viability and extracellular matrix (ECM) synthesis with respect to the use of EM. Moreover, the overall results indicate a faster and more sensitive response of the EC-derived cells to the use of CM as compared to HC chondrocytes. Finally, future preclinical in vivo studies are still needed to determine the potential clinical usefulness of these novel advanced therapy products.

Detergent-based decellularized peripheral nerve allografts: An in vivo preclinical study in the rat sciatic nerve injury model.

Nerve autograft is the gold standard technique to repair critical nerve defects, but efficient alternatives are needed. The present study evaluated the suitability of our novel Roosens-based (RSN) decellularized peripheral nerve allografts (DPNAs) in the repair of 10-mm sciatic nerve defect in rats at the functional and histological levels after 12 weeks. These DPNAs were compared with the autograft technique (AUTO) and Sondell (SD) or Hudson (HD) based DPNAs. Clinical and functional assessments demonstrated a partial regeneration in all operated animals. RSN-based DPNAs results were comparable with SD and HD groups and closely comparable with the AUTO group without significant differences (p > .05). Overall hematological studies confirmed the biocompatibility of grafted DPNAs. In addition, biochemistry revealed some signs of muscle affection in all operated animals. These results were confirmed by the loss of weight and volume of the muscle and by muscle histology, especially in DPNAs. Histology of repaired nerves confirmed an active nerve tissue regeneration and partial myelination along with the implanted grafts, being the results obtained with HD and RSN-based DPNAs comparable with the AUTO group. Finally, this in vivo study suggests that our novel RSN-based DPNAs supported a comparable tissue regeneration, along the 10-mm nerve gap, after 12-week follow-up to HD DPNAs, and both were superior to SD group and closely comparable with autograft technique. However, further improvements are needed to overcome the efficacy of the nerve autograft technique.

In vitro characterization of a novel magnetic fibrin-agarose hydrogel for cartilage tissue engineering.

The encapsulation of cells into biopolymer matrices enables the preparation of engineered substitute tissues. Here we report the generation of novel 3D magnetic biomaterials by encapsulation of magnetic nanoparticles and human hyaline chondrocytes within fibrin-agarose hydrogels, with potential use as articular hyaline cartilage-like tissues. By rheological measurements we observed that, (i) the incorporation of magnetic nanoparticles resulted in increased values of the storage and loss moduli for the different times of cell culture; and (ii) the incorporation of human hyaline chondrocytes into nonmagnetic and magnetic fibrin-agarose biomaterials produced a control of their swelling capacity in comparison with acellular nonmagnetic and magnetic fibrin-agarose biomaterials. Interestingly, the in vitro viability and proliferation results showed that the inclusion of magnetic nanoparticles did not affect the cytocompatibility of the biomaterials. What is more, immunohistochemistry showed that the inclusion of magnetic nanoparticles did not negatively affect the expression of type II collagen of the human hyaline chondrocytes. Summarizing, our results suggest that the generation of engineered hyaline cartilage-like tissues by using magnetic fibrin-agarose hydrogels is feasible. The resulting artificial tissues combine a stronger and stable mechanical response, with promising in vitro cytocompatibility. Further research would be required to elucidate if for longer culture times additional features typical of the extracellular matrix of cartilage could be expressed by human hyaline chondrocytes within magnetic fibrin-agarose hydrogels.

Myocardial fibrosis in arrhythmogenic cardiomyopathy: a genotype-phenotype correlation study.

AIMS: Arrhythmogenic right ventricular cardiomyopathy/dysplasia (ARVC/D) is a life-threatening entity with a highly heterogeneous genetic background. Cardiac magnetic resonance (CMR) imaging can identify fibrofatty scar by late gadolinium enhancement (LGE). Our aim is to investigate genotype-phenotype correlation in ARVC/D mutation carriers, focusing on CMR-LGE and myocardial fibrosis patterns. METHODS AND RESULTS: A cohort of 44 genotyped patients, 33 with definite and 11 with borderline ARVC/D diagnosis, was characterized using CMR and divided into groups according to their genetic condition (desmosomal, non-desmosomal mutation, or negative). We collected information on cardiac volumes and function, as well as LGE pattern and extension. In addition, available ventricular myocardium samples from patients with pathogenic gene mutations were histopathologically analysed. Half of the patients were women, with a mean age of 41.6 ± 17.5 years. Next-generation sequencing identified a potential pathogenic mutation in 71.4% of the probands. The phenotype varied according to genetic status, with non-desmosomal male patients showing lower left ventricular (LV) systolic function. LV fibrosis was similar between groups, but distribution in non-desmosomal patients was frequently located at the posterolateral LV wall; a characteristic LV subepicardial circumferential LGE pattern was significantly associated with ARVC/D caused by desmin mutation. Histological analysis showed increased fibrillar connective tissue and intercellular space in all the samples. CONCLUSION: Desmosomal and non-desmosomal mutation carriers showed different morphofunctional features but similar LV LGE presence. DES mutation carriers can be identified by a specific and extensive LV subepicardial circumferential LGE pattern. Further studies should investigate the specificity of LGE in ARVC/D.

Scleral surgical repair through the use of nanostructured fibrin/agarose-based films in rabbits.

Scleral defects can result as a consequence of trauma, infectious diseases or cancer and surgical repair with allogeneic scleral grafts can be required. However, this method has limitations and novel alternatives are needed. Here, the efficacy of acellular nanostructured fibrin-agarose hydrogel-based substitutes (NFAH) in the repair of scleral defects in rabbits was studied. For this, scleral defects of 5-mm diameter were made on 18 adult-male New Zealand rabbits and repaired with acellular NFAH, NFAH crosslinked with genipin (NFAH-GP) or glutaraldehyde (NFAH-GA), allogeneic scleral grafts as control (C-CTR) or not repaired (negative control N-CTR) (n = 3 each). Macroscopic and histological analyses were performed after 40-days. Macroscopy confirmed the repair of all defects in a comparable manner than the C-CTR. Histology showed no degradation nor integration in C-CTR while NFAH-GP and NFAH-GA biomaterials were encapsulated by connective and inflammatory tissues with partial biodegradation. The NFAH were fully biodegraded and replaced by a loose connective tissue and sclera covering the defects. This in vivo study demonstrated that the NFAH are a promising biocompatible and pro-regenerative alternative to the use of allogeneic cadaveric grafts. However, large defects and long-term studies are needed to demonstrate the potential clinical usefulness of these substitutes.

Identification of Cognitive and Social Framework of Tissue Engineering by Science Mapping Analysis.

IMPACT STATEMENT: This study evaluates the cognitive structure and social behavior of tissue engineering (TE) based on a science mapping analysis. Understanding the terms and topics that play a key role in the development of TE can help administrative authorities to better plan funding. Moreover, a better knowledge of collaborative networks in TE and the identification of potential new opportunities for collaboration may enhance synergies in scientific activities to implement future approaches to therapy.

Global Tissue Engineering Trends: A Scientometric and Evolutive Study.

Tissue engineering (TE) is defined as a multidisciplinary scientific discipline with the main objective to develop artificial bioengineered living tissues to regenerate damaged or lost tissues. Since its appearance in 1988, TE has globally spread to improve current therapeutic approaches, entailing a revolution in clinical practice. The aim of this study is to analyze global research trends on TE publications to realize the scenario of TE research from 1991 to 2016 by using document retrieval from Web of Science database and bibliometric analysis. Document type, language, source title, authorship, countries and filiation centers, and citation count were evaluated in 31,859 documents. Obtained results suggest a great multidisciplinary role of TE due to a wide spectrum-up to 51-of scientific research areas identified in the corpus of literature, being predominant technological disciplines as Material Sciences or Engineering, followed by biological and biomedical areas, as Cell Biology, Biotechnology, or Biochemistry. Distribution of authorship, journals, and countries revealed a clear imbalance, in which a minority is responsible for a majority of documents. Such imbalance is notorious in authorship, where a 0.3% of authors are involved in half of the whole production.

In vivo Evaluation of Nanostructured Fibrin-Agarose Hydrogels With Mesenchymal Stem Cells for Peripheral Nerve Repair.

The regenerative capability of peripheral nerves is very limited, and several strategies have been proposed to increase nerve regeneration. In the present work, we have analyzed the in vivo usefulness of a novel nanostructured fibrin-agarose bio-artificial nerve substitute (Nano) used alone or in combination with NeuraGen® collagen type I conduits (Coll-Nano) in laboratory rats with a 10-mm sciatic nerve defect. Control animals were subjected to the gold-standard autograft technique (Auto). Results first demonstrated that the percentage of self-amputations was lower in Nano and Coll-Nano groups as compared to the Auto group. Neurotrophic ulcers were more abundant in the Auto group (60%, with 66.6% of them being >2-mm) than Nano and Coll-Nano groups (0%) at 4 weeks, although Nano showed more ulcers after 12 weeks. Foot length was significantly altered in Auto animals due to neurogenic retraction, but not in Nano and Coll-Nano groups after 12 weeks. At the functional level, all animals showed a partial sensory recovery as determined by the pinch test, especially in Nano and Auto groups, but did not reach the levels of native animals. Toe-spread test revealed a partial motor function recovery only in Nano animals at 4 weeks and Auto and Nano at 12 weeks. Electromyography showed clear denervation signs in all experimental groups, with few differences between Auto and Nano animals. After 12 weeks, an important denervation decrease and an increase of the reinnervation process was found in Auto and Nano groups, with no differences between these groups. Histological analyses demonstrated an active peripheral nerve regeneration process with newly formed peripheral nerve fascicles showing S-100, GAP-43 and myelin in all experimental groups. The peripheral nerve regeneration process was more abundant in Auto group, followed by Nano group, and both were better than Coll-Nano group. Muscle histology confirmed the electromyography results and showed some atrophy and fibrosis signs and an important weight and volume loss in all groups, especially in the Coll-Nano group (56.8% weight and 60.4% volume loss). All these results suggest that the novel Nano substitutes used in in vivo were able to contribute to bridge a 10-mm peripheral nerve defect in rats.

Evaluation of freeze-drying and cryopreservation protocols for long-term storage of biomaterials based on decellularized intestine.

We evaluated the efficiency of several protocols to preserve the main components of decellularized tissue scaffolds for delayed use. Decellularized rat intestine scaffolds were generated by using SDS and triton X-100 and preserved for 3 months subjected to eight freeze-drying (F1 to F8) and 14 cryopreservation protocols (C1 to C14). Morphological analysis showed that cryopreservation tended to preserve the tissue morphostructure more efficiently than freeze-drying. Histological analysis showed that the content of proteoglycans and glycoproteins was efficiently preserved by most methods. The protocols that most efficiently preserved collagen fibers were those using trehalose and saccharose for freeze-drying (F2, F3, and F7 protocols) and DMSO, albumin, and saccharose (C3, C5, C6, C12) for cryopreservation. Most freeze-drying protocols and cryopreservation protocols with DMSO, albumin, and maltose (C6, C7, C13, and C14) efficiently preserved reticular fibers. For the elastic fibers, freeze-drying methods with trehalose and maltose (F2, F4, F6, and F8) properly preserved these fibers, with the results of most cryopreservation methods comparable to controls. These results suggest that freeze-drying using 0.1M trehalose and cryopreservation in the presence of 8% DMSO and 4.6% albumin are more efficient than other protocols in preserving the scaffold morphostructure and histological composition. © 2017 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 106B: 488-500, 2018.