Adipose Tissue-Derived Stem Cells: The Biologic Basis and Future Directions for Tissue Engineering.

Mesenchymal stem cells (MSCs) have been isolated from a variety of tissues using different methods. Active research have confirmed that the most accessible site to collect them is the adipose tissue; which has a significantly higher concentration of MSCs. Moreover; harvesting from adipose tissue is less invasive; there are no ethical limitations and a lower risk of severe complications. These adipose-derived stem cells (ASCs) are also able to increase at higher rates and showing telomerase activity, which acts by maintaining the DNA stability during cell divisions. Adipose-derived stem cells secret molecules that show important function in other cells vitality and mechanisms associated with the immune system, central nervous system, the heart and several muscles. They release cytokines involved in pro/anti-inflammatory, angiogenic and hematopoietic processes. Adipose-derived stem cells also have immunosuppressive properties and have been reported to be "immune privileged" since they show negative or low expression of human leukocyte antigens. Translational medicine and basic research projects can take advantage of bioprinting. This technology allows precise control for both scaffolds and cells. The properties of cell adhesion, migration, maturation, proliferation, mimicry of cell microenvironment, and differentiation should be promoted by the printed biomaterial used in tissue engineering. Self-renewal and potency are presented by MSCs, which implies in an open-source for 3D bioprinting and regenerative medicine. Considering these features and necessities, ASCs can be applied in the designing of tissue engineering products. Understanding the heterogeneity of ASCs and optimizing their properties can contribute to making the best therapeutic use of these cells and opening new paths to make tissue engineering even more useful.

AUTOLOGOUS CHONDROCYTE IMPLANTATION IN BRAZIL.

OBJECTIVE: To describe the first series of cases of autologous chondrocyte implantation (ACI) in collagen membrane performed in Brazil. METHODS: ACI was performed in 12 knees of 11 patients, aged 32.1 ± 10.9 years, with 5.3 ± 2.6 cm2 full-thickness knee cartilage lesions, with a six-month minimum follow-up. Two surgical procedures were performed: arthroscopic cartilage biopsy for isolation and expansion of chondrocytes, which were seeded onto collagen membrane and implanted in the lesion site; the characterization of cultured cells and implant was performed using immunofluorescence for type II collagen (COL2) for cell viability and electron microscopy of the implant. Clinical safety, KOOS and IKDC scores and magnetic resonance imaging were evaluated. We used repeated-measures ANOVA and post-hoc comparisons at α = 5%. RESULTS: COL2 was identified in the cellular cytoplasm, cell viability was higher than 95% and adequate distribution and cell adhesion were found in the membrane. The median follow-up was 10.9 months (7 to 19). We had two cases of arthrofibrosis, one of graft hypertrophy and one of superficial infection as complications, but none compromising clinical improvement. KOOS and IKDC ranged from 71.2 ± 11.44 and 50.72 ± 14.10, in preoperative period, to 85.0 ± 4.4 and 70.5 ± 8.0, at 6 months (p = 0.007 and 0.005). MRI showed regenerated tissue compatible with hyaline cartilage. CONCLUSION: ACI in collagen membrane was feasible and safe in a short-term follow-up, presenting regenerated formation visualized by magnetic resonance imaging and improved clinical function. Level of evidence IV, Case series.

OBJETIVO: Descrever a primeira série de casos de transplante autólogo de condrócitos (TAC) em membrana de colágeno realizada no Brasil. MÉTODOS: Doze joelhos de onze pacientes, com idade de 32,1 ± 10,9 anos, com lesões de cartilagem de espessura total do joelho de tamanho de 5,3 ± 2,6 cm 2 foram submetidos ao TAC, com seguimento mínimo de seis meses. Realizamos dois procedimentos cirúrgicos: biópsia artroscópica de cartilagem para isolamento e expansão de condrócitos, que foram semeados em uma membrana de colágeno implantada no leito da lesão. Foi realizada caracterização com imunofluorescência para colágeno tipo II (COL2) de células cultivadas e implantes, viabilidade celular e microscopia eletrônica no implante. Foram avaliados a segurança clínica, os escores funcionais KOOS e IKDC e a ressonância magnética. Utilizamos teste ANOVA para medidas repetidas, com comparações post-hoc, α = 5%. RESULTADOS: COL2 foi identificado no citoplasma da célula, viabilidade celular foi superior a 95% e houve distribuição adequada e adesão celular na membrana. O seguimento mediano foi de 10,9 meses (7 a 19). Como complicações, ocorreram dois casos de artrofibrose, um de hipertrofia do enxerto e um de infecção superficial, nenhum deles havendo comprometimento da melhora clínica. Escalas KOOS e IKDC passaram de 71,2 ± 11,44 e 50,72 ± 14,10, no pré-operatório, para 85,0 ± 4,4 e 70,5 ± 8,0, aos 6 meses (p = 0,007 e 0,005). Ressonância magnética mostrou tecido regenerado compatível com cartilagem hialina. CONCLUSÃO: TAC em membrana de colágeno foi viável e seguro em seguimento de curto prazo, apresentando formação de regenerado visualizado através de imagens de ressonância magnética e melhora de função clínica. Nível de evidência IV, Série de casos.

IMPLEMENTAÇÃO DO TRANSPLANTE AUTÓLOGO DE CONDRÓCItOS NO BRASIL / Autologous chondrocyte implantation in brazil

ABSTRACT Objective: To describe the first series of cases of autologous chondrocyte implantation (ACI) in collagen membrane performed in Brazil. Methods: ACI was performed in 12 knees of 11 patients, aged 32.1 ± 10.9 years, with 5.3 ± 2.6 cm2 full-thickness knee cartilage lesions, with a six-month minimum follow-up. Two surgical procedures were performed: arthroscopic cartilage biopsy for isolation and expansion of chondrocytes, which were seeded onto collagen membrane and implanted in the lesion site; the characterization of cultured cells and implant was performed using immunofluorescence for type II collagen (COL2) for cell viability and electron microscopy of the implant. Clinical safety, KOOS and IKDC scores and magnetic resonance imaging were evaluated. We used repeated-measures ANOVA and post-hoc comparisons at α = 5%. Results: COL2 was identified in the cellular cytoplasm, cell viability was higher than 95% and adequate distribution and cell adhesion were found in the membrane. The median follow-up was 10.9 months (7 to 19). We had two cases of arthrofibrosis, one of graft hypertrophy and one of superficial infection as complications, but none compromising clinical improvement. KOOS and IKDC ranged from 71.2 ± 11.44 and 50.72 ± 14.10, in preoperative period, to 85.0 ± 4.4 and 70.5 ± 8.0, at 6 months (p = 0.007 and 0.005). MRI showed regenerated tissue compatible with hyaline cartilage. Conclusion: ACI in collagen membrane was feasible and safe in a short-term follow-up, presenting regenerated formation visualized by magnetic resonance imaging and improved clinical function. Level of evidence IV, Case series.

RESUMO Objetivo: Descrever a primeira série de casos de transplante autólogo de condrócitos (TAC) em membrana de colágeno realizada no Brasil. Métodos: Doze joelhos de onze pacientes, com idade de 32,1 ± 10,9 anos, com lesões de cartilagem de espessura total do joelho de tamanho de 5,3 ± 2,6 cm 2 foram submetidos ao TAC, com seguimento mínimo de seis meses. Realizamos dois procedimentos cirúrgicos: biópsia artroscópica de cartilagem para isolamento e expansão de condrócitos, que foram semeados em uma membrana de colágeno implantada no leito da lesão. Foi realizada caracterização com imunofluorescência para colágeno tipo II (COL2) de células cultivadas e implantes, viabilidade celular e microscopia eletrônica no implante. Foram avaliados a segurança clínica, os escores funcionais KOOS e IKDC e a ressonância magnética. Utilizamos teste ANOVA para medidas repetidas, com comparações post-hoc, α = 5%. Resultados: COL2 foi identificado no citoplasma da célula, viabilidade celular foi superior a 95% e houve distribuição adequada e adesão celular na membrana. O seguimento mediano foi de 10,9 meses (7 a 19). Como complicações, ocorreram dois casos de artrofibrose, um de hipertrofia do enxerto e um de infecção superficial, nenhum deles havendo comprometimento da melhora clínica. Escalas KOOS e IKDC passaram de 71,2 ± 11,44 e 50,72 ± 14,10, no pré-operatório, para 85,0 ± 4,4 e 70,5 ± 8,0, aos 6 meses (p = 0,007 e 0,005). Ressonância magnética mostrou tecido regenerado compatível com cartilagem hialina. Conclusão: TAC em membrana de colágeno foi viável e seguro em seguimento de curto prazo, apresentando formação de regenerado visualizado através de imagens de ressonância magnética e melhora de função clínica. Nível de evidência IV, Série de casos.

A Reliable Stem Cell Carrier: An Experimental Study in Wistar Rats.

INTRODUCTION: Treatments based on cell biology need reliable and precise carriers for reaching the desired targets. For that reason, a PDO-based cell carrier was idealized, with the purpose of carrying stem cells to distant sites at room temperature. MATERIALS AND METHODS: Three modalities of the same carrier were evaluated: one containing undifferentiated human dental pulp stem cells (DPSCs); one loaded with stem cells induced to neurogenic differentiation (DPSCNs); and one without cells (Blank). The carriers were implanted in sciatic nerve gaps in 48 Wistar rats that were divided in three groups. Two other rats were included in a SHAM control group. Immunohistochemical, histological and clinical analyses were performed in two, four, six and eight weeks of time. RESULTS: Efficacy of human stem cell transportation at room temperature to rats was attested. Moreover, it was possible to confirm that those cells show tropism for inflamed environments and are also prone to induction of neurogenesis in the first two weeks, vanishing after that period. CONCLUSION: Clinical evaluation of the animals' gait recovery shows a promising perspective of success with the inclusion of stem cell-loaded PDO tubes in nerve gaps, which may be positively compared to previously published studies. NO LEVEL ASSIGNED: This journal requires that authors assign a level of evidence to each article. For a full description of these Evidence-Based Medicine ratings, please refer to the Table of Contents or the online Instructions to Authors - www.springer.com/00266.

Mesenchymal progenitor cells from canine fetal tissues: yolk sac, liver, and bone marrow.

During fetal development, mesenchymal progenitor (MP) cells are co-localized in major hematopoietic territories, such as yolk sac (YS), bone marrow (BM), liver (LV), and others. Studies using mouse and human MP cells isolated from fetus have shown that these cells are very similar but not identical to adult mesenchymal stem cells (MSC). Their differentiation potential is usually restricted to production of highly committed osteogenic and chondrogenic precursors. Such properties of fetal MP cells can be very useful for tissue regeneration, when a great number of committed precursors are required. The objectives of this study were to isolate and characterize MP cells from canine YS, BM, and LV in early and late stages of fetal development. Gestational stage was identified, and cell culture conditions were evaluated for efficient isolation of canine MP cells. All canine fetal MP cells expressed vimentin, nestin, and CD44 proteins. Cytokeratin 18 expression was observed in BM- and LV-MP cells, and vascular endothelial (VE)-cadherin expression was observed only in YS-MP cells. A small number of MP cells (5%) from LV and YS expressed Oct3/4 protein. The differentiation potential of canine fetal MP cells varied significantly: YS- and BM-MP cells differentiated into bone and cartilage, whereas LV-MP cells differentiation was limited to osteogenic fate. None of the canine fetal MP cells were able to differentiate into adipose cells. Our data suggest that canine fetal MP cells are an appropriate in vitro model to study MP biology from hematopoietic territories and they are a source of committed osteogenic and chondrogenic precursors for regenerative medicine.

Corneal Reconstruction with Tissue-Engineered Cell Sheets Composed of Human Immature Dental Pulp Stem Cells

To determine the outcome of the use of a tissue-engineered cell sheet composed of human undifferentiated immature dental pulp stem cells (hIDPSC) for ocular surface reconstruction in an animal model of total limbal stem cell deficiency (LSCD). LSCD was induced by the application of 0.5 M NaOH to the right eye of rabbits for 25 seconds (mild chemical burn [MCB]) and for 45 seconds (severe chemical burn [SCB]). After 1 month, a superficial keratectomy was performed to remove the fibrovascular pannus that covered the animals' burned corneas. A tissue-engineered hIDPSC sheet was transplanted onto the corneal bed and then covered with deepithelialized human amniotic membrane (AM). In the respective control groups, the denuded cornea was covered with AM only. After 3 months, a detailed analysis of the rabbit eyes was performed with regard to clinical aspect, histology, electron microscopy, and immunohistochemistry. Corneal transparency of the rabbit eyes that underwent hIDPSC transplantation was improved throughout the follow-up, while the control corneas developed total conjunctivalization and opacification. Rabbits from the MCB group showed clearer corneas with less neovascularization. The clinical data were confirmed by histologic analysis that showed healthy uniform corneal epithelium, especially in the MCB group. The presence of hIDPSC was detected using an anti-hIDPSC antibody. The corneal tissue also showed positive immunostaining with anti-human antibodies. In the control corneas, none of these antigens were detected. Overall, these data showed that transplantation of a tissue-engineered hIDPSC sheet was successful for the reconstruction of corneal epithelium in an animal model of LSCD.

Corneal reconstruction with tissue-engineered cell sheets composed of human immature dental pulp stem cells.

PURPOSE: To determine the outcome of the use of a tissue-engineered cell sheet composed of human undifferentiated immature dental pulp stem cells (hIDPSC) for ocular surface reconstruction in an animal model of total limbal stem cell deficiency (LSCD). METHODS: LSCD was induced by the application of 0.5 M NaOH to the right eye of rabbits for 25 seconds (mild chemical burn [MCB]) and for 45 seconds (severe chemical burn [SCB]). After 1 month, a superficial keratectomy was performed to remove the fibrovascular pannus that covered the animals' burned corneas. A tissue-engineered hIDPSC sheet was transplanted onto the corneal bed and then covered with deepithelialized human amniotic membrane (AM). In the respective control groups, the denuded cornea was covered with AM only. After 3 months, a detailed analysis of the rabbit eyes was performed with regard to clinical aspect, histology, electron microscopy, and immunohistochemistry. RESULTS: Corneal transparency of the rabbit eyes that underwent hIDPSC transplantation was improved throughout the follow-up, while the control corneas developed total conjunctivalization and opacification. Rabbits from the MCB group showed clearer corneas with less neovascularization. The clinical data were confirmed by histologic analysis that showed healthy uniform corneal epithelium, especially in the MCB group. The presence of hIDPSC was detected using an anti-hIDPSC antibody. The corneal tissue also showed positive immunostaining with anti-human antibodies. In the control corneas, none of these antigens were detected. CONCLUSIONS: Overall, these data showed that transplantation of a tissue-engineered hIDPSC sheet was successful for the reconstruction of corneal epithelium in an animal model of LSCD.