Preliminary study of in vitro chondrogenesis by co-culture of chondrocytes and adipose-derived stromal cells / 中华整形外科杂志

<p><b>OBJECTIVE</b>To explore the feasibility of in vitro chondrogenesis by co-culture of chondrocytes and adipose-derived stromal cells (ADSCs) so as to confirm the hypothesis that chondrocytes can provide chondrogenic microenvironment to induce chondrogenic differentiation of ADSCs.</p><p><b>METHODS</b>Human ADSCs and porcine auricular chondrocytes were in vitro expanded respectively and then were mixed at the ratio of 7:3 (ADSCs: chondrocytes). 200 microl mixed cells (5.0 x 10(7)/ml) were seeded onto a polyglycolic acid/polylactic acid (PGA/PLA) scaffold, 8 mm in diameter and 2 mm in thickness, as co-culture group. Chondrocytes and ADSCs with the same cell number were seeded respectively onto the scaffold as positive control group and negative control group. 200 microl chondrocytes (1.5 x 10(7)/ml) were seeded as low concentration chondrocyte group. There were 6 specimens in each group. All specimens were harvested after in vitro culture for 8 weeks in DMEM plus 10% FBS. Gross observation, histology, immunohistochemistry, wet weight measurement and glycosaminoglycan (GAG) quantification were used to evaluate the results. Multiple-sample t-test statistics analysis was done to compare the difference of wet weight and glycosaminoglycan(GAG) content between the groups.</p><p><b>RESULTS</b>Cells in all groups had fine adhesion to the scaffold and could secrete extracellular matrix. In co-culture group and positive control group, cell-scaffold constructs could maintain the original size and shape during in vitro culture. At 8 weeks, cartilage-like tissue formed in gross appearance and histological features, and abundant type II collagen could be detected by immunohistochemistry. Wet weight and glycosaminoglycan(GAG) content of co-culture group were respectively (174 +/- 12) mg and (7.6 +/- 0.4) mg. There were respectively 75% (P < 0.01) and 79% (P<0.01) of those of positive control group. In negative control group, however, constructs shrunk gradually without mature cartilage lacuna in histology. In low concentration chondrocyte group, constructs also shrunk obviously with small amount of cartilage formation at the edge area of the construct, and wet weight was (85 +/- 5) mg, which was 37% (P<0.01) of that of positive control group.</p><p><b>CONCLUSIONS</b>Chondrocytes can provide chondrogenic microenvironment to induce chondrogenic differentiation of ADSCs and thus promote the in vitro chondrogenesis of ADSCs.</p>

Preliminary study on the phenomenon of epidermal stem cell ectopy in expanded skin / 中华烧伤杂志

<p><b>OBJECTIVE</b>To observe the differentiation and distribution of epidermal stem cell (ESC) after skin soft tissue expansion, and to initially probe into the growth mechanism of expanded skin tissue.</p><p><b>METHODS</b>Samples of normal skin and expanded skin (mean effusion period 45 days) were harvested from head and cervical region in 15 patients who underwent II stage surgery after skin expansion. Samples were divided into scalp adjacent to the center of expander group (expanded scalp, 3 cm from the vertical axis of the expander), scalp from lateral part of the expander group (expanded scalp, 5 - 7 cm lateral to the vertical axis of the expander), cervical skin expansion group, un-expanded scalp control group, and un-expanded cervical skin control group, according to the position of skin harvested. The tissue structure of skin in each group was observed with HE staining, and the differentiation and distribution characteristics of cytokeratin 19 (CK19) positive cells were observed with immunohistochemical staining.</p><p><b>RESULTS</b>Compared with those in the un-expanded control groups, uneven, relatively thickened and obviously folded epidermis with more cell layers and cells with obvious aggregation close to the basal layer were observed in the expanded groups, but those cells were not well-arranged and the transition of polarity was not obvious. The continuity of CK19 positive cells in the basal layer of skin was observed in each of the expanded group with immunohistochemical staining, and positive cells increased obviously and arranged in multilayer in certain parts of basal layer. Clustered or dispersed CK19 positive cells were also observed outside the basal layer. No above-mentioned phenomenon was observed in the un-expanded control group.</p><p><b>CONCLUSIONS</b>The proliferation and differentiation of ESC with ectopic distribution may enhance the repair process after skin soft tissue expansion.</p>

Preliminary investigation on the dynamic change in epidermal stem cells under mechanical stress in vivo / 中华烧伤杂志

<p><b>OBJECTIVE</b>To observe the distribution of epidermal stem cell (ESC) after soft tissue expansion, and to explore dynamic change in ESC under mechanical stress and kinetic mechanism of skin expansion.</p><p><b>METHODS</b>Skin samples were collected from patients after expansion of the scalp. They were divided into three groups: A group (scalp harvested 3 cm away from the center of dilator), B group (scalp tissues at the edge of dilator), and control group (scalp without dilatation). The tissue structures were observed with optical microscope with HE staining. The distribution and differentiation characteristics of cell keratin 19 (CK19) positive cells were observed with inverted phase contrast microscope after immunohistochemistry staining.</p><p><b>RESULTS</b>HE staining showed that the epidermis was thickened and distributed densely with uneven, rugged and increased layers in A, B groups. With immunohistochemistry staining, CK19 positive cells appeared in multilayers in basal membrane, a few of them were in cluster or dispersed , with" hollowing" structure formation. These phenomena were not seen in control group.</p><p><b>CONCLUSION</b>ESC can proliferate with abnormal distribution and "hollowing" structure formation after mechanical dilatation, which may be related to dynamic changes in basal layer cells.</p>

Progress of cellular dedifferentiation research / 中华创伤杂志(英文版)

Differentiation, the stepwise specialization of cells, and transdifferentiation, the apparent switching of one cell type into another, capture much of the stem cell spotlight. But dedifferentiation, the developmental reversal of a cell before it reinvents itself, is an important process too. In multicellular organisms, cellular dedifferentiation is the major process underlying totipotency, regeneration and formation of new stem cell lineages. In humans, dedifferentiation is often associated with carcinogenesis. The study of cellular dedifferentiation in animals, particularly early events related to cell fate-switch and determination, is limited by the lack of a suitable, convenient experimental system. The classic example of dedifferentiation is limb and tail regeneration in urodele amphibians, such as salamanders. Recently, several investigators have shown that certain mammalian cell types can be induced to dedifferentiate to progenitor cells when stimulated with the appropriate signals or materials. These discoveries open the possibility that researchers might enhance the endogenous regenerative capacity of mammals by inducing cellular dedifferentiation in vivo.