BackgroundSmall caliber vascular prostheses are not clinically available because synthetic vascular prostheses lack endothelial cells which modulate platelet activation, leukocyte adhesion, thrombosis, and the regulation of vasomotor tone by the production of vasoactive substances. We developed a novel method to create scaffold-free tubular tissue from multicellular spheroids (MCS) using a “Bio-3D printer”-based system. This system enables the creation of pre-designed three-dimensional structures using a computer controlled robotics system. With this system, we created a tubular structure and studied its biological features.Methods and ResultsUsing a “Bio-3D printer,” we made scaffold-free tubular tissues (inner diameter of 1.5 mm) from a total of 500 MCSs (2.5× 104 cells per one MCS) composed of human umbilical vein endothelial cells (40%), human aortic smooth muscle cells (10%), and normal human dermal fibroblasts (50%). The tubular tissues were cultured in a perfusion system and implanted into the abdominal aortas of F344 nude rats. We assessed the flow by ultrasonography and performed histological examinations on the second (n = 5) and fifth (n = 5) day after implantation. All grafts were patent and remodeling of the tubular tissues (enlargement of the lumen area and thinning of the wall) was observed. A layer of endothelial cells was confirmed five days after implantation.ConclusionsThe scaffold-free tubular tissues made of MCS using a Bio-3D printer underwent remodeling and endothelialization. Further studies are warranted to elucidate the underlying mechanism of endothelialization and its function, as well as the long-term results.
Adipose tissue that consists of mature and immature adipocytes is suggested to contain mesenchymal stem cells (MSCs), but a culture system for analyzing their cell types within the tissue has not been established. Here we show that three-dimensional collagen gel culture of rat sc adipose tissue fragments maintained viable mature adipocytes for a long term, producing immature adipocytes and MSC-like cells from the fragments, using immunohistochemistry, ELISA, and real time RT-PCR. Bromodeoxyuridine uptake of mature adipocytes was detected. Adiponectin and leptin, and adipocyte-specific genes of adiponectin, leptin, and PPAR-gamma were detected in culture assembly, whereas the lipogenesis factor insulin (20 mU/ml) and inflammation-related agent TNF-alpha (2 nm) increased and decreased, respectively, all of their displays. Both spindle-shaped cell types with oil red O-positive lipid droplets and those with expression of MSC markers (CD105 and CD44) developed around the fragments. The data indicate that adipose tissue-organotypic culture retains unilocular structure, proliferative ability, and some functions of mature adipocytes, generating both immature adipocytes and CD105+/CD44+ MSC-like cells. This suggests that our method will open up a new way for studying both multiple cell types within adipose tissue and the cell-based mechanisms of obesity and metabolic syndrome.
Before they are used in the clinical setting, the effectiveness of artificially produced human-derived tissue-engineered medical products should be verified in an immunodeficient animal model, such as severe combined immunodeficient mice. However, small animal models are not sufficient to evaluate large-sized products for human use. Thus, an immunodeficient large animal model is necessary in order to properly evaluate the clinical efficacy of human-derived tissue-engineered products, such as artificial grafts. Here we report the development of an immunodeficient pig model, the operational immunodeficient pig (OIDP), by surgically removing the thymus and spleen, and creating a controlled immunosuppressive protocol using a combination of drugs commonly used in the clinical setting. We find that this model allows the long-term accommodation of artificial human vascular grafts. The development of the OIDP is an essential step towards a comprehensive and clinically relevant evaluation of human cell regeneration strategies at the preclinical stage.
Tumor budding is a major risk factor for T1 colorectal cancer. Quality control of the pathological diagnosis of budding is crucial, irrespective of the pathologist's experience. This study examines the interobserver variability according to pathologists' experience and evaluates the influence of cytokeratin (CK) immunostaining in the assessment of budding. Hematoxylin-eosin (HE) and CK-immunostained slides of 40 cases with T1 primary colorectal cancer were examined. Budding grades were individually evaluated by 12 pathologists who we categorized into three groups by their experience (expert, with >10 years of experience (n = 4), senior, with 5-10 years (n = 4), and junior, < 5 years (n = 4)). The results revealed a tendency for the more experienced pathologists to assign higher budding grades compared to the less-experienced pathologists. In the junior group, the interobserver variability obtained with HE slides was poor, but it was markedly improved in the evaluation using CK-immunostained slides. The benefit of CK immunostaining was only slight in the expert group. CK immunostaining would be useful when a pathologist is not experienced enough or does not have enough confidence in the assessment of budding.
The irradiated fibroblast-induced response of non-irradiated neighboring cells is called 'radiation-induced bystander effect', but it is unclear in non-irradiated human squamous cell carcinoma (SCC) cells. The present study shows that irradiated fibroblasts promoted the invasive growth of T3M-1 SCC cells, but not their apoptosis, more greatly than non-irradiated fibroblasts, using collagen gel invasion assay, immunohistochemistry and Western blot. The number of irradiated fibroblasts decreased to about 30% of that of nonirradiated fibroblasts, but irradiated fibroblasts increased the growth marker ki-67 display of SCC cells more greatly than non-irradiated fibroblasts. T he major malignant tumor of the oral cavity is squamous cell carcinoma (SCC). Radiotherapy has been frequently applied for patients with SCC.(1,2) In the cancer tissue, cancer cell-fibroblast interaction is critical for the behavior of SCC cells. (3,4) Despite the fact that both SCC cells and fibroblasts undergo irradiation by radiotherapy, little attention has been paid to effects of irradiated fibroblasts on the behavior of SCC cells. Previous reports have shown that irradiated fibroblasts are involved in carcinogenesis and invasive growth of both normal and abnormal epithelial cell types that are not exposed to irradiation.(5-7) This irradiated fibroblast-induced response of non-irradiated neighboring cells is called 'radiation-induced bystander effect'.(8,9) However, it is unclear whether irradiated fibroblasts may affect the behavior of non-irradiated SCC cells through bystander mechanism under cancer-stromal cell interaction.p53-binding protein-1 (53BP1), a DNA damage checkpoint protein, (10,11) forms irradiation-induced foci (IRIF) in nuclei in response to irradiation. 53BP1 functions in activation of ATM (mutated in ataxia-telangiectasia), which activates signaling pathways of DNA double-stranded break repair.(10) This response, which leads to cell-cycle delay, apoptosis and senescence, is critical for maintaining genomic stability.(11-13) Thus, IRIF formation of 53BP1 indicates a genomic instability and DNA damage. (10,12,14,15) However, it is unclear whether irradiated fibroblasts themselves enable non-irradiated SCC cells to form 53BP1 IRIF through the bystander mechanism.To address these critical issues, we examined the effects of irradiated fibroblasts on the apoptosis, growth and invasion of SCC cells using collagen gel invasion assay system. (3,4,(16)(17)(18)(19) Cellular growth-, invasion-and motility-related molecules such as c-Met, Ras, mitogen-activated protein kinase (MAPK) cascade proteins (Raf-1, MEK-1, and ERK-1/2), (20) matrix metalloproteinase-1, -9 (MMP-1, -9), (21) laminin 5 (22) and filamin A (23) were analyzed by immunohistochemistry and Western blot. Also, IRIF formation of the genomic instability marker 53BP1 was studied by immunofluorescence. Materials and MethodsCell lines. All procedures involving animal and human materials were performed in accordance with the regulations laid down by the ethical guidelines of ...
Adipose tissue exists in the gastric submucosa and subserosa. Thus, adipose tissue stromal cells (ATSCs), which include mesenchymal stem cells (MSCs), seem critical for the progression of gastric cancer but their interaction with the cancer cells is unknown. We demonstrated an interaction between these cells, using immunohistochemistry, Western blot and the collagen gel invasion assay system, in which the adenocarcinoma cells (well and poorly differentiated types, MKN28 and MKN45, respectively) were cultured on a ATSC-embedded or ATSC-non-embedded gel. ATSCs promoted the expression of the growth marker, proliferation cell nuclear antigen but inhibited that of the apoptosis marker, single-stranded DNA, in the cancer cell types. ATSCs accelerated the invasion of only MKN28 into the gel and promoted the expression of mitogen-activated protein kinase (MAPK, pERK-1/2) but decreased that of the molecularly targeted protein, HER2, in the cancer cells. ATSCs did not affect the expression of the prostaglandin biosynthetic enzyme cyclooxgenase-2 (COX-2) in the cancer cells. The COX-2 inhibitor celecoxib did not affect the morphology or invasion of the cancer cells. The cancer cell types in turn promoted the display of the myofibroblast marker, α-smooth muscle actin, whereas they decreased that of some MSC markers, e.g., CD44 and CD105, in ATSCs. The data suggest that (1) ATSCs influence the progression of gastric cancer by increasing their growth/invasion and decreasing their apoptosis through MAPK activation in a COX-2-independent way; (2) ATSCs adversely affect HER2-targeted therapy; (3) the cancer cells induce the cancer-associated myofibroblast phenotype in ATSCs.
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