ObjectiveTo investigate the growth characteristics of pancreatic cancer cells in the twodimensional culture system (monolayer) and threedimensional culture system (type Ⅰ collagen and extracellular matrix gel). MethodsThree pancreatic cancer cell lines (SW1990, PCT, and ASPC1) were cultured in monolayer, type Ⅰ collagen, and extracellular matrix gel, respectively. The growth patterns were observed, growth curves were detected by CCK8 test, and the cell cycle distributions were analyzed by propidium iodide staining. Results In the twodimensional culture system, cells grew in monolayer. In the type Ⅰ collagen and the ECM gel threedimensional culture system, cells formed multicellular spheroids (MCS), of which the growth rates were slower than those of the cells in monolayer. The proportions of S phase of SW1990, PCT, and ASPC1 cells in twodimensional culture system were significantly more than those in the type Ⅰ collagen on 4 d and 8 d 〔(29.6±3.0)% vs. (18.2±5.1)%, (33.6±2.1)% vs. (14.5±3.2)%, (33.1±1.8)% vs. (24.7±2.6)%; Plt;0.05〕, while the difference of proportion of three cell lines in G2/M phase was not different between twodimensional culture system and type Ⅰ collagen (Pgt;0.05). The proportions of G0/G1 phase of SW1990 and PCT cells cultured in the type Ⅰ collagen on 4 d and 8 d and ASPC1 cells cultured in the type Ⅰ collagen on 4 d were significant more than those cultured in twodimensional culture system (Plt;0.05). The proportions of S phase of ASPC1 cells and SW1990 cells cultured in the type Ⅰ collagen on 4 d were significant more than those cultured in the type Ⅰ collagen on 8 d (Plt;0.05). ConclusionsThe characteristics of pancreatic cancer cells in twodimensional and threedimensional culture systems are different. MCS culture system can better mimic the in vivo growth environment of cells in tumors.
Objective To investigate the possibility of repairing articular cartilage defects with the mesenchymal stem cells(MSCs) seeded type Ⅰ collagen-glycosaminoglycan(CG) matrices after being cultured with the chondrogenic differentiation medium. Methods The adherent population of MSCs from bone marrow of10 adult dogs were expanded in number to the 3rd passage. MSCs were seeded intothe dehydrothermal treatment (DHT) crosslinked CG matrices; 2×106 cells per 9mm diameter samples were taken. Chondrogenic differentiation was achieved by the induction media for 3 weeks. Cell contractility was evaluated by the measuement of the cell-mediated contraction of the CG matrices with time inculture.The in vitro formation of the cartilage was assessed by an assayemploying immunohistochemical identification of type Ⅱ collagen and by immunohistochemistry to demonstrate smooth muscle actin (SMA). The cells seededingCGs wereimplanted into cartilage defectsof canine knee joints. Twelve weeks after surgery, the dogs were sacrificed and results were observed. Results There was significant contraction of the MSCsseeded DHT crosslinked CG scaffolds cultured in the cartilage induction medium. After 21 days, the MSCseeded DHT crosslinked matrices were contracted to 64.4%±0.3%; histologically, the pores were found to be compressedandthe contraction coupled with the newly synthesized matrix, transforming the MSCsseeded CG matrix into a solid tissue in most areas. The type Ⅱ collagen staining was positive. The SMA staining was positive when these MSCs were seeded and the contracted CGs were implanted into the cartilage defects of the canine knee joints to repair the cartilage defects. The function of the knee joints recovered and the solid cartilaginous tissue filled the cartilage defects. Conclusion The results demonstrates that MSCs grown in the CG matrices can produce a solid cartilaginous tissuecontaining type Ⅱ collagen after being cultured with the chondrogenic differentiation medium and implanted into cartilage defects. We hypothesize that the following steps can be performed in the chondrogenic process: ①MSCs express SMA, resulting in matrix contraction, thus achieving a required cell density (allowing the cells to operate in a necessary society); ②Cells interact to form a type Ⅱ collagencontaining extracellular matrix (and cartilaginous tissue); ③Other factors, suchas an applied mechanical stress, may be required to form a mature cartilage with the normal architecture.
Objective To investigate the influence of collagen on the biomechanics strength of tissue engineering tendon. Methods All of 75 nude mice were madethe defect models of calcaneous tendons, and were divided into 5 groups randomly. Five different materials including human hair, carbon fibre (CF), polyglycolic acid (PGA), human hair and PGA, and CF and PGA with exogenous collagen were cocultured with exogenous tenocytes to construct the tissue engineering tendons.These tendons were implanted to repair defect of calcaneous tendons of right hind limb in nude mice as experimental groups, while the materials without collagenwere implanted to repair the contralateral calcaneous tendons as control groups. In the 2nd, 4th, 6th, 8th and 12th weeks after implantation, the biomechanicalcharacteristics of the tissue engineering tendon was measured, meanwhile, the changes of the biomechanics strength were observed and compared. Results From the 2nd week to the 4th week after implantation, the experimental groups were ber than the control groups in biomechanics, there was statistically significantdifference (Plt;0.05). From the 6th to 12th weeks, there was no statisticallysignificant difference between the experiment and control groups (Pgt;0.05). Positivecorrelation existed between time and intensity, there was statistically significant difference (Plt;0.05). The strength of materials was good in human hair,followed by CF, and PGA was poor. Conclusion Exogenous collagen can enhance the mechanics strength of tissue engineering tendon, and is of a certain effect on affected limb rehabilitation in early repair stages.
Osteoporosis is a degenerative disease characterized by decreased bone mass and destruction of bone microstructure. At present, previous studies have found that the structure and content of type Ⅰ collagen fibers are closely related to osteoporosis. However, there have been few studies on the prevention and treatment of osteoporosis using type Ⅰ collagen fibers as therapeutic targets. In this paper, the relationships between type Ⅰ collagen fibers and osteoporosis, biomechanics, bone matrix and bone strength are discussed. At the same time, the regulation of type Ⅰ collagen-related signaling pathways in osteoporosis is summarized, such as the signaling pathways of cathepsin K, transforming growth factor-β/Sma- and Mad-related protein, transforming growth factor-β/bone morphogenetic protein, c-jun N-terminal protein kinase and Wnt/β-catenin, in order to provide a new therapeutic direction for the prevention and treatment of osteoporosis.