Relative humidity at 37uC, with a change of medium every 48 h.Evaluation of MedChemExpress EAI045 seeding efficiencyTwenty four hours after seeding, the seeding efficiency of each group was analyzed, which was defined as the ratio of the number of cells existing in the scaffold to the number of cells added originally to the scaffold. After transferring bone substitutes to other wells, non-adherent cells in the well were collected by rinsing repeatedly with DMEM/F12 medium. Then, the cells attached to well bottom were digested with 0.25 trypsin plus 0.01 EDTA and collected. The cells in the supernatant and those adhering to the bottom of the well were separately counted by hemocytometer. The sum of these two portion of cells was recorded as `remaining cell number’ in each well. The seeding efficiency was calculated by: (initial cell number-remaining cell number)/initial cell number.Scaffold preparationCubes of human demineralized cancellous bone matrix (DBM, 4 mm64 mm64 mm) were obtained from the tissue bank of our university and used as the Duvelisib scaffolds in this study. The porosity of DBM is 70 and the pore size is 300?00 mm. The DBM was prepared by a series process, as 25331948 previously described by Tan et al. [18].Cell viabilityThe viabilities of cells in scaffolds were assayed at various time points (8 h, 16 h, 24 h, 48 h, and 3?4 d after seeding). The cellscaffold constructs were removed from their medium, rinsed with phosphate buffered saline (PBS), and placed in a 96-well culture plate. Cell viability was determined as reported [19]. Cell counting kit-8 (CCK-8, 20 mL/well, Dojindo Chemical Institute, Kumamoto, Japan) was added to each well, followed by further culture for 3 h (5 CO 2, 37uC, 100 relative humidity). Then, the constructs were removed, and the optical density of each well at 450 nm was measured with an ELISA reader (reference wavelength: 655 nm), with cell-free DMB scaffolds as the controls.Construction of implants and GroupingFour kinds of bone substitutes were constructed based on different approach of seeding and culture (Table 1). Hydrodynamic seeding and hydrodynamic culture (group A): Fifty DBM scaffolds and 5.06107 MSCs were added into the highaspect ratio vessel of a rotary cell culture system (Synthecon RCCS-1, Houston, TX, USA). The vessel was filled with 50 ml of DME/F12 culture medium (Hyclone, Logan, UT, USA) and degassed. The rotation speed was adjusted daily (18?4 rpm) to ensure that the rotating trajectories of the scaffolds would not collide with the vessel wall or converge to the center. The rotary culture system was incubated in an atmosphere of 5 CO2 and 100 relative humidity at 37uC, with daily adjustment of rotation speed and a change of medium every 48 h. Hydrogel-assisted seeding and hydrodynamic culture (group B): The fibrin glue (25 mg/ml, Tissucol, Baxter, Austria) wasALP activityThe ALP activities were measured at various time points (2, 4, 6, 8, 10, 12, 14 and 16 d) after seeding. The cell-scaffold constructs were rinsed twice with PBS and then lysed with 0.2 Triton X100 (Sigma, USA). The lysate was centrifuged at 600 g for 5 min and the supernatant was collected and incubated for 15 min (5 CO2, 37uC, 100 relative humidity). The absorbance at 405 nm was measured on a microplate reader and converted into the ALP activity against a standard curve, which was established based on the reaction of 10 ml of a p-nitrophenyl solution (Wako) andEffects of Initial Cell and Hydrodynamic CultureTable 1. Summary of in vitro.Relative humidity at 37uC, with a change of medium every 48 h.Evaluation of seeding efficiencyTwenty four hours after seeding, the seeding efficiency of each group was analyzed, which was defined as the ratio of the number of cells existing in the scaffold to the number of cells added originally to the scaffold. After transferring bone substitutes to other wells, non-adherent cells in the well were collected by rinsing repeatedly with DMEM/F12 medium. Then, the cells attached to well bottom were digested with 0.25 trypsin plus 0.01 EDTA and collected. The cells in the supernatant and those adhering to the bottom of the well were separately counted by hemocytometer. The sum of these two portion of cells was recorded as `remaining cell number’ in each well. The seeding efficiency was calculated by: (initial cell number-remaining cell number)/initial cell number.Scaffold preparationCubes of human demineralized cancellous bone matrix (DBM, 4 mm64 mm64 mm) were obtained from the tissue bank of our university and used as the scaffolds in this study. The porosity of DBM is 70 and the pore size is 300?00 mm. The DBM was prepared by a series process, as 25331948 previously described by Tan et al. [18].Cell viabilityThe viabilities of cells in scaffolds were assayed at various time points (8 h, 16 h, 24 h, 48 h, and 3?4 d after seeding). The cellscaffold constructs were removed from their medium, rinsed with phosphate buffered saline (PBS), and placed in a 96-well culture plate. Cell viability was determined as reported [19]. Cell counting kit-8 (CCK-8, 20 mL/well, Dojindo Chemical Institute, Kumamoto, Japan) was added to each well, followed by further culture for 3 h (5 CO 2, 37uC, 100 relative humidity). Then, the constructs were removed, and the optical density of each well at 450 nm was measured with an ELISA reader (reference wavelength: 655 nm), with cell-free DMB scaffolds as the controls.Construction of implants and GroupingFour kinds of bone substitutes were constructed based on different approach of seeding and culture (Table 1). Hydrodynamic seeding and hydrodynamic culture (group A): Fifty DBM scaffolds and 5.06107 MSCs were added into the highaspect ratio vessel of a rotary cell culture system (Synthecon RCCS-1, Houston, TX, USA). The vessel was filled with 50 ml of DME/F12 culture medium (Hyclone, Logan, UT, USA) and degassed. The rotation speed was adjusted daily (18?4 rpm) to ensure that the rotating trajectories of the scaffolds would not collide with the vessel wall or converge to the center. The rotary culture system was incubated in an atmosphere of 5 CO2 and 100 relative humidity at 37uC, with daily adjustment of rotation speed and a change of medium every 48 h. Hydrogel-assisted seeding and hydrodynamic culture (group B): The fibrin glue (25 mg/ml, Tissucol, Baxter, Austria) wasALP activityThe ALP activities were measured at various time points (2, 4, 6, 8, 10, 12, 14 and 16 d) after seeding. The cell-scaffold constructs were rinsed twice with PBS and then lysed with 0.2 Triton X100 (Sigma, USA). The lysate was centrifuged at 600 g for 5 min and the supernatant was collected and incubated for 15 min (5 CO2, 37uC, 100 relative humidity). The absorbance at 405 nm was measured on a microplate reader and converted into the ALP activity against a standard curve, which was established based on the reaction of 10 ml of a p-nitrophenyl solution (Wako) andEffects of Initial Cell and Hydrodynamic CultureTable 1. Summary of in vitro.
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