Fabricated microscale tissues that replicate in vivo architectures have shown huge potential in regenerative medicine and drug discovery. Owing to the spatial organization of cell-encapsulated hydrogel microstructures, three-dimensional (3D) tissue structures have been broadly applied as novel pathological or pharmacological models. However, the spatial reorganization of arbitrary microstructures with tissue-specific shapes into 3D in vitro microtissues that mimic the physiological morphology and nutrient diffusion of native tissues presents a major challenge. Here, we develop a versatile method that engineers permeable 3D microtissues into tissue-specific microscopic architectures. The customized, arbitrarily shaped hollow micromodules are prepared by photocopolymerizing poly(ethylene glycol) diacrylate (PEGDA) with acryloyl-PEG-Arg-Gly-Asp-Ser (RGDS). These micromodules are spatially reorganized and self-aligned by a facile assembly process based on hydrodynamic interactions, forming an integrated geometry with tissue-specific morphology and a vessel-mimetic lumen. The RGD linkages create cell-adhesive structures in the PEGDA hydrogel, greatly increasing the long-term cell viability in 3D microtissue cultures. Meanwhile, the mechanical properties for fast cell spreading inside the microstructures can be optimized by modulating the PEGDA concentration. The 3D microtissues, with their different geometries and permeable tubular lumens, maintained cell proliferation over 14 days. The cell viabilities exceeded 98%. We anticipate that our method will regenerate complex tissues with physiological importance in future tissue engineering.
This study makes two important contributions to the existing literature. On the one hand, it investigated tourism impacts as perceived by residents in two important historic cities in India (Puri and Varanasi). On the other hand, it analysed residents' perceived tourism impacts in relation to their evaluation of stage of destination development. A survey collected valid responses from 570 local residents, who display a high level of agreement concerning the positive economic and sociocultural contributions of tourism. Despite environmental concerns, respondents wish to attract more tourists and further develop infrastructure for tourism. Residents who perceive tourism to be in the development and full development/stagnation stages agree more strongly than those who consider tourism to be in the beginning stage that it increases employment opportunities and seasonality and stipulates cultural activities. In contrast, those who think tourism is in the beginning stage are more concerned about environmental pollution and thus advocate restrictions on the industry. Implications are suggested for tourism research, policy making, and planning.
A noncontact method that can achieve immobilization, transportation, and rotation in the microscale is desired in biological micromanipulation. A multifunctional noncontact micromanipulation method is proposed here based on a vibration‐generated whirling flow. Resonance of a cantilever structure is utilized to extend the straight vibration of a single piezo actuator to the 2D circular vibration of a micropipette. The circular vibration in fluids can generate the whirling flow featured with low pressure in the core area and flow velocity gradient. The low pressure can immobilize the objects nearby and transport them together with the micropipette, and the flow velocity gradient is utilized to form a torque to rotate the immobilized object. Experiments of the microbeads are conducted to evaluate the claimed functions and quantify the key parameters that influence the rotation velocity. The cell spheroid is immobilized and rotated for 3D observation, and by assessing the viability of the cells containing in the spheroid, the proposed method is proved noninvasive to living cells. Finally, another important application in operations of mouse egg cells is shown, which indicates that the proposed method is a potential valuable tool in biological micromanipulation.
The saturation flow rate is a fundamental parameter to measure the intersection capacity and time the traffic signals. However, it is revealed that traditional methods which are mainly developed using the average value of observed queue discharge headways to estimate the saturation headway might lead to underestimate saturation flow rate. The goal of this paper is to study the stochastic nature of queue discharge headways and to develop a more accurate estimate method for saturation headway and saturation flow rate. Based on the surveyed data, the characteristics of queue discharge headways and the estimation method of saturated flow rate are studied. It is found that the average value of queue discharge headways is greater than the median value and that the skewness of the headways is positive. Normal distribution tests were conducted before and after a log transformation of the headways. The goodness-of-fit test showed that for some surveyed sites, the queue discharge headways can be fitted by the normal distribution and for other surveyed sites, the headways can be fitted by lognormal distribution. According to the queue discharge headway characteristics, the median value of queue discharge headways is suggested to estimate the saturation headway and a new method of estimation saturation flow rates is developed.
In the last decade, the integration of microfluidic devices and multiple actuation technologies at the microscale has greatly contributed to the progress of related fields. In particular, microbubbles are playing...
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