An integrated practical implementation of continuous aqueous two‐phase systems for the recovery of human IgG: From the microdevice to a multistage bench‐scale mixer‐settler device

Aqueous two‐phase systems (ATPS) are a liquid‐liquid extraction technology with clear process benefits; however, its lack of industrial embracement is still a challenge to overcome. Antibodies are a potential product to be recovered by ATPS in a commercial context. The objective of this work is to present a more integral approach of the different isolated strategies that have arisen in order to enable a practical, generic implementation of ATPS, using human immunoglobulin G (IgG) as experimental model. A microfluidic device is used for ATPS parameters preselection for product recovery. ATPS were continuously operated in a mixer‐settler device in one stage, multistage and multistage with recirculation configuration. Single‐stage pure IgG extraction with a polyethylene glycol (PEG) 3350‐phophates ATPS within continuous operation allowed a 65% recovery. Further implementation of a multistage platform promoted a higher particle partitioning reaching a 90% recovery. The processing of IgG from a cell supernatant culture harvest in a multistage system with top phase recirculation resulted in 78% IgG recovery in bottom phase. This work conjugates three not widely spread methodologies for ATPS: microfluidics, continuous and multistage operation.     

显微镜下减压联合前路Zero-P治疗颈椎病的早期临床疗效分析

目的:探讨前路颈椎显微镜辅助下精准减压联合前路椎间隙Zero-P融合器置入治疗颈椎病的早期临床疗效。方法:回顾性分析2016年6月至2018年1月我院收治的43例颈椎病患者,处理节段共73个;患者均行显微镜辅助颈椎前路减压、髓核切除、Zero-P置入融合内固定术。记录患者手术节段、手术时间,术中失血量及并发症。手术前,术后1个月、3个月、6个月、末次随访时的颈部及上肢疼痛视觉模拟评分(Visual Analogue Scale,VAS)、颈部日本骨科协会评分(Japanese Orthopedic Association,JOA)和颈椎残障功能指数(Neck Disability Index,NDI),并采用配对t检验对不同时间点的评分进行分析,评估临床疗效。并同期行颈椎X线、CT及MRI检查,测量和评估椎间隙高度、颈椎Cobb角的改变情况和邻近节段异位骨化形成(Adjacent Level Ossification Development,ALOD)。结果:所有患者术后均获得随访,随访时间12-18个月,平均(14.9±2.2)个月。平均手术时间(82.2±20.9)min,失血量(91.5±33.7) m L;未发生神经和血管损伤等严重并发症。与术前相比,患者术后1个月、3个月、6个月及末次随访时的VAS评分、JOA评分、NDI评分、椎间隙高度及Cobb角均明显改善,差异有统计学意义(P0.05)。但术后随访时间点比较,差异无统计学意义(P0.05)。术后出现轻度吞咽困难2例,中度和重度吞咽困难各1例。随访期间,所有患者均获椎间骨性融合,未发生Zero-P融合器松动、滑脱或断裂,椎体未出现继发性骨折。结论:显微镜辅助颈椎前路椎间盘切除、Zero-P融合器置入治疗颈椎病,能够精准的去除神经脊髓组织的压迫,术后短期和中期临床疗效良好,同时显微镜下止血、术中出血少;视野清晰、手术安全性高。     

尖吻蝮人工养殖灌喂技术研究

目的探讨采用灌喂器人工灌喂尖吻蝮技术的可行性。方法采用湖南京湘源蛇类养殖有限公司自主研制的灌喂器人工灌喂尖吻蝮,观察记录随机抽取的30条尖吻蝮幼蛇及30条尖吻蝮成蛇在机器灌喂后每条幼蛇的体重数据,每3个月测量1次,观察12个月统计尖吻蝮的体重增长情况,并与常规灌喂方法饲养的尖吻蝮进行比较。结果灌喂器饲养的尖吻蝮幼蛇成活率为86.67%,平均体重达（482.39±40.19）g;灌喂器饲养的尖吻蝮成蛇成活率为96.67%,平均体重达（1346.13±117.51）g。而同期常规灌喂技术饲养的尖吻蝮幼蛇全部死亡,尖吻蝮成蛇成活率为76.67%,平均体重（878.56±82.39）g。结论人工灌喂器饲养的尖吻蝮幼蛇及成蛇的体重增长快速,成活率高,值得推广。     

Improving sodium dodecyl sulfate polyacrylamide gel electrophoresis detection of low-abundance protein samples by rapid freeze centrifugation

This work presents a rapid and simple freeze centrifugation method to concentrate dilute protein solutions for detection by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS–PAGE) Coomassie blue staining. Moreover, a simple way to assemble a cryoconcentration device is presented, and its use is discussed. Commercial purified protein standard and an enzyme with high fructosyltransferase (FTase) activity, coming from target fractions obtained by chromatographic separation, were used as an example. FTase, coming directly from the chromatographic fractions, was difficult to view through SDS–PAGE analysis; however, it was easily visualized, and its activity was enhanced, after the application of the freeze centrifugation protocol presented here.     

Role of Microstructure in Oxygen Induced Photodegradation of Methylammonium Lead Triiodide Perovskite Films

This paper investigates the impact of microstructure on the degradation rate of methylammonium lead triiodide (MAPbI₃) perovskite films upon exposure to light and oxygen. By comparing the oxygen induced degradation of perovskite films of different microstructure–fabricated using either a lead acetate trihydrate precursor or a solvent engineering technique–it is demonstrated that films with larger and more uniform grains and better electronic quality show a significantly reduced degradation compared to films with smaller, more irregular grains. The effect of degradation on the optical, compositional, and microstructural properties of the perovskite layers is characterized and it is demonstrated that oxygen induced degradation is initiated at the layer surface and grain boundaries. It is found that under illumination, irreversible degradation can occur at oxygen levels as low as 1%, suggesting that degradation can commence already during the device fabrication stage. Finally, this work establishes that improved thin‐film microstructure, with large uniform grains and a low density of defects, is a prerequisite for enhanced stability necessary in order to make MAPbI₃ a promising long lived and low cost alternative for future photovoltaic applications.     

Rapid synthesis of BaMoO4:Eu3+ red phosphors using microwave irradiation

This study synthesized BaMoO4:Eu³⁺ red phosphors using the microwave method. In addition, the phase composition, morphology, and luminescence properties of the red phosphors were characterized using X-ray diffraction, field-scanning electron microscopy, and photoluminescence spectroscopy. The results revealed that doping red phosphors with different concentrations of Eu³⁺ does not change the crystal structure of the matrix material. The BaMoO₄:Eu³⁺ phosphors exhibited micron-scale irregular polyhedra, which could be excited by ultraviolet light with a wavelength of 395 nm to induce red-light emission. The optimal dosage of Eu³⁺ was 0.08, and the chromaticity coordinates of BaMoO₄:0.08Eu³⁺ phosphors were (0.5869, 0.3099). White light-emitting diode (w-LED) devices manufactured by using a combination of BaMoO₄:0.08Eu³⁺ phosphor and commercially available phosphors exhibited good white-light emission under the excitation of an ultraviolet chip. The BaMoO₄:0.08Eu³⁺ red phosphors that rapidly synthesized under the microwave field are expected to be used in w-LED devices.     

Environmental sustainability of orthopedic devices produced with powder bed fusion

Additive manufacturing consists in melting metallic powders to produce objects from 3D data, layer upon layer. Its industrial applications range from automotive, biomedical (e.g., prosthetic implants for dentistry and orthopedics), aeronautics and others. This study uses life cycle assessment to evaluate the possible improvement in environmental performance of laser‐based powder bed fusion additive manufacturing systems on prosthetic device production. Environmental impacts due to manufacturing, use, and end of life of the designed solution were assessed. In addition, two powder production technologies, gas atomization (GA) and plasma atomization (PA), were compared in order to establish the most sustainable one. Production via traditional subtractive technologies and the additive manufacturing production were also compared. 3D building was found to have a significant environmental advantage compared to the traditional technology. The powder production process considerably influences on a damage point of view the additive manufacturing process; however, its impact can be mitigated if GA powders are employed.     

Characterisation and simulation of an active microvalve for glaucoma

Glaucoma drainage device (GDD) has the potential to eliminate hypotony but still suffers from poor flow control and fibrosis. The ideal shunt should change its hydraulic resistance to achieve the desired intraocular pressure (IOP). In this study, the characterisation of a preliminary design of a new GDD is presented. This is activated by means of a diaphragm, which is actuated by conducting polymers. The valve can be manufactured employing microelectromechanical system technology by soft lithography. The characterisation process is performed by numerical simulation using the finite element method, considering the coupling between the fluid and the structure (diaphragm) obtaining the hydraulic resistance for several positions of the diaphragm. To analyse the hydraulic system of the microvalve implanted in a human eye, an equivalent circuit model was used. The parameters of the equivalent circuit model were obtained from numerical simulation. The hydraulic resistance of the designed GDD varies in the range of 13.08–0.36 mmHg min/μl compared with 3.38–0.43 mmHg min/μl for the Ahmed valve. The maximum displacement of the diaphragm in the vertical direction is 18.9 μm, and the strain in the plane is 2%. The proposed preliminary design allows to control the IOP by varying the hydraulic resistance in a greater range than the existing passive valves, and the numerical simulation facilitates the characterisation and the improvement of the design before its construction, reducing time and costs.     

Integration of geometric separation mechanisms by implementing curved constrictions in a biochip microchannel fluidic separator

This paper investigates the effectiveness of using curved constrictions in the bifurcation region of T-type fluid separators for promoting flow development in the intervals between bifurcations. A design of biofluid separator is proposed and a mathematical analysis and a numerical simulation of the blood flow in microchannels are conducted. The design is based on a modification of an existing T-shaped biochip device which consists of a main channel and a series of perpendicularly positioned side channels. By means of bifurcation effect, the blood is separated into plasma concentration flow from the side channels and blood cell concentration flow from the main channel. In this design, curved constrictions are inserted between bifurcations to replace the original straight channel section, so that the constriction and curved channel effects can be induced apart from the existing bifurcation effect. The mathematical analysis is aimed to the flow field and shear stress of the blood fluid in the microchannel geometries employed in the current design, including bifurcation, constriction and curved channel. The numerical simulation and mathematical analysis result in agreed conclusions, giving some insights into the importance of the relevant geometries in promoting biofluid separation. The main results can be summarised as follows: (i) the constrictions can largely increase the shear stress by the ratio of square of the reduction of the sections between the constriction and parent main channel. (ii) The curved channel intervals can induce centrifugal force, smoothly transit the flow field and increase the chances depleting fluid from the cell-free layer. (iii) The thickness of the boundary layer skimmed into the side channels from the main channel is decreased in this design and can be controlled, falling into the cell-free layer region by adjusting the geometry of the side channels.