Tag: 0-100

In 2019,Meat Science included an article by Paula, Marielle Maria de Oliveira; Haddad, Gabriela de Barros Silva; Rodrigues, Lorena Mendes; Benevenuto, Augusto Aloisio Junior; Ramos, Alcineia de Lemos Souza; Ramos, Eduardo Mendes. Related Products of 7647-14-5. The article was titled 《Effects of PSE meat and salt concentration on the technological and sensory characteristics of restructured cooked hams》. The information in the text is summarized as follows:

The effects of the use of normal and pale, soft, and exudative (PSE) meat on the technol. and sensorial quality of restructured cooked hams elaborated with different salt contents (0.8, 1.2, 1.6, 2.0, and 2.4%) were investigated. A low salt content implied (P < .05) high cooking loss (6.27 vs 3.25%), expressive moisture and C* values and low hardness. Products elaborated with PSE meat had (P < .05) lower cohesiveness, energy to fracture and hue tone color and higher springiness than did samples elaborated with normal meat. Salty taste perception was slightly higher for the PSE meat-based products, which were also preferred by the assessors when salt contents lower than 1.6% were used. It was concluded that when PSE meat was used, the addition of 1.2% salt was sufficient to maintain the technol. and sensory characteristics of the restructured cooked hams.Sodium chloride(cas: 7647-14-5Related Products of 7647-14-5) was used in this study.

Sodium chloride(cas: 7647-14-5) has been used for the preparation of tris buffered saline, phosphate buffered saline, MPM-2 (mitotic protein monoclonal 2) cell lysis buffer, immunoprecipitation wash buffer, LB (Luria-Bertani) media and dialysis buffer.Related Products of 7647-14-5

Referemce:
Chloride – Wikipedia,
Chlorides – an overview | ScienceDirect Topics

In 2019,Food Research International included an article by Rios-Mera, Juan D.; Saldana, Erick; Cruzado-Bravo, Melina L. M.; Patinho, Iliani; Selani, Miriam M.; Valentin, Dominique; Contreras-Castillo, Carmen J.. Application In Synthesis of Sodium chloride. The article was titled 《Reducing the sodium content without modifying the quality of beef burgers by adding micronized salt》. The information in the text is summarized as follows:

This study determined the effect of the incorporation of micronized salt on physicochem., yield and consumer’s sensory characteristics of beef burger. The micronized salt was obtained by sieving the com. salt in a 60-mesh stainless steel sieve. The com. (regular salt) and micronized salt presented differences in the mean size, size distribution and bulk d. Half of the amount of the micronized salt was mixed with pork back fat, and the other half was added to the meat batter in the beef burger manufacture A Pivot profile method was used with consumers to describe the sensory properties of the burger samples (ranging from 0.5% to 1.5% NaCl). The Pivot profile data revealed that treatments with 0.75% and 0.5% micronized salt were mainly characterized as dry, besides showing the highest cooking loss and diameter reduction However, beef burgers with 1.0% micronized salt and 1.5% regular salt had similar perceived salty taste. In terms of salt reduction, the results indicated that it would be possible to reduce salt from 1.5% to 1.0% when using micronized salt, without affecting the pH, color parameters, yield properties and some sensory characteristics of the burger, such as salty, tasty, juicy, fatty, and spicy. Therefore, this strategy promises great potential for industrial application in products that contain lipids in their composition, such as meat products. The results came from multiple reactions, including the reaction of Sodium chloride(cas: 7647-14-5Application In Synthesis of Sodium chloride)

Sodium chloride(cas: 7647-14-5) has been used for the preparation of tris buffered saline, phosphate buffered saline, MPM-2 (mitotic protein monoclonal 2) cell lysis buffer, immunoprecipitation wash buffer, LB (Luria-Bertani) media and dialysis buffer.Application In Synthesis of Sodium chloride

Referemce:
Chloride – Wikipedia,
Chlorides – an overview | ScienceDirect Topics

Quality Control of Sodium chlorideIn 2019 ,《Technoeconomic Analysis of Brackish Water Capacitive Deionization: Navigating Tradeoffs between Performance, Lifetime, and Material Costs》 was published in Environmental Science & Technology. The article was written by Hand, Steven; Guest, Jeremy S.; Cusick, Roland D.. The article contains the following contents:

Capacitive deionization (CDI), a class of electrochem. separation technologies, has been proposed as an energy-efficient brackish H2O desalination method. Previous studies have focused on improving capacity and energy consumption through material (e.g., ion-selective membranes [IEMs], charged C) and operational modifications, but there has been no anal. that directly links laboratory-scale exptl. performance to capital and operating costs of full-scale H2O production We developed a parameterized process model and technoeconomic anal. framework to project capital and operating costs at the million gal per day scale based on reported material and operational characteristics for constant current CDI with and without low ($20 m-2)- and high-cost ($100 m-2) IEMs. Using this framework, we conducted global sensitivity and uncertainty analyses for H2O price across the reported CDI design space. The operating constraints of brackish H2O desalination lead to capital costs 2-14 times greater than operating costs (particularly for MCDI). While MCDI outperforms CDI, IEM prices dictate the threshold at which MCDI is more cost-effective. The high relative capital costs highlight the importance of achieving system lifetimes at 2 years or beyond. Last, we set performance and areal cost benchmarks for material-based CDI performance and lifetime improvements. In the part of experimental materials, we found many familiar compounds, such as Sodium chloride(cas: 7647-14-5Quality Control of Sodium chloride)

Sodium chloride(cas: 7647-14-5) has been used for the preparation of tris buffered saline, phosphate buffered saline, MPM-2 (mitotic protein monoclonal 2) cell lysis buffer, immunoprecipitation wash buffer, LB (Luria-Bertani) media and dialysis buffer.Quality Control of Sodium chloride

Referemce:
Chloride – Wikipedia,
Chlorides – an overview | ScienceDirect Topics

Formula: ClNaIn 2019 ,《Global Sensitivity Analysis To Characterize Operational Limits and Prioritize Performance Goals of Capacitive Deionization Technologies in water desalination》 was published in Environmental Science & Technology. The article was written by Hand, Steven; Shang, Xia; Guest, Jeremy S.; Smith, Kyle C.; Cusick, Roland D.. The article contains the following contents:

Capacitive deionization (CDI) technologies couple electronic and ionic charge storage, enabling improved thermodn. efficiency of brackish desalination by recovering energy released during discharge. However, insight into CDI has been limited by discrete exptl. observations at low desalination depths (Δc, typically reducing influent salinity by 10 mM or less). The performance and sensitivity of 3 common CDI configurations [standard CDI, membrane CDI (MCDI), and flowable electrode CDI (FCDI)] were evaluated across the operational and material design landscape by varying 8 common input parameters (electrode thickness, influent concentration, c.d., electrode flow rate, specific capacitance, contact resistance, porosity, and fixed charge). All combinations of designs were evaluated for 2 influent concentrations with a calibrated and validated 1-dimensional (1-D) porous electrode model. Sensitivity analyses were carried out via Monte Carlo and Morris methods, focusing on 6 performance metrics. Across all performance metrics, high sensitivity was observed to input parameters which impact cycle length (current, resistance, and capacitance). Simulations demonstrated the importance of maintaining both charge and round-trip efficiencies, which limit the performance of CDI and FCDI, resp. Accounting for energy recovery, only MCDI was capable of operating at thermodn. efficiencies similar to reverse osmosis. In the experiment, the researchers used Sodium chloride(cas: 7647-14-5Formula: ClNa)

Sodium chloride(cas: 7647-14-5) has been used for the preparation of tris buffered saline, phosphate buffered saline, MPM-2 (mitotic protein monoclonal 2) cell lysis buffer, immunoprecipitation wash buffer, LB (Luria-Bertani) media and dialysis buffer.Formula: ClNa

Referemce:
Chloride – Wikipedia,
Chlorides – an overview | ScienceDirect Topics

COA of Formula: ClNaIn 2020 ,《Trace-Fe-Enhanced Capacitive Deionization of Saline Water by Boosting Electron Transfer of Electro-Adsorption Sites》 was published in Environmental Science & Technology. The article was written by Wang, Guizhi; Yan, Tingting; Zhang, Jianping; Shi, Liyi; Zhang, Dengsong. The article contains the following contents:

Capacitive deionization (CDI) is a promising water purification technol. However, the current ion adsorption capacity of CDI electrode materials is still an issue, which cannot meet the rapid demand of clean water from saline water. Herein, trace-Fe-enhanced removal of ions from saline water via CDI is presented. The ion adsorption capacity of CDI electrodes is up to 36.25 mg g-1 in a 500 mg L-1 NaCl media at 1.2 V together with stable regeneration property. In situ Raman and ex situ XPS measurements unravel the removal mechanism of ions from saline water, and the reinforced adsorption of ions is due to the introduction of trace Fe boosting electron transfer of electro-adsorption sites during the CDI process. This work presents a promising solution to highly efficient capacitive deionization for saline water. The experimental part of the paper was very detailed, including the reaction process of Sodium chloride(cas: 7647-14-5COA of Formula: ClNa)

Sodium chloride(cas: 7647-14-5) has been used for the preparation of tris buffered saline, phosphate buffered saline, MPM-2 (mitotic protein monoclonal 2) cell lysis buffer, immunoprecipitation wash buffer, LB (Luria-Bertani) media and dialysis buffer.COA of Formula: ClNa

Referemce:
Chloride – Wikipedia,
Chlorides – an overview | ScienceDirect Topics

The author of 《Plant cell-surface GIPC sphingolipids sense salt to trigger Ca2+ influx》 were Jiang, Zhonghao; Zhou, Xiaoping; Tao, Ming; Yuan, Fang; Liu, Lulu; Wu, Feihua; Wu, Xiaomei; Xiang, Yun; Niu, Yue; Liu, Feng; Li, Chijun; Ye, Rui; Byeon, Benjamin; Xue, Yan; Zhao, Hongyan; Wang, Hsin-Neng; Crawford, Bridget M.; Johnson, Douglas M.; Hu, Chanxing; Pei, Christopher; Zhou, Wenming; Swift, Gary B.; Zhang, Han; Vo-Dinh, Tuan; Hu, Zhangli; Siedow, James N.; Pei, Zhen-Ming. And the article was published in Nature (London, United Kingdom) in 2019. HPLC of Formula: 7647-14-5 The author mentioned the following in the article:

Salinity is detrimental to plant growth, crop production and food security worldwide. Excess salt triggers increases in cytosolic Ca2+ concentration, which activate Ca2+-binding proteins and upregulate the Na+/H+ antiporter in order to remove Na+. Salt-induced increases in Ca2+ have long been thought to be involved in the detection of salt stress, but the mol. components of the sensing machinery remain unknown. Here, using Ca2+-imaging-based forward genetic screens, we isolated the Arabidopsis thaliana mutant monocation-induced [Ca2+]i increases 1 (moca1), and identified MOCA1 as a glucuronosyltransferase for glycosyl inositol phosphorylceramide (GIPC) sphingolipids in the plasma membrane. MOCA1 is required for salt-induced depolarization of the cell-surface potential, Ca2+ spikes and waves, pNa+/H+ antiporter activation, and regulation of growth. Na+ binds to GIPCs to gate Ca2+ influx channels. This salt-sensing mechanism might imply that plasma-membrane lipids are involved in adaptation to various environmental salt levels, and could be used to improve salt resistance in crops. The results came from multiple reactions, including the reaction of Sodium chloride(cas: 7647-14-5HPLC of Formula: 7647-14-5)

Sodium chloride(cas: 7647-14-5) has been used for the preparation of tris buffered saline, phosphate buffered saline, MPM-2 (mitotic protein monoclonal 2) cell lysis buffer, immunoprecipitation wash buffer, LB (Luria-Bertani) media and dialysis buffer.HPLC of Formula: 7647-14-5

Referemce:
Chloride – Wikipedia,
Chlorides – an overview | ScienceDirect Topics

In 2019,Environmental Science & Technology included an article by Han, Jinlong; Yan, Tingting; Shen, Junjie; Shi, Liyi; Zhang, Jianping; Zhang, Dengsong. Quality Control of Sodium chloride. The article was titled 《Capacitive Deionization of Saline Water by Using MoS2-Graphene Hybrid Electrodes with High Volumetric Adsorption Capacity》. The information in the text is summarized as follows:

Capacitive deionization (CDI) has received wide attention as an emerging water treatment technol. due to its low energy consumption, low cost and high efficiency. However, the conventional C electrode materials for CDI have low densities, which occupy large volumes and are disadvantageous for use in limited space (e.g., in household or on offshore platforms). In order to miniaturize the CDI device, it is quite urgent to develop high volumetric adsorption capacity (VAC) electrode materials. To overcome this issue, we rationally designed and originally developed high VAC MoS2-graphene hybrid electrodes for CDI. It is interesting that MoS2-graphene hybrid electrode has a much higher NaCl volumetric adsorption capacity of 14.3 mg/cm3 with a gravimetric adsorption capacity of 19.4 mg/g. It has been demonstrated that the adsorption capacity is significantly enhanced due to the rapid ion transport of MoS2 and high elec. conductivity of graphene. In-situ Raman spectra and high-angle annular dark-field scanning transmission electron microscopy tests demonstrated a favorable Faradaic reaction, which was crucial to enhancing the NaCl volumetric adsorption capacity of MoS2-graphene hybrid electrode. This work opens a new avenue for miniaturizing future CDI devices. The experimental part of the paper was very detailed, including the reaction process of Sodium chloride(cas: 7647-14-5Quality Control of Sodium chloride)

Sodium chloride(cas: 7647-14-5) has been used for the preparation of tris buffered saline, phosphate buffered saline, MPM-2 (mitotic protein monoclonal 2) cell lysis buffer, immunoprecipitation wash buffer, LB (Luria-Bertani) media and dialysis buffer.Quality Control of Sodium chloride

Referemce:
Chloride – Wikipedia,
Chlorides – an overview | ScienceDirect Topics

《Dissecting the Role of Substrate on the Morphology and Separation Properties of Thin Film Composite Polyamide Membranes: Seeing Is Believing》 was published in Environmental Science & Technology in 2020. These research results belong to Peng, Lu Elfa; Yao, Zhikan; Yang, Zhe; Guo, Hao; Tang, Chuyang Y.. COA of Formula: ClNa The article mentions the following:

Recent studies show that the surface morphol. of a thin film composite (TFC) polyamide membrane depends strongly on its porous substrate. Nevertheless, the underlining mechanisms and the effects on membrane separation performance remain controversial. To dissect the exact role of pore properties, we synthesized TFC polyamide membranes on polycarbonate substrates with cylindrical track-etched pores (PCTE) of well-defined pore size ranging from 10 to 800 nm. Leaf-like roughness features were most prominent for polyamide films formed on substrates of intermediate pore sizes (80 and 100 nm). Smaller pores inhibited leaf-like features as a result of insufficient storage of m-phenylenediamine (MPD) monomers for the interfacial reaction, whereas larger pores resulted in diminished surface roughness due to the lack of confinement to the interfacially degassed nanobubbles. Substrate porosity plays a critical role on membrane water permeability, while smaller pores with greater pore d. are favored to improve membrane rejection. TFC polyamide membranes prepared on sponge-like polyethersulfone and polysulfone substrates exhibit better water permeability and salt rejection compared to the PCTE-TFC membranes, thanks to the simultaneously enhanced confinement and MPD storage effects. The mechanistic insights gained in this study reveals the huge potential of substrate design towards high performance TFC RO membranes. In the part of experimental materials, we found many familiar compounds, such as Sodium chloride(cas: 7647-14-5COA of Formula: ClNa)

Sodium chloride(cas: 7647-14-5) has been used for the preparation of tris buffered saline, phosphate buffered saline, MPM-2 (mitotic protein monoclonal 2) cell lysis buffer, immunoprecipitation wash buffer, LB (Luria-Bertani) media and dialysis buffer.COA of Formula: ClNa

Referemce:
Chloride – Wikipedia,
Chlorides – an overview | ScienceDirect Topics

The author of 《Osmotically and Thermally Isolated Forward Osmosis-Membrane Distillation (FO-MD) Integrated Module》 were Kim, Youngjin; Li, Sheng; Francis, Lijo; Li, Zhenyu; Linares, Rodrigo Valladares; Alsaadi, Ahmad S.; Abu-Ghdaib, Muhannad; Son, Hyuk Soo; Amy, Gary; Ghaffour, Noreddine. And the article was published in Environmental Science & Technology in 2019. COA of Formula: ClNa The author mentioned the following in the article:

The authors propose a novel module design to integrate forward osmosis (FO) and membrane distillation (MD). The two processes are sealed in one module and operated simultaneously, making the system compact and suitable for a wide range of applications. To evaluate the system under large-scale module operating conditions, FO and MD experiments were performed sep. The effect of draw solution (DS) temperature on the FO performance was 1st assessed in terms of flux, reverse salt flux (RSF), and specific RSF (SRSF). While a higher DS temperature resulted in an increased RSF, a higher FO flux was achieved, with a lower SRSF. The influence of DS concentration on the MD performance was then studied in terms of flux and salt rejection. High DS concentration had a slightly neg. impact on MD water vapor flux, but the MD membrane was a complete barrier for DS salts. The FO-MD integrated module was simulated based on mass balance equations. Initial DS (MD feed) flow rate and concentration are the most important factors for stable operation of the integrated module. Higher initial DS flow rate and lower initial DS concentration can achieve a higher permeate rate of the FO-MD module. The experimental part of the paper was very detailed, including the reaction process of Sodium chloride(cas: 7647-14-5COA of Formula: ClNa)

Sodium chloride(cas: 7647-14-5) has been used for the preparation of tris buffered saline, phosphate buffered saline, MPM-2 (mitotic protein monoclonal 2) cell lysis buffer, immunoprecipitation wash buffer, LB (Luria-Bertani) media and dialysis buffer.COA of Formula: ClNa

Referemce:
Chloride – Wikipedia,
Chlorides – an overview | ScienceDirect Topics

The author of 《Membrane-Free Hybrid Capacitive Deionization System Based on Redox Reaction for High-Efficiency NaCl Removal》 were Wang, Shiyong; Wang, Gang; Wu, Tingting; Li, Changping; Wang, Yuwei; Pan, Xin; Zhan, Fei; Zhang, Yunqi; Wang, Shuaifeng; Qiu, Jieshan. And the article was published in Environmental Science & Technology in 2019. Synthetic Route of ClNa The author mentioned the following in the article:

Capacitive deionization (CDI) is a promising technol. for desalination due to its advantages of low driven energy and environmental friendliness. However, the ion removal capacity (IRC) of CDI is insufficient for practical application because such a capacity is limited by the available surface area of the C electrode for ion absorption. Thus, the development of a novel desalination technol. with high IRC and low cost is vital. Here, a membrane-free hybrid capacitive deionization system (HCDI) with hollow C@MnO2 (HC@MnO2) to capture Na via redox reaction and hollow C sphere with net pos. surface charges (PHC) for chloride adsorption is introduced. The as-obtained HC@MnO2 with unique structure and high conductivity can improve the use of MnO2 pseudocapacitive electrodes. Meanwhile, the PHC can selectively adsorb Cl- and prevent the adsorption of Na+ due to electrostatic repulsion. As expected, the membrane-free HCDI system demonstrates excellent desalination performance. The system’s IRC and maximum removal rate are 30.7 mg g-1 and 7.8 mg g-1 min-1, resp. Also, the proposed system has a low cost because of the absence of expensive ion exchange membranes (IEM), which is suitable for practical application. The excellent performance of this HCDI makes it a promising desalination technol. for future use. After reading the article, we found that the author used Sodium chloride(cas: 7647-14-5Synthetic Route of ClNa)

Sodium chloride(cas: 7647-14-5) has been used for the preparation of tris buffered saline, phosphate buffered saline, MPM-2 (mitotic protein monoclonal 2) cell lysis buffer, immunoprecipitation wash buffer, LB (Luria-Bertani) media and dialysis buffer.Synthetic Route of ClNa

Referemce:
Chloride – Wikipedia,
Chlorides – an overview | ScienceDirect Topics