Control of electrothermal heating during regeneration of activated carbon fiber cloth

Electrothermal swing adsorption (ESA) of organic gases generated by industrial processes can reduce atmospheric emissions and allow for reuse of recovered product. Desorption energy efficiency can be improved through control of adsorbent heating, allowing for cost-effective separation and concentration of these gases for reuse. ESA experiments with an air stream containing 2000 ppm(v) isobutane and activated carbon fiber cloth (ACFC) were performed to evaluate regeneration energy consumption. Control logic based on temperature feedback achieved select temperature and power profiles during regeneration cycles while maintaining the ACFC's mean regeneration temperature (200 °C). Energy requirements for regeneration were independent of differences in temperature/power oscillations (1186-1237 kJ/mol of isobutane). ACFC was also heated to a ramped set-point, and the average absolute error between the actual and set-point temperatures was small (0.73%), demonstrating stable control as set-point temperatures vary, which is necessary for practical applications (e.g., higher temperatures for higher boiling point gases). Additional logic that increased the maximum power application at lower ACFC temperatures resulted in a 36% decrease in energy consumption. Implementing such control logic improves energy efficiency for separating and concentrating organic gases for post-desorption liquefaction of the organic gas for reuse.     

Continuous Manufacturing of Active Pharmaceutical Ingredients: Current Trends and Perspectives

The pharmaceutical industry has traditionally employed batch processing as a means of synthesizing active pharmaceutical ingredients (APIs) on a commercial scale. Batch manufacturing enables API synthesis in large quantities in order to meet regulations. Yet, this strategy remains cumbersome, is labor-intensive, and creates complex logistical networks. In recent decades, batch API processing has gradually eroded American economic competitiveness and has led to the offshoring of API manufacturing from the United States. Today it is estimated that +80% of APIs are manufactured overseas.^[1] Meanwhile, disruptions from the Coronavirus Disease (SARS-CoV-2) have exacerbated weaknesses in the global supply chain, culminating with widespread shortages of critical life-saving drugs.^[2] These shortages have emphasized the importance of reshoring drug manufacturing to the U.S. and fostered a regulatory landscape that seeks advanced methods of API manufacturing in order to bolster America's supply chain resiliency.^[3] Recently, increased attention has been directed towards continuous drug manufacturing to enable nonstop API production within modular stand-alone flow systems. Continuous manufacturing (CM) facilitates modular automation, offers new avenues towards process intensification, and even enables in-line analytical monitoring from raw materials to packaged products. This strategy offers better conversion, increased safety, reduced waste, and overall cost savings versus traditional batch-style processing. The rise of advanced API manufacturing, coupled with the current regulatory landscape, offers a rare window of opportunity to convert traditional batch pharmaceutical processes into continuous, streamlined production systems to on-shore API manufacturing and eliminate drug shortages. This review will outline the current state-of-the-art in the CM of APIs and will highlight the translation of chemistry and unit operations from batch processes to modular CM systems.     

Updated occurrence of 3-monochloropropane-1,2-diol esters (3-MCPD) and glycidyl esters in infant formulas purchased in the United States between 2017 and 2019

ABSTRACT

Fatty acid esters of 3-monochloropropane-1,2-diol (3-MCPD) and glycidol are potentially carcinogenic and/or genotoxic processing contaminants that are formed during the process of edible oil refining. Because of their toxicological properties, the presence of these compounds in refined oils and foods containing these oils, particularly infant formula, poses a potential food safety concern. For this reason, recent research efforts have focussed on the development of methods for the analysis of MCPD and glycidyl esters in infant formula in order to estimate levels of exposure. This work presents occurrence data for 3-MCPD and glycidyl esters in 222 infant formulas purchased in the United States between December 2017 and January 2019. The results of this study show a wide range of contaminant concentrations across four different manufacturers, with average bound 3-MCPD concentrations ranging from 0.035 µg g^?1 to 0.63 µg g^?1 and average bound glycidol concentrations ranging from 0.019 µg g^?1 to 0.22 µg g^?1. The data suggest that manufacturers B and C source palm oil produced with mitigation measures, leading to reduced amounts of 3-MCPD and glycidyl esters in their infant formulas. Additionally, comparison with a previously published study in our laboratory of the occurrence of 3-MCPD and glycidyl esters in infant formula purchased in the U.S. between 2013 and 2016 revealed that, since 2016, contaminant concentrations have decreased in products produced by manufacturers A, B, and C, while contaminant amounts in formulas from manufacturer D have slightly increased.     

Selective serotonin receptor stimulation of the medial nucleus accumbens causes differential effects on food intake and locomotion.

Substantial evidence suggests that pharmacological manipulations of neural serotonin pathways influence ingestive behaviors. Despite the known role of the nucleus accumbens in directing appetitive and consummatory behavior, there has been little examination of the influences that serotonin receptors may play in modulating feeding within nucleus accumbens circuitry. In these experiments, the authors examined the effects of bilateral nucleus accumbens infusions of the 5-HT1/7 receptor agonist 5-CT (at 0.0, 0.5, 1.0, or 4.0 μg/0.5 μl/side), the 5-HT? receptor agonist EMD 386088 (at 0.0, 1.0, and 4.0 μg/0.5 μl/side), or the 5-HT2C preferential agonist RO 60–0175 (at 0.0, 2.0, or 5.0 μg/0.5 μl/side) on food intake and locomotor activity in the rat. Intra-accumbens infusions of 5-CT caused a dose-dependent reduction of food intake and rearing behavior, both in food-restricted animals given 2-hr free access to Purina Protab RMH 3000 Chow, as well as in nondeprived rats offered 2-hr access to a highly palatable fat/sucrose diet. In contrast, stimulation of 5-HT? receptors with EMD 386088 caused a dose-dependent increase of intake under both feeding conditions, without affecting measures of locomotion. Infusions of the moderately selective 5-HT2C receptor agonist RO 60–0175 had no effects on feeding or locomotor measures in food-restricted animals, but did reduce intake of the fat/sucrose in nonrestricted animals at the 2.0 μg, but not the 5.0 μg dose. Intra-accumbens infusions of selective antagonists for the 5-HT? (SB 269970), 5-HT? (SB 252585), and 5-HT2C (RS 102221) receptors did not affect locomotion, and demonstrated no lasting changes in feeding for any of the groups tested. These data are the first to suggest that the activation of different serotonin receptor subtypes within the feeding circuitry of the medial nucleus accumbens differentially influence consummatory behavior. (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Surface and structural characterization of multi-walled carbon nanotubes following different oxidative treatments

Six commonly used wet chemical oxidants (HNO₃, KMnO₄, H₂SO₄/HNO₃, (NH₄)₂S₂O₈, H₂O₂, and O₃) were evaluated in terms of their effects on the surface chemistry and structure of MWCNTs using a combination of analytical techniques. X-ray photoelectron spectroscopy (XPS) and energy dispersive spectroscopy (EDX) were used to characterize the extent of surface oxidation, while chemical derivatization techniques used in conjunction with XPS allowed the concentration of carboxyl, carbonyl, and hydroxyl groups at the surface to be quantified for each MWCNT sample. Our results indicate that the distribution of oxygen-containing functional groups was insensitive to the reaction conditions (e.g., w/w% of oxidant), but was sensitive to the identity of the oxidant. MWCNTs treated with (NH₄)₂S₂O₈, H₂O₂, and O₃ yielded higher concentrations of carbonyl and hydroxyl functional groups, while more aggressive oxidants (e.g., HNO₃, KMnO₄) formed higher fractional concentrations of carboxyl groups. IR spectroscopy was unable to identify oxygen-containing functional groups present on MWCNTs, while Raman spectra highlighted the frequently ambiguous nature of this technique for measuring CNT structural integrity. TEM was able to provide detailed structural information on oxidized MWCNT, including the extent of sidewall damage for different oxidative treatments.     

Underwater Adhesives Produced by Chemically Induced Protein Aggregation

Barnacles convert hydrophilic proteins into an insoluble, yet aqueous, material that functions as a permanent underwater adhesive. Here, it is demonstrated that a common hydrophilic protein, bovine serum albumin, can be chemically triggered underwater to aggregate into a similar aqueous adhesive that mimics the formation of the natural adhesive. The combined action of multiple chemical denaturants initiates rapid gelation followed by further curing over time in artificial seawater. The adhesive strengths of this waterborne adhesive measured by lap shear are comparable to many bioinspired adhesives that use organic solvents and a high fraction of hydrophobic components. This approach establishes a bioinspired adhesive that can be deployed at practical scales in marine environments, produced sustainably, and sourced from low-cost materials.