Optimization of inoculum to substrate ratio for enhanced methane yield from leather fleshings in a batch study

One of the most significant issues of the last few decades has been tracing for renewable energy sources. Animal fleshing (ANFL) is the most common proteinaceous solid waste accured during the production of leather and it must be disposed of in an environmentally responsible manner. This paper is attempts to assess the biogas production from solid waste originating from the chrome based tannery. Anaerobic digestion of these wastes will be a viable option for waste stabilization and energy production in the form of biogas to be utilized in the industry. The bio-methane potential of the wastes were examined by mixing these wastes with various sources of inoculum and different inoculum to substrate (I/S) ratio considered. The batch experiments were carried out in 2.5 l glass reactors with a various source of inoculumviz., Cow Dung (CD), Elephant Dung (ED) and Bio-Digested Slurry (BDS) with varied inoculum to substrate (LFs) ratios for a retention time of 50 days with replications. The results obtained from the experiments showed that BDS:LF (25:75) had the highest gas production of 14505 ml (651.85 ml CH₄g^?1 VS) followed by CD:LF (50:50) produced 12072.5 ml (789.36 ml CH₄g^?1 VS) and ED:LF (75:25) produced 11252.5 ml (1492.08 ml CH₄g^?1 VS)with a methane content of 63.77, 61.92 and 62.72%, respectively.     

Additive manufacturing approaches for biological power generation

As the consequences of global warming continue to affect the climate, there is an increased need for technologies that decrease dependence on fossil fuel consumption and promote sustainability. Additive manufacturing (AM) not only enables the scale-up and mass production of renewable energy technologies but also reduces cost and lead time, minimizes waste, and uses less energy than traditional manufacturing processes. Moreover, AM brings design and innovation to the forefront by allowing for design strategy revision and rapid prototyping. Herein, AM approaches used to fabricate devices that enable biological power generation are described. Biological power generation is a process through which biocatalysts – electroactive bacteria, enzymes, or cyanobacteria – harvest electrons from chemical substrates or light. Device engineering directs electron transfer events to a conductive material and maximizes power output. This review covers recent AM approaches for biological power generation in the form of microbial fuel cells (MFCs), enzymatic fuel cells, and biophotovoltaic cells with an emphasis on MFCs. Fabrication methods and materials for electrodes, chambers, inserts, membranes, and biofilms are described, along with impacts on device performance.     

Bibliometric analysis and an overview of the application of the non-precious materials for pyrolysis reaction of plastic waste

Huge plastic consumption and depletion of fossil fuels are at the top of the world's environmental and energy challenges. The scientific community has tackled these issues through different approaches. Catalytic pyrolysis of plastic wastes to valuable products has been proved as a sustainable route which fits with the circular economy aspects. The design of catalytic materials is the central factor for performing the catalytic conversion of plastic wastes. This review aims to conduct a Bibliometric analysis of the pyrolysis of plastic wastes and non-precious-based catalysts by mapping research studies over the last fifty years. The analysis was developed via VOSviewer and RStudio tools. It showed the historical progress regarding plastic waste pyrolysis to produce valuable products and chemicals worldwide. The research shows that the top five countries with the highest citations and publications in this field were Spain, China, England, the USA and India. The Journal of Analytical and Applied Pyrolysis had the most comprehensive coverage of plastic waste. The relationship between the catalyst and the mechanism of plastic waste can influence the production yield and selectivity. The research gap and underrepresented research topics were identified, and previous research studies on developing non-precious-based catalysts that were most relevant to the current topic were reviewed and discussed. The challenges and perspectives on catalyst preparation and development for material complexity were critically discussed. Challenges of previous studies and directions for future research were provided. This report might guide the reader to take a general look at plastic waste valorization by pyrolysis and easily understand the main challenges.     

Photocatalytic and antifouling properties of TiO2-based photocatalytic membranes

Photocatalysis has been extensively studied due to its potential ability to avoid the excessive use of chemical reagents and reduce the energy consumption by employing solar energy. Moreover, to alleviate the reduction in the membrane permeation selectivity, separation efficiency, and membrane service life caused by the emerging micro-pollutants and membrane fouling, membrane technology is often coupled with microbial, electrochemical, and catalytic processes. However, although physical/chemical cleaning and membrane module replacement can overcome the inherent limitations caused by membrane fouling and other membrane separation processes, high operating costs limit their practical applications. In this review, common preparation methods for TiO₂ photocatalytic membranes are described in detail, and the main approaches to enhancing their photocatalytic performance are discussed. More importantly, the mechanism of the TiO₂ photocatalytic membrane antifouling process is elucidated, and some applications of photocatalytic membranes in other areas are described. This review systematically outlines future research directions in the field of photocatalytic membrane modification, including metal and non-metal doping, fabrication of heterojunction structures, control over reaction conditions, increase in hydrophilicity, and increase in membrane porosity.     

Bioelectrodes for evaluating molecular therapeutic and toxicity properties

Recent progress on material designs merged with nanotechnology and biotechnology strategies has advanced studies of complex biological samples on electrodes for cytochrome P450 (CYP)–driven biocatalytic reactions (e.g. liver membrane fractions, cells, and various organ-specific CYP extracts). In addition, protein engineering of CYP enzymes with their reductase partner in membranes (e.g. baculovirus- or Escherichia coli bacteria–expressed CYP microsomes) and other recombinant strategies (e.g. engineered CYP and reductase fusion domains and site-directed CYP mutagenesis) are promising sustainable approaches for offering abundant sources of CYP enzymes for electrocatalytic applications. The combination of in silico and experimental electroanalytical methods with hyphenated approaches and biological assays can offer early and rigorous profiling of new drugs and specialty chemicals for safe exposure and beneficial use.     

The use of Bagassa guianensis aubl. forestry waste as an alternative for obtaining bioproducts and bioactive compounds

The development of new products and technologies based on agro-industrial waste use has been caused by the dearth of raw materials linked to environmental factors. In this work, it was aimed at proving the potential of using Bagassa guianensis species forestry waste (MENDESS ROSS Ltda., located on Mucajaí – RR/Brazil) in obtaining bioactive compounds and the use of ethanolic extract as a bioproduct in combating oxidative stress. The chemical profile of ethyl acetate and ethanolic extracts, by HPLC, HPTLC and NMR, allowed to identify the presence of important phytochemical classes, such as fatty acids, stilbenes, moracins, flavanones and dihydroflavonols in both extracts, in addition to the identification of bioactive compounds of pharmacological and economic relevance, such as stilbenes trans-resveratrol, trans-oxyresveratrol, moracin M, moracin N and the aminosugar 1-deoxynojirimycin, their permanence in the raw material confirms the viability of using this waste even after industrial processing, which allows adding value to the species productive chain. The analysis of the antioxidant capacity showed an important action of ethanolic extract in the face of DPP? and ABT?⁺ radicals solutions, with IC₅₀ 23.71 and 5.79 µg/mL respectively, which suggests being related to its abundant phenolic composition, thus, indicating a possible bioproduct in the combat the effects caused by oxidative stress, in addition to its application in cosmetics, pharmaceuticals, stabilizing additives or even as a raw material for obtaining bioactive molecules in secondary processes.     

The glucocorticoid derivative with the phthalimide group cationic nanocrystal for ophthalmic application: a design space development approach

The glucocorticoid derivative of budesonide with a phthalimide group is a drug candidate to treat inflammatory eye diseases; nevertheless, it presents low water solubility. Drug nanocrystals have been proposed to overcome this hurdle. The development of an innovative ophthalmic anti-inflammatory nanosuspension was performed using a design space approach. We obtained the particle size reduction of this glucocorticoid derivative on a nanometer scale (approximately 165.0 nm), applying wet bead milling on a super reduced scale. The design of experiment supported the optimization of the formula evaluating the parameters that influence reducing the particle size and also allowed determining the design space. Considering the two statistical models developed and the size range obtained, we proposed that the optimized formulation for the glucocorticoid derivative nanosuspension may be 1.0 wt% glucocorticoid derivative and 0.092 wt% cetylpyridinium chloride. This formulation was characterized by the morphological, physical–chemical, and mucoadhesive in vitro test and showed potential for ophthalmic use with reduced frequency of product application, improved efficiency, and safety, which may promote better patient compliance.     

Plant cell culture technologies: A promising alternatives to produce high-value secondary metabolites

Plants have been used for its medicinal values since ancient time. The medicinal properties of plants are based on their phytochemical constituent particularly secondary metabolites which are produced in low amounts by plants. Secondary metabolites have been used as medicines, flavors, colors, and fragrances. In recent time, these natural compounds are gaining enormous attention in pharmaceutical, cosmetics, and nutraceutical industries and are regarded economically valuable products. The production of plant secondary metabolites in plant is largely dependent on the plant species, environmental factors and geographical regions. In addition, the main challenges in their mass production is reported to be the quality and quantity issues during their synthesis. Therefore, enthusiasm has grown for increasing the production of secondary metabolites by employing in vitro plant cell culture technology and bioengineering methods. Such technological advancement, has led to production of a huge number of medicinal herbs and high-value secondary metabolites that are mostly used in pharmaceuticals, cosmetics and nutraceuticals industries. The current mini-review article focuses on applications of plant cell culture system for the production secondary metabolites and recent techniques used to improve metabolite contents. Furthermore, our review emphasizes safety issues of plant cell culture derived products.     

Photocatalytic remediation of persistent organic pollutants (POPs): A review

The release of persistent organic pollutants (POPs) into the environment is an issue of global concern, as the chemicals are stable over a prolonged period resulting in their accumulation in many animals and plants. Although POPs are banned in several countries, many chemicals have been proposed as POP candidates to be added to the existing compounds as defined by the United Nations Stockholm Convention committee. To address the safe disposal and clean-up of such chemicals, new, and especially cost-effective, remediation technologies for POPs are urgently required. This review focuses on existing POPs and the types of remediation processes available for their removal. Particular attention is paid towards photocatalysis using nanocatalysts in this review, due to their effectiveness towards POP degradation, technological feasibility, and energy and cost-efficiency. The underlying principles and the key mechanisms of the photocatalysts based on TiO₂ based materials, metal oxides, light-assisted Fenton systems, framework materials e.g. metal-organic frameworks and polyoxometalates, including metal-free and hybrid photocatalysts for POPs cleanup are described for advance applications in solving the POPs contamination in the environment. The improvements of photocatalytic performance especially the POPs removal mechanism using the conventional and modified process, the design and optimization of photoreactors, and the integration technology are the critical challenges for the emerging pollutants and require intensive research for the forthcoming future.     

Biodegradable silk-curcumin composite for sustained drug release and visual wound monitoring

The production of biodegradable dressing capable of sustained drug release, along with the monitoring of wound conditions, represents new heights of multifunctional platforms for wound care. The reported curcumin-loaded silk fibroin has shown sustained drug release over the time of 10 days through a non-Fickian diffusion process satisfying Korsmeyer-Peppas' model along with the visual monitoring of wound healing through notable color variation with pH as a biomarker. The superhydrophobic nature (water contact angle = 163.7) of the SF, along with the lipophilicity (CA = 0 (Blood)) and hygroscopic nature prevents wetting of wound surface, whereas the excess exudates from wounds are absorbed along with sufficient water and oxygen permeability. The pH responsiveness as a result of the keto-enol tautomerism in curcumin was utilized for wound monitoring through visual indication enabling even ordinary people to detect the state of the wound. The in-situ biodegradation studies verified using cow-dung slurry, the degradability of the material with 25.3% weight loss within 30 days following first-order kinetics (R² = 0.994), as a result of the attack of proteolytic enzymes on the amino acid units of SF, mitigating the concerns of medical wastes.     

Integrating approach to discover novel bergenin derivatives and phenolics with antioxidant and anti-inflammatory activities from bio-active fraction of Syzygium brachythyrsum

Syzygium brachythyrsum is an important folk medicinal and edible plant in Yunnan ethnic minority community of China, however, little is known about the chemical and bio-active properties. The present study is aimed to identify the bioactive constituents with antioxidant and anti-inflammatory properties by an integrating approach. First, two new bergenin derivatives, brachythol A (1) and brachythol B (2), together with eleven known phenolic compounds (3–13) were isolated from bioactive fractions by phytochemical method. Among these isolated chemicals, five bergenin derivatives, along with 3 phenolics were found in Syzygium genus for the first time. Then, a further chemical investigation based on ultra-high-performance liquid chromatography-Q Exactive Orbitrap mass spectrometry resulted in a total of 107 compounds characterized in the bio-active fractions, including 50 bergenin derivatives, among which 14 bergenin derivatives and 14 phenolics were potential new natural chemicals. Most of the isolated compounds showed obvious antioxidant activities, while compounds 11, 12, and 13 had favorable performance. Eight compounds (2–5, 7, and 9–11) showed good inhibitory activity on nitric oxide (NO) production in macrophage RAW 264.7 cells. The structure–activity correlation analysis indicated that the antioxidation and anti-inflammatory activities enhanced when bergenin was esterified with gallic acid, caffeic acid or ferulic acid. This is the first report of bergenins in Syzygium genus and the richness in new bio-active bergenins and gallic acid derivatives indicated that Syzygium brachythyrsum is a promising functional and medicinal resource.     

Recent studies on advance spectroscopic techniques for the identification of microorganisms: A review

The continuous development of resistance to antibiotic drugs by microorganisms causes high mortality and morbidity. Pathogens with distinct features and biochemical abilities make them destructive to human health. Therefore, early identification of the pathogen is of substantial importance for quick ailments and healthcare outcomes. Several phenotype methods are used for the identification and resistance determination but most of the conventional procedures are time-consuming, costly, and give qualitative results. Recently, great focus has been made on the utilization of advanced techniques for microbial identification. This review is focused on the research studies performed in the last five years for the identification of microorganisms particularly, bacteria using advanced spectroscopic techniques including mass spectrometry (MS), infrared (IR) spectroscopy, Raman spectroscopy (RS), and nuclear magnetic resonance (NMR) spectroscopy. Among all the techniques, MS techniques, particularly MALDI-TOF/MS have been widely utilized for microbial identification. A total of 44 bacteria i.e., 6 Staphylococcus spp., 3 Enterococcus spp., 6 Bacillus spp., 4 Streptococcus spp., 6 Salmonella spp., and one from each genus including Escherichia, Acinetobacter, Pseudomonas, Proteus, Clostridioides, Candida, Brucella, Burkholderia, Francisella, Yersinia, Moraxella, Vibrio, Shigella, Serratia, Citrobacter, and Haemophilus (spp.) were discussed in the review for their identification using the above-mentioned techniques. Among all the identified microorganisms, 21% of studies have been conducted for the identification of E. coli, 14% for S. aureus followed by 37% for other microorganisms.     

Developments on carbon dioxide reduction: Their promise,achievements, and challenges

CO₂ reduction processes continue to be developed for electrosynthesis, energy storage applications, and environmental remediation. A number of promising materials have shown high activity and selectivity to target reduction products. However, the progress has been mainly at a small laboratory scale, and the technical challenges of large scale CO₂ reduction have not been considered adequately. This review covers recent advancements in catalyst materials and cell designs. The leading materials for CO₂ reduction to a number of useful products are presented with their corresponding cell and reactor designs. The latest efforts to progress to industrially relevant scales are discussed, along with the challenges that must be met for carbon dioxide reduction to be a viable route for mass scale production.     

Hydrides compounds for electrochemical applications

Hydrides have been used since a long time for solid-state hydrogen storage and electrochemical nickel-metal hydride batteries. Besides these applications, growing attention has been devoted to their development as anode materials, as well as solid electrolytes for Li-ion and other ion batteries. Herein, we review and summarize the recent advances of hydrides as negative electrodes for Ni-MH and A-ion batteries (A = Li, Na), and as electrolyte for all solid-state batteries (ASSB). Metallic hydrides such as intergrowth compounds are highlighted as the best compromise up to now for Ni-MH. Regarding anodes of Li-ion batteries, MgH₂, especially its combination with TiH₂, provides very promising results. Complex hydrides such as Li-borohydride and related closo-borates and monovalent carborate boron clusters appear to be very attractive as solid electrolytes for Li-based ASSB, whereas closo-hydroborate sodium salts and closo-carboborates are investigated for Na- and Mg-ASSB. Finally, further research directions are foreseen for hydrides in electrochemical applications.     

Water oxidation with inhomogeneous metal-silicon interfaces

Silicon (Si) is a prime candidate for manufacturing water-splitting photoelectrochemical cells, however, the stability of this material remains a serious bottleneck. This is particularly true for the photoanode, subject to severe deactivation mechanisms. So far, thin film homogeneity has been the paradigm in the quest for stable and efficient Si-based photoanodes, which involved the use of vapor deposition methods to produce conformal thin films ensuring Si protection and efficient catalysis during operation. Conversely, recent reports on n-Si/metal thin film junctions have highlighted the benefits of the junction heterogeneity, generated in situ. In addition, results obtained from n-Si photoanodes partially covered with discontinuous films of Co and Ni nanoparticles lately suggested that homogeneity is not a prerequisite to reach efficiency and stability. Such findings may open new protection routes for Si-based photoanodes, breaking with classical strategies and allowing the use of liquid phase modification methods such as electrodeposition.     

Exploring the promoting mechanisms of bovine serum albumin,lignosulfonate, and polyethylene glycol for lignocellulose saccharification from perspective of molecular interactions with cellulase

Bovine serum albumin (BSA), polyethylene glycol (PEG) and lignosulfonate (LS) have been extensively employed as synergistic agents in lignocellulose saccharification. Nevertheless, the promoting mechanisms have not been fully understood and there are a number of controversial opinions existed. All attention has been paid to the interactions between respective additive and substrate. However, rarely attention has been paid to the interactions between additives and enzymes (cellulase from Trichoderma reesei in this investigation). This interaction is actually more important since cellulase interacts with the additives before it contacts with substrate. Therein, Quartz crystal microbalance with dissipation monitoring (QCM-D), surface plasma resonance (SPR) and small angel X-ray scattering (SAXS) were incorporated to study the interaction between enzyme and additives. The results showed synergistic agents have different interaction modes with cellulase. BSA and LS can form complexes with cellulase and the formed complexes prevent them from nonproductive binding by residue lignin; what’s more, the cellulase-BSA complexes improve the hydrolytic capability of pristine enzyme whereas cellulase-LS complexes reduce. PEG prevents the unproductive binding of cellulase to the residual lignin by forming a thin layer that actually acts as a steric hindrance to the residual lignin. This investigation helps us to understand the sophisticated interactions among the components in the complicated enzymatic system, especially the interactions between enzymes and synergistic agents. It will be helpful in the design and utilization of synergistic additives in the lignocellulose biorefinery process as well.     

Polymeric microspheres as support to co-immobilized Agaricus bisporus and Trametes versicolor laccases and their application in diazinon degradation

The laccase enzymes of Agaricus bisporus and Trametes versicolor were successfully covalently co-immobilized on poly(glycidyl methacrylate) microspheres. The enzyme load reached after the co-immobilization of both enzymes was 6.75 U g⁻¹ carrier. The resulting biocatalyst showed the combined properties of both immobilized enzymes, increasing their optimum pH and temperature ranges. The storage and operational stabilities were also improved after co-immobilization. In presence of mediator (ABTS) the organophosphate pesticide diazinon was 100% biodegraded after 48 h of reaction with 0.2 U/mL of co-immobilized enzymes (at the two maximum activity pH values: 2.0 and 3.0). In the absence of a mediator, the degradation percentages were above 88%. Data showed that, compared with single enzymatic immobilization, the co-immobilization of the two laccases is an easy, efficient, and low cost alternative to expanding the range of work of the biocatalyst, thereby improving the stability and some biochemical properties to generate a powerful alternative for pesticide degradation in a wide range of conditions.     

First germanium doped titanium disulfide polytypes: Crystal structure and metal–metal interactions

Single crystals of Ge-doped TiS₂ polytypes, 1T, (4H)₂, 12R, and their corresponding new a√3 × a√3 superstructure were grown by chemical vapor transport method. The crystals were characterized by combining X-ray diffraction and transmission electron microscopy techniques. The structures of these polytypes are all based on close packing layers of sulfur of CdI₂-type structure. Except in the 1T polytype, the germanium atoms are observed to be equally distributed over both partial and complete occupancy layers. A significant distortion of the metal–sulfur distances is observed in the superstructure polytypes, as a consequence of metal–metal corrugated layers. The 12R-a√3 × a√3 superstructure is revealed by both electron diffraction and X-ray diffraction by the presence of satellite reflections. Electron diffraction patterns from the 12R polytype show highly structured diffuse scattering surrounding the main spots. These diffuse segments, which are arranged in triangles sharing vertices, correspond to a 2a* × 2a* superstructure and are attributed to the short-range order of metal atoms in the partially filled layers.     

Camellia sinensis: Insights on its molecular mechanisms of action towards nutraceutical,anticancer potential and other therapeutic applications

The Camellia sinensis plant provides a wide diversity of black, green, oolong, yellow, brick dark, and white tea. Tea is one of the majorly used beverages across the globe, succeeds only in the water for fitness and pleasure. Generally, green tea has been preferred more as compared to other teas due to its main constituent e.g. polyphenols which contribute to various health benefits. The aim of this updated and comprehensive review is to bring together the latest data on the phytochemistry and pharmacological properties of Camellia sinensis and to highlight the therapeutic prospects of the bioactive compounds in this plant so that the full medicinal potential of Camellia sinensis can be realised. A review of published studies on this topic was performed by searching PubMed/MedLine, Scopus, Google scholar, and Web of Science databases from 1999 to 2022. The results of the analysed studies showed that the main polyphenols of tea are the four prime flavonoids catechins: epigallocatechin gallate (EGCG), epicatechin gallate (ECG), epigallocatechin (EGC), and epicatechin (EC) along with the beneficial biological properties of tea for a broad heterogeneity of disorders, including anticancer, neuroprotective, antibacterial, antiviral, antifungal, antiobesity, antidiabetes and antiglaucoma activities. Poor absorption and low bioavailability of bioactive compounds from Camellia sinensis are limiting aspects of their therapeutic use. More human clinical studies and approaching the latest nanoformulation techniques in nanoparticles to transport the target phytochemical compounds to increase therapeutic efficacy are needed in the future.     

Challenges in semiconductor single-entity photoelectrochemistry

It is challenging to study the single semiconductor nanocrystal electrochemistry and photoelectrochemistry. The photocatalytic processes, such as the oxidation of methanol and iodide, that result from the electron–hole pair formed within a nanoparticle (NP) allow the detection of discrete current transient events assigned to single entities. Photocatalytic current amplification allows detection of collisions between the semiconductor NPs and the ultramicroelectrode that produce current transient. Staircase responses and blips in the i vs. t response indicate that irreversible and reversible NP/electrode interactions result depending on the experimental conditions. Dye sensitization increases the photocurrent magnitude of ZnO and TiO₂ with respect to bare TiO₂ NPs. The microelectrodes used are Pt, TiO₂/Pt, TiO₂/Au, and F-doped SnO₂.