Oligomeric Derivatives Research Articles

Limonene and its derived oligomer as bioactive additives in starch/coffee husks biocomposites for food packaging applications

In this study, antioxidant, and antimicrobial starch-based biocomposite films reinforced with coffee husks (S/CH) were developed by incorporating either limonene (LM) (S/CH/LM) or its oligomer derivative, poly(limonene) (PLM) (S/CH/PLM), at different concentrations (5–10 % w/w of starch). Through a comprehensive assessment of film properties, morphology, and structure, a comparative analysis between the two additives was proposed. Scanning electron microscopy (SEM) revealed some defects throughout the polymer matrix after additive incorporation. The tensile strength (TS) and modulus of elasticity (ME) showed a decrease upon the inclusion of both LM and PLM, while the elongation at break (E) increased. Notably, PLM exhibited outstanding antioxidant capacity, enhancing the films by 108 % over control samples. Additionally, at just 5 % concentration, PLM effectively inhibited the growth of Escherichia coli ATCC 11775 (35.33 ± 2.52 mm) and demonstrated an impressive UV–Vis barrier, comparable to the highest amount of LM incorporated. Therefore, this research highlights the potential of coffee husk-reinforced starch biocomposites with limonene-derived additives as a promising solution for food packaging applications. The comparative analysis sheds light on the advantages of using the PLM in terms of antioxidant and antimicrobial properties, contributing to the advancement of active packaging technologies.

Enhancement of the biological activity of hydroxytyrosol through its oxidation by laccase from Trametes versicolor

The laccase-catalyzed oxidation of hydroxytyrosol (HT) towards the formation of its bioactive oligomer derivatives was investigated. The biocatalytic oligomerization was catalyzed by laccase from Trametes versicolor in aqueous or various water-miscible organic solvents and deep eutectic solvent (DES)-based media. Mass Spectroscopy and Nuclear Magnetic Resonance were used for the characterization of the products. The solvent system used significantly affects the degree of HT oligomerization. The use of 50 % v/v methanol favored the production of the HT dimer, while other organic solvents as well as DESs led to the formation of hydroxytyrosol trimer and other oligomers. In vitro studies showed that the HT dimer exhibits 3- to 4-fold enhanced antibacterial activity against Gram-positive and Gram-negative bacteria compared to the parent compound. Moreover, the ability of HT dimer to inhibit the activity of soybean lipoxygenase and Candida rugosa lipase was 1.5-fold higher than HT, while molecular docking supported these results. Furthermore, HT dimer showed reduced cytotoxicity against HEK293 cells and exhibited a strong ability to inhibit ROS formation. The enhanced bioactivity of HT dimer indicates that this compound could be considered for use in cosmetics, skin-care products, and nutraceuticals.

Theoretical investigations on electronic structure and optoelectronic properties of vinyl fused monomeric and oligomeric benzimidazole derivatives using DFT and TDDFT techniques.

The present work encompasses the theoretical investigation of 14 benzimidazole-based (seven vinyl fused monomeric benzimidazole (VFMBI) and seven vinyl fused oligomeric benzimidazole (VFOBI)) derivatives using density functional theory (DFT) and time-dependent density functional theory (TD-DFT) techniques. The effects of electron donor and acceptor groups on the electronic structure such as HOMO (highest occupied molecular orbital) and LUMO (lowest unoccupied molecular orbital) energies, HOMO-LUMO energy gap, ionization potentials (IPs), electron affinities (EAs), internal reorganization energies of holes and electrons (λh/e), and excited state properties have been explored in the present work. In addition, natural bond orbital (NBO) analysis of these compounds has been investigated to reveal the typical stabilization interactions in these molecules. Hence, the aim of the present work is to explore the electronic structures and optoelectronic properties of the title molecules on the basis of the DFT quantum chemical calculations and to make an idea on the parameters influencing the optoelectronic efficiency toward a better understanding of the structure-property relationships. Moreover, the calculated results reveal the suitable optoelectronic properties of benzimidazole oligomer derivatives using theoretical techniques. Of the investigated molecules, 4_MABIMCY and 4_MABIOCY show potential optoelectronic properties and can be used as a potential charge transport material due to their narrow band gap, high hyperpolarizability, low ionization potential, and high electron affinity. The larger λab and λem values favor the system to be used as a potential optoelectronic material with better optical properties. All quantum chemical calculations were carried out using Gaussian09 theoretical chemistry code. Ground state calculations were made using the B3LYP/6-31+G(d,p) method. All excited state calculations had been computed using TDB3P86/6-311++(d,p). The initial structure for excited state calculations was optimized using the AM1 semi-empirical method.

New highly π-conjugated bisalkynyl-linked oligomers of heteroatom-substituted perylene diimides: Optical and electronic properties and performance in perovskite solar cells

A series of four new oligomeric derivatives of NFA, NFA(S), NFA(Se) and NFA(N) with terminal perylene diimide groups modified with heteroatoms of S, Se, and N, were successfully synthesized and fully characterized by a variety of physicochemical methods. Due to deep LUMO levels, all compounds have an electron-acceptor character, which allows them to perform as electron transport compounds in perovskite solar cells of p-i-n architecture. The highest efficiency of 17.23 % was delivered by the solar cells with NFA(Se) electron transporting layer.

Ethers and Their Oligomeric Derivatives Obtained from 2,4,6,8-Tetra(hydroxymethyl)glycoluril

Ethers and Their Oligomeric Derivatives Obtained from 2,4,6,8-Tetra(hydroxymethyl)glycoluril

Advanced pectin-based films: Enhancing antioxidant, antibacterial, UV barrier, and physicochemical properties upon oligomeric limonene derivative incorporation

In the field of active packaging, the utility of limonene (LIM) as an antioxidant, antibacterial agent, and UV blocker has long been recognized. However, its high volatility and limited stability have constrained its full potential. Thus, this research proposes the use of an oligomer derivative, poly (limonene) (PLM), as an alternative functional component in citrus pectin-based films. Percentages of 10% and 20% (w/w of pectin) of PLM and LIM were incorporated leading to films with enhanced antioxidant activity (84% higher than the control sample) and UV light barrier effect (particularly in the UV-A and UV-B range) when 10% of PLM was used. Notably, the introduction of PLM into the films imparted effective antibacterial properties against Staphylococcus aureus. Additionally, it enhanced tensile strength by 35% and elongation at break by 85%. Although the mechanical properties were statistically similar to the films with LIM, its derived oligomer showed superior performance regarding functional properties, probably related to its non-volatility. These findings underscore the potential of PLM as a groundbreaking and non-volatile functional additive for the active packaging field.

Transesterification‐vulcanization route to durable composites from post‐consumer poly(ethylene terephthalate), terpenoids, and industrial waste sulfur

AbstractDespite improvements in chemical recycling, most post‐consumer plastics are still deposited in landfills where they pose a significant threat to ecological health. Herein we report a two‐stage method for chemically recycling poly(ethylene terephthalate) (PET) using terpenoids and waste sulfur to yield composites. In this method, post‐consumer PET (from beverage bottles) undergoes transesterification with a terpenoid alcohol (citronellol or geraniol) to yield low‐molecular PET oligomers. The terpene‐derived alkenes in these PET oligomer derivatives then served as reaction sites for inverse vulcanization with 90 wt% elemental sulfur to form composite CPS (using citronellol) or GPS (using geraniol). Composition, mechanical, thermal, and morphological properties were characterized by NMR spectroscopy, MALDI, FT‐IR spectroscopy, compressive and flexural strength analysis, TGA, DSC, elemental analysis, and SEM/EDX. The composites CPS (compressive strength = 5.20 MPa, flexural strength = 3.10 MPa) and GPS (compressive strength = 5.8 MPa, flexural strength = 2.77 MPa) showed mechanical strengths comparable to those of commercial bricks (classification C62 for general building). The approach delineated herein thus represents a method to chemically recycle waste plastic with industrial waste sulfur and plant‐derived terpenoids to yield composites having favorable properties comparable to existing building materials.

Characterizing the Impact of Oligomerization on Redox Flow Cell Performance

AbstractRedox flow batteries (RFBs) are hindered by complex failure modes, particularly crossover through the membrane, resulting in capacity fade and reduced cycling efficiencies. Redox‐active oligomers (RAOs) have recently been proposed for mitigating this phenomenon while maintaining sufficient transport properties; however, to date, few studies have quantified how the chemical and electrochemical properties of RAOs influence their performance in redox flow cells. Here, we demonstrate that oligomeric derivatives of 2,2,6,6‐tetramethylpiperidine 1‐oxyl (TEMPO) exhibit lower diffusivities than the monomeric species but retain facile charge transfer characteristics. The size‐dependent variations in mass transport rates directly translate to differences in flow cell polarization and symmetric cycling performance. Post‐mortem analyses reveal that oligomerization does not meaningfully alter decay processes as evinced by similar capacity fade across all species. Broadly, these findings corroborate and extend upon previously developed relationships between molecular size, electrochemical properties, and flow cell performance.

Reaction of Bacterial Poly-3-Hydroxybutyrate with Thionyl Chloride in the Presence of Zinc Chloride, and the Preparation of Chlorine-Containing Oligomers

The degradation patterns of bacterial poly-3-hydroxybutyrate (PHB) in chloroform solution under the action of thionyl chloride in the presence of zinc chloride were studied. When 2.5.mol of zinc chloride and 100 mmol of thionyl chloride were introduced into the solution of 25 mmol PHB, a decrease in the molecular weight of the polymer was observed. During the reaction, a relatively rapid decrease in the molecular weight of the polymer was noted in the first hour of the experiment; thus, the values of the weight-average molecular weight decreased from 840 kDa to 483, 167, 58.6, and 16.7 kDa after 1, 5, 24, and 96 h of the experiment, respectively. The polydispersity also gradually decreased from 2.69 at the beginning to 1.92 at the end of the experiment. Oligomers of PHB containing 3-chlorobutyric acid and 3-hydroxybutyryl chloride residues at the O and C ends of the polymer chain, respectively, were obtained. The results confirm the ability of thionyl chloride to interact with aliphatic esters in the presence of zinc compounds, and demonstrate the possibility of using this reaction to produce oligomeric derivatives of polyesters bearing chloralkyl and acid chloride functional groups.

First-principles study of electronic and optical properties in 1-dimensional oligomeric derivatives of telomestatin.

Real-space self-interaction corrected (time-dependent) density functional theory has been used to investigate the ground-state electronic structure and optical absorption profiles of a series of linear oligomers inspired by the natural product telomestatin. Length-dependent development of plasmonic excitations in the UV region is seen in the neutral species which is augmented by polaron-type absorption with tunable wavelengths in the IR when the chains are doped with an additional electron/hole. Combined with a lack of absorption in the visible region this suggests these oligomers as good candidates for applications such as transparent antennae in dye-sensitised solar energy collection materials. Due to strong longitudinal polarisation in their absorption spectra, these compounds are also indicated for use in nano-structured devices displaying orientation-sensitive optical responses.

Synthesis of branched chitosan derivatives for demulsification and steel anti-corrosion performances investigation

In the process of oil production, the existence of water inevitably brings numerous problems, such as the formation of emulsion and oil pipeline corrosion. It is an urgent need to develop multifunctional oilfield chemicals with greenness, demulsification and corrosion inhibition functions. In this study, we synthesized two eco-friendly branched chitosan derivatives (BH and CH), and investigated their demulsification and corrosion inhibition performance. Confocal laser micrographs revealed that BH and CH destabilized the water-in-oil emulsion through coalescence and flocculation, resulting in demulsification. The demulsification results showed that BH and CH at 500 mg∙L−1 removed up to 90.45% and 81.53% of the emulsified water, respectively. The dehydrated crude oil corroded the oil pipeline during transportation. The synthesized BH and CH were grafted quaternary ammonium groups and Schiff bases, which could adsorb onto iron surface to protect pipeline from corrosion. BH and CH at 500 mg∙L−1 inhibited the carbon steel corrosion by 85.70% and 83.56%, respectively from weight loss experiment in 8 wt% NaCl CO2-saturated solution at 60 ℃. Surface analysis techniques (SEM, EDX) and electrochemical techniques agreed with weight loss experimental results revealing effective corrosion inhibition. Experimental results indicated that both BH and CH showed satisfying demulsification and corrosion inhibition performances. It indicated that chitosan oligomer derivatives BH and CH showed satisfying application prospect in petrochemical industry.

Identification of polysaccharide binding materials used in cultural relics by pyrolysis-gas chromatography/mass spectrometry

热裂解-气相色谱/质谱(Py-GC/MS)技术能够实现微量样品中有机组分的准确、快速检测,非常适用于文物中各类天然有机材料的定性分析。该研究以中国古代书画、建筑、器物等文化遗产中常用的淀粉、桃胶,以及西方文化遗产中常用的阿拉伯胶等多糖类胶结材料为研究对象,系统分析并总结各类材料的Py-GC/MS特征裂解组分及辨别方法。研究发现,淀粉、桃胶、阿拉伯胶在色谱保留时间前段的裂解产物基本一致,主要是小分子呋喃、酮类组分;在保留时间中段3类材料的裂解产物主要是呋喃型酮等组分,但不同材料的具体裂解组分差异明显;在保留时间后段,3类材料检出多种单糖衍生物以及单糖低聚体衍生物,其中桃胶与阿拉伯胶裂解组分较为接近,但与淀粉完全不同。因此,可根据不同保留时间段淀粉、桃胶、阿拉伯胶裂解产物的差异实现3类材料的辨别,其中1,6-脱水-β-D-吡喃葡萄糖只在淀粉中检出且色谱峰强度高,可以作为识别淀粉的特征组分;此外,可根据桃胶、阿拉伯胶在保留时间后段的裂解产物主要质谱碎片离子m/z 60、m/z 101的提取离子流图分布特征实现其辨别。基于所建立的Py-GC/MS方法,研究推断故宫旧藏清代剔红云龙纹天球瓶瓶口部位黏结材料含有面粉,旻宁御笔并蒂含芳贴落画心纸所用黏结材料为面粉糨糊。该研究所建立方法及所总结的数据易于推广,适用于我国文物中多糖类材料的准确、快速识别,研究结果能为相关文物材质工艺的研究以及保护修复方案的制定提供科学依据。

Low-molar-mass and oligomeric derivatives of carbazole and triphenylamine containing thiazolo[5,4-d]thiazole moieties

Low-molar-mass and oligomeric derivatives of carbazole and triphenylamine containing thiazolo[5,4-d]thiazole moieties

Synthesis of Lignosulfonate-Based Dispersants for Application in Concrete Formulations.

Lignosulfonates (LS) are products from the sulfite pulping process that could be applied as renewable environmentally-friendly polymeric surfactants. Being widely used as plasticizers and water-reducing admixtures in concrete formulations LS compete in the market with petroleum-based superplasticizers, such as naphthalene sulfonate formaldehyde polycondensate (NSF) and copolymer polycarboxylate ethers (PCE). In this work, different chemical modification strategies were used to improve LS performance as dispersants for concrete formulations. One strategy consisted in increasing the molecular weight of LS through different approaches, such as laccase and polyoxometalate-mediated polymerization, glyoxalation, and reversible addition-fragmentation chain transfer (RAFT) polymerization. The other strategy consisted of preparing LS-based non-ionic polymeric dispersants using two different epoxidized oligomer derivatives of poly(ethylene glycol) (PEG) and poly(propylene glycol) (PPG). Modified LS were used to prepare cement pastes, which were examined for their fluidity. Results revealed that the most promising products are PPG-modified LS due to the introduction of PPG chains by reaction with phenolic moieties in LS. The enhanced dispersant efficiency of the ensuing products is probably related not only to electrostatic repulsion caused by the sulfonic ionizable groups in LS but also to steric hindrance phenomena due to the grafted bulky PPG chains.

Supramolecular architecture in sulfonylurea, sulfonyldiurea and sulfonyltriurea drugs: Synthesis, X-ray structure and Hirshfeld surface analysis

Sulfonylureas provide a useful motif for carrying donor and acceptor sites capable of hydrogen bonding. These are a prominent class of therapeutic agents in the pharmaceutical industry. However, the use of aryl sulfonyl oligomers in drug discovery, supramolecular chemistry and crystal engineering are unexplored. This motivated us to design, synthesize and understand the structural features of aryl sulfonylurea oligomers (n = 1–3). Here, we report the synthesis and spectroscopic characterization details such as 1H NMR, 13C NMR, mass spectrometry and single-crystal X-ray diffraction analysis for three sulfonylurea oligomer derivatives. Further, the molecular packing analysis of three derivatives reveals the significance of NH…O and CH…O intra and intermolecular hydrogen bonding. These hydrogen bonding contacts enable the sulfonylurea derivatives to form 2D framework/architecture. We quantify various intermolecular interactions in these derivatives by Hirshfeld analysis and 2D fingerprint plots. We have performed in-silico docking studies against Plasmodium falciparum (Pf) prolyl-tRNA synthetase (ProRS) to rationalize the binding affinity of title compounds.

Specific targeting of a highly toxic subpopulation of Aβ42 oligomers for the treatment of Alzheimer’s disease

AbstractBackgroundNon‐clinical data on the etiology of Alzheimer’s disease (AD) suggest that only a very small fraction of soluble oligomeric Aβ42 carries most of the neurotoxic potency. But the study of Aβ42 soluble species has been hampered by their intrinsic heterogeneous and dynamic nature. A unique oligomer‐stabilizing technology, AβCC, enables the development of therapies that target these specifically. We here demonstrate the development such immunotherapies that exhibit unique Aβ oligomer targeting activity which translates into high efficacy in non‐clinical models of the disease.MethodStable synthetic Aβ42CC peptide oligomer derivatives were used as antigens in an active vaccine and were used to develop a murine monoclonal antibody, ALZ‐201. Efficacy was evaluated on brain extracts from AD patients and controls. These brain extracts were immunodepleted with ALZ‐201 and control antibodies. Toxicity assays were then performed in primary mouse neuronal cultures using an automated cell imaging platform. In addition, acute neurotoxicity effects on memory formation in zebrafish were assessed following intracranial injections of the brain extracts.ResultThe AβCC oligomers were able to generate truly oligomer‐specific antibodies. AD extracts exhibited higher levels of toxicity in contrast to non‐AD extracts in both cells assays and in zebrafish. This toxicity was highly dependent on Aβ, shown by immunodepletion with 4G8. Comparable toxicity was observed for brain extracts immunodepleted with ALZ‐201 as for extracts immunodepleted with 4G8. Interestingly, the soluble Aβ42 species captured by ALZ‐201 were below the limit of detection with the standard biochemical techniques used for analysis.ConclusionThe data support the hypothesis that a specific subtype of Aβ42 oligomers has large neurotoxic effects in the central nervous system that can affect synaptic plasticity, learning and memory. These oligomers are present in very small amounts and, due to the inaccessible environment, are not likely to be targeted with non‐specific anti‐Aβ immunotherapies. In contrast, targeting them specifically may serve as effective future treatments.

High-Energy Proton-Beam-Induced Polymerization/Oxygenation of Hydroxynaphthalenes on Meteorites and Nitrogen Transfer from Urea: Modeling Insoluble Organic Matter?

Formation and structural modification of oxygenated polycyclic aromatic hydrocarbons (oxyPAHs) by UV irradiation on minerals have recently been proposed as a possible channel of PAH transformation in astrochemical and prebiotic scenarios of possible relevance for the origin of life. Herein, it is demonstrated that high-energy proton-beam irradiation in the presence of various meteorites, including stony iron, achondrite, and chondrite types, promotes the conversion of two representative oxyPAH compounds, 1-naphthol and 1,8-dihydroxynaphthalene, to complex mixtures of oxygenated and oligomeric derivatives. The main identified products include polyhydroxy derivatives, isomeric dimers encompassing benzofuran and benzopyran scaffolds, and, notably, a range of quinones and perylene derivatives. Addition of urea, a prebiotically relevant chemical precursor, expanded the range of identified species to include, among others, quinone diimines. Proton-beam irradiation of oxyPAH modulated by nitrogen-containing compounds such as urea is proposed as a possible contributory mechanism for the formation and processing of insoluble organic matter in meteorites and in prebiotic processes.

Synthesis and Functions of Oligomeric and Multidentate Dipyrrin Derivatives and their Complexes

The dipyrrin–metal complexes and especially the boron complex 4,4-difluoro-4-bora-3a,4a-diaza-s-indacene (BODIPY) have recently attracted considerable attention because of their interesting properties and possible applications. We have developed two unique and useful ways to extend versatility and usefulness of the dipyrrin complexes. The first one is the linear and macrocyclic oligomerization of the BODIPY units. These arrangements of the B–F moieties of the oligomerized BODIPY units provide sophisticated functions, such as unique recognition ability toward cationic guest, associated with changes in the photophysical properties by utilizing unprecedented interactions between the B–F and a cationic species. The second one is introduction of additional ligating moieties into the dipyrrin skeleton. The multidentate N2Ox dipyrrin ligands thus obtained form a variety of complexes with 13 and 14 group elements, which are difficult to synthesize using the original N2 dipyrrin derivatives. Interestingly, these unique complexes exhibit novel structures, properties, and functions such as guest recognition, stimuli-responsive structural conversion, switching of the optical properties, excellent stability of the neutral radicals, etc. We believe that these multifunctional dipyrrin complexes will advance the basic chemistry of the dipyrrin complexes and develop their applications in the materials and medicinal chemistry fields.1 Introduction2 Linear Oligomers of Boron–Dipyrrin Complexes3 Cyclic Oligomers of Boron–Dipyrrin Complexes4 A Cyclic Oligomer of Zinc–Dipyrrin Complexes5 Group 13 Element Complexes of N2Ox Dipyrrins6 Chiral N2 and N2Ox Dipyrrin Complexes7 Group 14 Element Complexes of N2O2 Dipyrrins8 Other N2O2 Dipyrrin Complexes with Unique Properties and Functions9 Conclusion

Oligomerization: An Inherent Property of Sulfonimidamides?

The treatment of the TBS‐protected p‐toluenesulfonimidamide with HCl exclusively affords the deprotected product. However, when HCl was replaced with formic acid, and the reaction mixture was left for an extended time or treated at high temperature, a mixture of oligomers was obtained as main products. The relevant N,N'‐capped oligomers were prepared through carbamoylation with p‐chlorophenyl isocyanate. The key to dicarbamoylation is to remove formic acid from the reaction mixture. For comparison, methylsulfonimidamide (as the representative of alkyl sulfonimidamides) was tested under similar conditions. Dissimilarly, the oligomerization occurred slowly, and the N,N'‐dicarbamoylation is needed for an adequate separation of the oligomeric derivatives by HPLC. Oligomerization is an unexpected but inherent feature of sulfonimidamides, thus it is suggested that sulfonimidamides should be prepared in the HCl form or the TBS‐protected derivatives to minimize the risk of formation of oligomers. Additionally, this work provides a simple approach to access oligomeric sulfonimidamides, an unexplored motif.

Two-Step Solvent-Free Synthesis of Poly(hydroxybutyrate)-Based Photocurable Resin with Potential Application in Stereolithography.

A bio-based polymeric ink for stereolithography developed through a two-step solvent-free process is herein proposed. Specifically, low-molecular-weight poly(hydroxybutyrate) (PHB)-diol oligomers are prepared via molten transesterification of bacterial PHB with 1,4-butanediol. Transesterification conditions such as diol concentration, catalyst amount, and reaction time are studied for optimizing the final oligomers' molecular weight and structural features. In the second step, the oligomeric hydroxyl terminals are converted into methacrylate moieties through a solvent-free end-capping reaction and diluted in propylene carbonate in order to obtain a photo-polymerizable ink with suitable viscosity. The ink is UV-cured, and the obtained material properties are investigated by FT-IR and differential scanning calorimetry measurements. The proposed method provides a valuable and environmentally friendly alternative to currently available synthetic routes, overcoming their typical disadvantages related to the used solvents and harsh conditions. Moreover, it opens up a sustainable route for converting polyesters into functionalized oligomeric derivatives, which can potentially find application in 3D printing of customized biomedical devices.