Unprecedented Biodegradable Cellulose-Derived Polyesters with Pendant Citronellol Moieties: From Monomer Synthesis to Enzymatic Degradation

Levoglucosenone (LGO) is a cellulose-derived molecule that is present commercially on a multi-ton/year scale. Taking advantage of the α,β-conjugated ketone of LGO, a new citronellol-containing 5-membered lactone (HBO-citro) was synthesized through a one-pot two-step pathway involving oxa-Michael addition and Baeyer-Villiger oxidation. The solvent-free treatment of HBO-citro with NaBH4 at room temperature led to the full reduction of the lactone moiety which gave a novel fully renewable triol monomer having a citronellol side chain (Triol-citro). Noticeably, by simply changing the reducing agent, temperature and reaction duration, the partial reduction of HBO-citro can be achieved to yield a mixture of 5- and 6-membered Lactol-citro molecules. Triol-citro was chosen to prepare functional renewable polyesters having citronellol pendant chains via polycondensation reactions with diacyl chlorides having different chain lengths. Good thermal stability (Td5% up to 170 °C) and low glass transition temperatures (as low as −42 °C) were registered for the polyesters obtained. The polymers were then hydrolyzed using a commercial lipase from Thermomyces lanuginosus (Lipopan® 50 BG) to assess their biodegradability. A higher degradation profile was found for the polyesters prepared using co-monomers (acyl chlorides) having longer chain lengths. This is likely due to the decreased steric hindrance around the ester bonds which allowed enhanced accessibility of the enzyme.

Synthesis and Characterization of 2-Decenoic Acid Modified Chitosan for Infection Prevention and Tissue Engineering

Chitosan nanofiber membranes are recognized as functional antimicrobial materials, as they can effectively provide a barrier that guides tissue growth and supports healing. Methods to stabilize nanofibers in aqueous solutions include acylation with fatty acids. Modification with fatty acids that also have antimicrobial and biofilm-resistant properties may be particularly beneficial in tissue regeneration applications. This study investigated the ability to customize the fatty acid attachment by acyl chlorides to include antimicrobial 2-decenoic acid. Synthesis of 2decenoyl chloride was followed by acylation of electrospun chitosan membranes in pyridine. Physicochemical properties were characterized through scanning electron microscopy, FTIR, contact angle, and thermogravimetric analysis. The ability of membranes to resist biofilm formation by S. aureus and P. aeruginosa was evaluated by direct inoculation. Cytocompatibility was evaluated by adding membranes to cultures of NIH3T3 fibroblast cells. Acylation with chlorides stabilized nanofibers in aqueous media without significant swelling of fibers and increased hydrophobicity of the membranes. Acyl-modified membranes reduced both S. aureus and P. aeruginosa bacterial biofilm formation on membrane while also supporting fibroblast growth. Acylated chitosan membranes may be useful as wound dressings, guided regeneration scaffolds, local drug delivery, or filtration.

Gram-scale Preparation of Acyl Fluorides and Their Reactions with Hindered Nucleophiles

A series of acyl fluorides was synthesized at 100 mmol scale using phase transfer catalyzed halogen exchange between acyl chlorides and aqueous bifluoride solution. The convenient procedure consists of vigorous stirring of the biphasic mixture at rt, followed by extraction and distillation. Isolated acyl fluorides (usually 7 g to 20 g) display excellent purity, and can be transformed into sterically hindered amides and esters, when treated with lithium amide bases and alkoxides under mild conditions.

Regioselective Iodine/Zinc-Exchange for the Selective Functionalization of Polyiodinated Arenes and Heterocycles in Toluene

Regioselective I/Zn-exchange reactions were performed on polyiodinated arenes or heterocycles within 20 min at 0-25 °C using the bimetallic combination pTol2Zn·2LiOR (R = (CH2)2N(Me)(CH2)2NMe2) in toluene. The resulting diaryl- or di(hetero)aryl-zincs reacted well with allylic bromides and acyl chlorides to provide functionalized (hetero)aryl iodides in good yields.

Preparation of Functionalized Diorganomagnesium Reagents in Toluene via Bromine or Iodine/Magnesium-Exchange Reactions

A wide range of polyfunctionalized di(hetero)aryl- and dialkenyl-magnesium reagents were prepared in toluene within 10 to 120 min between −78 °C and 25 °C via an I/Mg- or Br/Mg-exchange reaction using reagents of the general formula R2Mg (R = sBu, Mes). Highly sensitive functional groups, such as a triazene or a nitro group, were tolerated in these exchange reactions, enabling the synthesis of various functionalized (hetero)arenes and alkenes derivatives after quenching with several electrophiles including allyl bromides, acyl chlorides, aldehydes, ketones, and aryl iodides.

Organophosphane-Catalyzed Construction of Functionalized 2-Ylideneoxindoles via Direct β-Acylation

We report an efficient method for the direct β-acylation of 2-ylideneoxindoles with acyl chlorides in the presence of base-catalyzed by organophosphanes. A variety of functionalized 2-ylideneoxindoles were prepared in moderate to good yields under metal-free and mild conditions via a tandem phospha-Michael/O-acylation/intramolecular cyclization/ rearrangement sequence. The mechanistic investigations revealed that the C-O bond cleavage on possible betaine intermediate is the key step for the installation of keto-functionality at β-position of 2-ylideneoxindoles in a highly stereospecific manner. The synthetic utility of this protocol could also be proven by scale-up reactions and synthetic transformations of the products.

A Study of the Regiochemistry in the Synthesis of Pyrano[3,4-c]pyridines

Aims: Biological studies have shown that some condensed derivatives of pyrano[3,4-c]pyridines 6 exhibited pronounced biological activity. Considering these results, the principal aim of this work is to study the regiochemistry of the synthesis of pyrano[3,4-c]pyridines 6, optimize the reaction conditions, and increase the previously observed low yields of pyrano[3,4-c]pyridines. Background: Several years ago, a method for the preparation of 6-oxopyrano[3,4-c]pyridines 6 starting from 2,2-dimethyltetrahydro-4H-pyran-4-one 1 was developed. In this study, we have separated and identified only the most expected reaction products of 6-oxopyrano[3,4-c]pyridines 6. On the basis of this datum, we suggested that the enamines 2 and 3 reacting with acyl chlorides were not acylated at C-3 and that 5-acylpyran-4-ones 4 were the only products of the reaction. We have justified this result by considering the steric effects exerted by the two methyl groups present in the pyran ring. Moreover, we did not identify the products at the second reaction center: that is, the isomeric compounds 7. This result was justified considering the different reactivity of aliphatic and cyclic ketone groups. Objective: The main objectives of this work are as follows: a) implementation of the reaction of 2,2-dimethyltetrahydro-4H-pyran-4-one 1 with morpholine; b) acylation of the obtained enamines 2 and 3 with acyl chlorides under Stork conditions; c) synthesis of pyranopyridines 6–8 based on β-diketones: 3-acylpyran-4-ones 4 and 5-acylpyran-4-ones 5; d) confirmation of the structure of the obtained compounds. Method: For the synthesis of pyrano[3,4-c]pyridines, known methods were used. Thus, the reaction of starting 2,2-dimethyltetrahydro-4H-pyran-4-one 1 with morpholine in benzene led to the formation of isomeric enamines 2 and 3. Then, they were acylated with acyl chlorides under Stork conditions with the formation of two β-diketones: 3-acylpyran-4-ones 4 and 5-acylpyran-4-ones 5. Finally, in order to obtain the aimed pyrano[3,4-c]pyridines 6, the obtained β-dicarbonyl compounds 4 and 5 (as a mixture of isomers) were reacted with 2-cyanoacetamide in ethanol in the presence of diethylamine, according to the Knoevenagel condensation. The structure of the obtained compounds has been unambiguously confirmed by using a wide spectrum of physicochemical methods (NMR, IR, X-ray structural and elemental analysis) and, in the instance of compounds 7, also by an alternative synthesis. Results: Starting from the 2,2-dimethyltetrahydro-4H-pyran-4-one 1, a series of new and already known 6-oxopyrano[3,4-c]pyridines 6 were synthesized. As a result of the study of the regiochemistry in the synthesis of pyrano[3,4-c]pyridines, out of the four possible isomer pyranopyridines 6−9, we have succeeded to identify three of them (6−8). Thus, isomer pyranopyridines 7 and 8 were identified in the mixture with the main compounds 6. Moreover, isomeric pyrano[3,4-c]pyridines 8 were detected when alkyl groups are present in the starting compounds 4 and 5, while isomeric pyrano[4,3-b]pyridines 7 were detected in the case of the presence of aromatic groups. Unfortunately, we have not been able to isolate compounds 7 and 8 in the pure state from the reaction mixtures. Currently, we have not been able to detect and identify isomeric pyrano[4,3-b]pyridines 9. On the whole, we have been able to increase the effectiveness of the synthesis of pyrano[3,4-c]pyridines 6, increasing their yields by ≈ 5–15%. Conclusion: As a result of our investigation, we have found that the acylation reaction of enamines 2 and 3 and the cyclization reaction of β-diketones 4 and 5 are not regioselective. Therefore we can state that enamines 2 and 3 can be acylated at both C-3 and C-5 with the formation of a mixture of 3-acylpyran-4-ones 4 and 5-acylpyran-4-ones 5. Their condensation with 2-cyanoacetamide led to the formation of mixtures of regioisomeric pyranopyridines 6−8. In conclusion, as a result of our present research, we can say that we have been able to increase the effectiveness of the synthesis of pyranopyridines, largely improving our previous results։ Other: Currently, we are working to look for the fourth isomeric pyrano[4,3-b]pyridines 9 by using the most modern and fine methods. Moreover, we hope that we would be able to separate the mixtures of pyranopyridines 6–8 so that they can be used for further syntheses.