Antibacterial Hydrogel Adhesives Based on Bifunctional Telechelic Dendritic-Linear-Dendritic Block Copolymers.

Antibiotic-resistant pathogens have been declared by the WHO as one of the major public health threats facing humanity. For that reason, there is an urgent need for materials with inherent antibacterial activity able to replace the use of antibiotics, and in this context, hydrogels have emerged as a promising strategy. Herein, we introduce the next generation of cationic hydrogels with antibacterial activity and high versatility that can be cured on demand in less than 20 s using thiol-ene click chemistry (TEC) in aqueous conditions. The approach capitalizes on a two-component system: (i) telechelic polyester-based dendritic-linear-dendritic (DLDs) block copolymers of different generations heterofunctionalized with allyl and ammonium groups, as well as (ii) polyethylene glycol (PEG) cross-linkers functionalized with thiol groups. These hydrogels resulted in highly tunable materials where the antibacterial performance can be adjusted by modifying the cross-linking density. Off-stoichiometric hydrogels showed narrow antibacterial activity directed toward Gram-negative bacteria. The presence of pending allyls opens up many possibilities for functionalization with biologically interesting molecules. As a proof-of-concept, hydrophilic cysteamine hydrochloride as well as N-hexyl-4-mercaptobutanamide, as an example of a thiol with a hydrophobic alkyl chain, generated three-component networks. In the case of cysteamine derivatives, a broader antibacterial activity was noted than the two-component networks, inhibiting the growth of Gram-positive bacteria. Additionally, these systems presented high versatility, with storage modulus values ranging from 270 to 7024 Pa and different stability profiles ranging from 1 to 56 days in swelling experiments. Good biocompatibility toward skin cells as well as strong adhesion to multiple surfaces place these hydrogels as interesting alternatives to conventional antibiotics.

Synthesis and Characterization of Amino-Functional Polyester Dendrimers Based On Bis-MPA with Enhanced Hydrolytic Stability and Inherent Antibacterial Properties.

Polyester dendrimers based on 2,2 bis(hydroxymethyl)propionic acid have been reported to be degradable, non-toxic, and exhibit good antimicrobial activity when decorated with cationic charges. However, these systems exhibit rapid depolymerization, from the outer layer inwards in physiological neutral pHs, which potentially restricts their use in biomedical applications. In this study, we present a new generation of amine functional bis-MPA polyester dendrimers with increased hydrolytic stability as well as antibacterial activity for Gram-positive Staphylococcus aureus (S. aureus) and Gram-negative Escherichia coli (E. coli) and Pseudomonas aeruginosa (P. aeruginosa) planktonic bacteria strains. These new derivatives show generally good cytocompatibility for the concentrations they are active toward bacteria, in monocyte/macrophage-like cells (Raw 264.7), and human dermal fibroblasts. Fluoride - promoted esterification chemistry, anhydride chemistry, and click reactions were utilized to produce a library from generations 1-3 and with cationic peripheral groups ranging from 6 to 24 groups, respectively. The dendrimers were successfully purified using conventional purification techniques as well as characterized by matrix-assisted laser desorption ionization time-of-flight mass spectroscopy, nuclear magnetic resonance, and size exclusion chromatography. As proof of synthetic versatility, dendritic-linear-dendritic block copolymer were successfully synthesized to display cysteamine peripheral functionalities as well as the scaffolding ability with biomedically relevant lipoic acid and methoxy polyethylene glycol.

Dendritic Scaffold onto Titanium Implants. A Versatile Strategy Increasing Biocompatibility.

Osseointegration of metal prosthetic implants is a yet unresolved clinical need that depends on the interplay between the implant surface and bone cells. The lack of a relationship between bone cells and metal has traditionally been solved by coating the former with "organic" ceramics, such as hydroxyapatite. A novel approach is hereby presented, immobilizing covalently dendrimeric structures onto titanium implants. Amide-based amino terminal dendrons were synthetized and coupled to titanium surfaces in a versatile and controlled way. The dendritic moieties provide an excellent scaffold for the covalent immobilization of bioactive molecules, such as extracellular matrix (ECM) protein components or antibiotics. Herein, tripeptide arginine-glycine-aspartic acid (RGD) motifs were used to decorate the dendritic scaffolds and their influence on cell adhesion and proliferation processes was evaluated.

Platinum-Doped Dendritic Structure as a Phosphorescent Label for Bacteria in Two-Photon Excitation Microscopy.

Herein, we present a water-soluble dendritric Pt(II) complex as a phosphorescent label for bacterial cells. The dendritic moiety endows the Pt(II) complex with unique properties such as water solubility, shielding from quenching by dioxygen, and binding to bacterial surfaces. The new biosensor was employed for two-photon excitation microscopy, and the binding was confirmed by electron microscopy, which demonstrates that such hybrid arrays can provide orthogonal yet complementary readouts.

Synthesis of Amino Terminal Clicked Dendrimers. Approaches to the Application as a Biomarker.

Herein, we present an easy and efficient synthesis of amino terminal dendrons, combining protection/deprotection reactions with copper-catalyzed azide alkyne cycloaddition in a convergent way. This new approach affords dendrons in gram scale with excellent yields and easy purification. By choosing the appropriate azido-functionalized core, these dendrons lead to a more efficient and controlled convergent synthesis of dendrimers with different sizes and shapes and multivalence. The amino terminal dendrimers were analyzed by diffusion-ordered spectroscopy experiments. The observed dendrimer size is in excellent correlation with the expected size and shape by molecular dynamic simulations. The construction of these kinds of nanostructures, in a simple and efficient way, opens new opportunities for biomedical applications. Moreover, by choosing the appropriate core, these versatile macromolecules become an excellent fluorescent biomarker.

Dendrimeric Antigens for Drug Allergy Diagnosis: A New Approach for Basophil Activation Tests.

Dendrimeric Antigens (DeAns) consist of dendrimers decorated with multiple units of drug antigenic determinants. These conjugates have been shown to be a powerful tool for diagnosing penicillin allergy using in vitro immunoassays, in which they are recognized by specific IgE from allergic patients. Here we propose a new diagnostic approach using DeAns in cellular tests, in which recognition occurs through IgE bound to the basophil surface. Both IgE molecular recognition and subsequent cell activation may be influenced by the tridimensional architecture and size of the immunogens. Structural features of benzylpenicilloyl-DeAn and amoxicilloyl-DeAn (G2 and G4 PAMAM) were studied by diffusion Nuclear Magnetic Resonance (NMR) experiments and are discussed in relation to molecular dynamics simulation (MDS) observations. IgE recognition was clinically evaluated using the basophil activation test (BAT) for allergic patients and tolerant subjects. Diffusion NMR experiments, MDS and cellular studies provide evidence that the size of the DeAn, its antigen composition and tridimensional distribution play key roles in IgE-antigen recognition at the effector cell surface. These results indicate that the fourth generation DeAns induce a higher level of basophil activation in allergic patients. This approach can be considered as a potential complementary diagnostic method for evaluating penicillin allergy.

Use of the Basophil Activation Test May Reduce the Need for Drug Provocation in Amoxicillin-Clavulanic Allergy.

BACKGROUND: Reports of selective reactions to clavulanic acid (CLV) have increased in recent decades because of its increased prescription in combination with amoxicillin (AX) as AX-CLV. Basophil activation test (BAT) is used for diagnosing beta-lactam immediate hypersensitivity and is the only available in vitro assay for diagnosing patients with immediate hypersensitivity to CLV. However, few studies, and with limited numbers of patients have been published. OBJECTIVE: The aim of this study was to establish the sensitivity, specificity, and negativization rates of BAT to AX and CLV. METHODS: We studied 115 patients with immediate allergic reactions after AX-CLV treatment, 57 with selective reactions to AX (group A), 58 with selective reactions to CLV (group B), and 28 tolerant subjects. BAT was performed with AX in group A and with CLV in group B. A 4-year follow-up study was performed in patients with an initial positive BAT result. RESULTS: The overall sensitivity of BAT was 55%, specificity 89%, and positive predictive value (PPV) 96%. For group A, sensitivity was 47%, specificity 93%, and PPV 93%; for group B, sensitivity was 62%, specificity 89%, and PPV 92%. Follow-up study showed a faster negativization rate of BAT for group A, with around 40% of patients becoming negative at 12 months in both groups. CONCLUSIONS: The high PPV of BAT to CLV shows its potential value as a complementary tool to the allergological workup of patients with immediate allergic reactions after AX-CLV treatment. Importantly, the assay should be done within the first 12 months after the reaction to reduce false-negative results.

Development of nanostructures in the diagnosis of drug hypersensitivity reactions.

PURPOSE OF REVIEW: This article provides an overview of novel nanoscale structures potentially applicable to the field of allergy, and to discuss the required properties, advantages, and disadvantages of those nanostructures for clinical application focusing on diagnosis of drug hypersensitivity reactions. RECENT FINDINGS: Advances in the development of different nanostructures are favoring their biomedical applications. One area of interest is the interaction between nanostructures and the immune system, including their ability to emulate carrier molecules and their potential use for the diagnosis of allergic reactions. SUMMARY: Immunoassays are the most widely used in-vitro test for evaluating immunoglobulin E (IgE)-mediated drug hypersensitivity reactions. However, they have important technical limitations affecting their sensitivity. A wide variety of nanostructures have been designed to quantify specific IgE, with the aim of diagnosing different kinds of allergies. Nanoparticles-based colloidal immunoassay employed in microdevices and/or miniaturized systems are improving IgE detection sensitivity. Dendrimers have shown immense potential for the design and development of sensor platforms for evaluating IgE-mediated drug hypersensitivity reactions, due to the increase in hapten density and IgE accessibility. In this sense, a variety of dendritic structures as well as their hybridization to different solid supports have been shown to be successful when applied in the diagnosis of drug allergy. Moreover, the knowledge of the complete antigenic determinants would allow their inclusion and therefore further improvement of the sensitivity.