Artur Kasprzak

Conjugation of polyethylenimine and its derivatives to carbon-encapsulated iron nanoparticles

Carbon-based nanomaterials functionalized by cationic polymers are interesting starting materials for the development of nanotheranostic systems. In this study, polyethylenimine (PEI) and its pre-synthesized derivatives were conjugated to carbon-encapsulated iron nanoparticles (CEINs). Branched PEIs of various molecular weight were derivatized. The aim of the polymer modification was to introduce carboxylic functionality to the PEI structure. Two different synthetic pathways were proposed: the amide-type reaction with succinic acid anhydride and reductive amination using p-formylbenzoic acid. The polyethylenimine derivatives were analyzed by means of spectroscopic methods (NMR and FT-IR). In order to determine the ratio of primary, secondary and tertiary amine groups in the modified polymers, inverted-gate 13C NMR spectroscopy was applied. Next, CEINs modified with two different surface carboxylic linkers were functionalized using pristine PEI and its derivatives. The conjugation of the polymer to the surface-modified nanoparticles was carried out using the carbodiimide–amine type reaction. The success of the conjugation process was confirmed by thermogravimetry and infrared spectroscopy. The morphological details were analyzed using transmission electron microscopy, whilst the surface zeta potential and the average particle size were determined by dynamic light scattering. It was found that the molecular weight of the polymer and the type of the surface linker were the key factors which crucially influenced the functionalization yield and the physicochemical features of the synthesized nanoplatforms. The best dispersion stability in aqueous media and the smallest mean hydrodynamic particle size was found for CEINs with the longer carboxylic linker.

Grinding-induced functionalization of carbon-encapsulated iron nanoparticles

Covalent functionalization of carbon-encapsulated iron nanoparticles based on the grinding-induced 1,3-cycloaddition reaction of nitrile oxides is presented. We report an easy to perform, fast and efficient method for the direct introduction of various types of functional moieties, such as carboxylic, metallocene and sugar units, into carbon-encapsulated iron nanoparticles.

Sulfhydrylated graphene-encapsulated iron nanoparticles directly aminated with polyethylenimine: a novel magnetic nanoplatform for bioconjugation of gamma globulins and polyclonal antibodies

This study presents for the first time the direct amination of graphene-encapsulated iron nanoparticles (GEINs) with polyethylenimine (PEI) via radical-type reaction. This work describes the first example of a direct addition of N-centered radical species onto the graphene layer. The pristine PEI and the PEI attached to GEINs have also been derivatized to introduce sulfhydryl functionalities. The proposed two-step protocol constitutes a novel, versatile and low cost method for the synthesis of polymer derivatives decorated with SH moieties. The derivatives of pristine polyethylenimine were analyzed by means of spectroscopic methods (NMR and IR), while the obtained carbon materials were studied by thermogravimetry, infrared spectroscopy, dynamic light scattering, and transmission electron microscopy. Finally, the concomitant part of this work focused on the bioconjugation type reactions of various biocompounds, including bovine gamma-globulins and human polyclonal antibodies of class IgG, with the as-obtained sulfhydrylated GEINs-PEI nanoplatform. The presence of immobilized molecules was confirmed by thermogravimetry, protein and fluorescence assays as well as confocal microscopy images.

Nanoconjugates of ferrocene and carbon-encapsulated iron nanoparticles as sensing platforms for voltammetric determination of ceruloplasmin in blood

The nanoparticles comprising of iron core and carbon shell were decorated with ferrocene derivatives: ferrocenecarboxaldehyde (Fc-1) and ferrocenecarboxaldehyde oxime (Fc-2). A microdrop of suspension of the nanoconjugate was placed on a glassy-carbon electrode to prepare the recognition/sensing layer. Drying and purification of the sensing layer resulted in a well-defined and stable square-wave voltammogram of the ferrocene moiety. The height of the voltammetric peak increased in the presence of ceruloplasmin. That increase was linearly dependent on the logarithmic concentration of ceruloplasmin in blood. The applied external magnetic field was a factor which yielded better sensitivity and repeatability of the sensor response. The linearity of sensor response was found to be between 0.001 and 10μgdL-1 and 0.05-10μgdL-1 for both nanoconjugates: Fe@C-Fc-1 and Fe@C-Fc-2, in the presence and absence of the magnet, respectively. The obtained detection limit (LOD) for Fe@C-Fc-1 was found to be 0.60 and 0.10μgdL-1 in the absence and presence of magnetic field, respectively, whilst for Fe@C-Fc-2 was 0.4 and 0.07μgdL-1 in the absence and presence of a magnet, respectively. The proposed method is selective because the presence of common antioxidants in blood did not interfere significantly with the determination of the concentration of ceruloplasmin.

Novel non-covalent stable supramolecular ternary system comprising of cyclodextrin and branched polyethylenimine

The synthesis of a novel supramolecular system comprising of branched polyethylenimine and cyclodextrin, is presented. The synthesis route is based on the self-assembly phenomena with the inclusion of solvent molecules. The systems are formed by a hydrogen-bonding network and host–guest type interactions between the building blocks. It was found that the native cyclodextrin and polyethylenimine are able to form stable systems when the reaction medium constitutes a polar solvent forming host–guest type complexes with cyclodextrin. A special consideration was paid on the detailed spectroscopic analyses of the obtained water-soluble constructs, including ROESY and diffusion-ordered (DOSY) NMR spectroscopy studies. The versatility and significance of DOSY technique for the analysis of the cyclodextrin complexes and its non-covalent systems with branched polymers, were presented. It was also found that the guest molecules that were incorporated in the complexes exhibited enhanced thermal stability. The morphological details in the solid state were obtained by scanning electron microscope.Graphical Abstract

New Insight into the Synthesis and Biological Activity of the Polymeric Materials Consisting of Folic Acid and β-Cyclodextrin

This work presents a very new look at folate targeting and is focused on synthesizing and assessing the biological activity of folic acid-targeted drug delivery materials based on β-cyclodextrin. Both folic acid and β-cyclodextrin have been covalently conjugated to branched polyethylenimine as the polymeric vector. Host-guest inclusion of folic acid into a β-cyclodextrin cavity, demonstrated by means of the spectroscopic methods (2-D NMR, IR, UV-Vis), is found to be of crucial importance for biological activity of nanotherapeutics. This paper describes the very first example of the versatile synthetic approach to create the polymeric biosystems, where folic acid activity is not limited by the inclusion phenomenon. Cytotoxicity of the obtained polymeric materials against Lewis lung carcinoma cells is determined by neutral red uptake assay. Folate receptor-binding studies reveal that the developed synthetic approach enables full exploitation of the potential of folic acid as a targeting ligand.

Spectroscopic insight into supramolecular assemblies of boric acid derivatives and β-cyclodextrin

Interactions of select boric acid derivatives with β-cyclodextrin were investigated. All products were obtained employing the grinding-induced mechanochemical approach. It was found that phenylboronic acid, benzoxaborole and boric acid form non-covalent, hydrogen bonding-based systems with β-cyclodextrin, whereas catechol and pinacol esters of phenylboronic acid as well as ferroceneboronic acid form host-guest inclusion complexes. The interactions were probed using spectroscopic methods: 1H NMR, 1H-1H ROESY NMR, 1H DOSY NMR, FT-IR. Association constant values were evaluated by 1H DOSY NMR. The highest association constant was found for boric acid (117.5 ± 2.5 M-1), whilst the lowest for benzoxaborole (14.8 ± 0.3 M-1). The study shows the influence of boron compound structure on the nature of the assembly formed with β-cyclodextrin, laying up the basis for future work with such supramolecular systems.

Occlusion phenomenon of redox probe by protein as a way of voltammetric detection of non-electroactive C-reactive protein

Simple, selective and sensitive analytical devices are of a great importance for medical application. Herein, we developed highly selective immunosensor for electrochemical detection of C-reactive protein (CRP) in blood sample. Branched polyethylenimine functionalized with ferrocene residues (PEI-Fc) was the main element of the recognition layer, which allowed: (i) covalent binding of an antibody in its most favorable orientation and (ii) voltammetric detection of the C-reactive protein. Anchoring of PEI-Fc to the electrode surface through the electrodeposition process leads to the formation of thin, stable and reproducible layers, which is extremely important in the case of electrochemical immunosensing. The proposed analytical device is characterized by high selectivity and sensitivity and can be successfully used in the concentration range of CRP from 1 to 5·104 ng mL-1. The determined limit of detection was circa 0.5 and 2.5 ng mL-1 for voltammetric and impedance analysis, respectively. The developed analytical device has also been successfully applied for the analysis of CRP level in rat blood samples.

Functionalization of graphene: does the organic chemistry matter?

Reactions applying amidation- or esterification-type processes and diazonium salts chemistry constitute the most commonly applied synthetic approaches for the modification of graphene-family materials. This work presents a critical assessment of the amidation and esterification methodologies reported in the recent literature, as well as a discussion of the reactions that apply diazonium salts. Common misunderstandings from the reported covalent functionalization methods are discussed, and a direct link between the reaction mechanisms and the basic principles of organic chemistry is taken into special consideration.