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The book compiles scientific articles describing advances in nanomaterial synthesis and their application in water remediation. The publications treat diverse problems such as dye degradation, heavy metal ion, as well as radioactive element capture and sequestration. There are 10 original research articles and one review article. The latter proposes graphene/CNT and Prussian blue nanocomposites for radioactive 137-cesium extraction from aqueous media. All reports thoroughly characterize the nanomaterials post-synthesis and describe their catalytic, photocatalytic, or ion exchange activities in contaminated water. The dyes studied in the collection are azo dyes, i.e. methylene blue and orange, rhodamine B, phenolic dyes viz. bromophenol blue, and other dyes with sulfonyl groups. Extraction of radioactive elements, including cationic 137Cs+ and anionic 125I?, is also investigated. The omnipresence of ZnO nanoparticles in everyday products and their effects in wastewater are also evaluated. Layered double hydroxide are capable of capturing Ag ions, which then has a catalytic effect on dye degradation. The nanomaterials considered are varied, viz., graphene, CNT, Prussian blue, nanoporous carbon, layered double hydroxides, magnetite, ferrites, organic powders, polymer membranes, bacteria, and inorganic nanomaterials such as MnO and Ag. The book targets an interdisciplinary readership.

LDHs --- magnetic photocatalyst --- n/a --- bioremediation --- membrane --- BiOCl --- BiVO4 --- degradation --- agglomeration --- solvent vapor annealing --- nanoporous carbon --- nanocomposite --- Prussian blue --- stability --- silver nanomaterials --- adsorption --- wastewater --- desalination --- ZnO nanoparticles --- film --- magnetic performance --- metal-organic frameworks --- 137Cs+ selectivity --- nanomixtures --- water remediation --- photocatalytic activity --- adsorption properties --- magnetic extraction --- RGO --- structural regularity --- photocatalytic mechanism --- wastewater treatment --- 137-Cesium --- photocatalyst --- magnetic nanoparticles --- graphene --- radioactive iodine --- carbon nanotubes --- doping modification --- electrospinning --- radioactive contamination --- Mn–Zn ferrite --- mixed wastewater --- manganese oxide --- host–guest interaction --- bromophenol blue --- Dy3+ --- organic pollutants --- dye --- beta-cyclodextrin polymer --- polydopamine --- interaction --- dye removal --- adsorption models --- RhB photodegradation --- hydrothermal method --- supercapacitor --- Mn-Zn ferrite --- host-guest interaction

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This Special Issue is one of the first for the new MDPI flagship journal Chemistry (ISSN 2624-8549) which has a broad remit for publishing original research in all areas of chemistry. The theme of this issue is Supramolecular Chemistry in the 3rd Millennium and I am sure that this topic will attract many exciting contributions. We chose this topic because it encompasses the unity of contemporary pluridisciplinary science, in which organic, inorganic, physical and theoretical chemists work together with molecular biologists and physicists to develop a systems-level understanding of molecular interactions. The description of supramolecular chemistry as ‘chemistry beyond the molecule’ (Jean-Marie Lehn, Nobel Lecture and Gautam R. Desiraju, Nature, 2001, 412, 397) addresses the wide variety of weak, non-covalent interactions that are the basis for the assembly of supramolecular architectures, molecular receptors and molecular recognition, programed molecular systems, dynamic combinatorial libraries, coordination networks and functional supramolecular materials. We welcome submissions from all disciplines involved in this exciting and evolving area of science.

anion binding --- chloride receptor --- switchable system --- hydroquinone --- redox switch --- metal-organic frameworks --- vapour sorption --- solvatochromism --- desorption kinetics --- ion-channels --- crown-ethers --- bilayer membranes --- self-assembly --- supramolecular chemistry --- host–guest chemistry --- coordination cage --- catalysis --- crystal structure --- copper chloride complexes --- H-bonding pattern --- tetrazole ligands --- X-ray diffraction --- Hirshfeld surfaces --- uranium(VI) --- carboxylates --- capsules --- structure --- luminescence --- multicomponent cocrystal --- cocrystallization mechanism --- cocrystal synthesis --- crystal engineering --- porous material --- molecular recognition --- halogen bond --- co-crystal --- molecular tecton --- binary solid --- network structure --- σ-hole --- molecular electrostatic potential --- calixarenes --- coordination clusters --- manganese --- molecular magnetism --- host–guest interaction --- cucurbit[7]uril --- 4-pyrrolidinopyridinium --- copper complexes --- chlorido ligand displacement --- catalysis regulation --- Schiff base ligands --- urea hydrolysis --- coordination chemistry --- hydrogen bonds --- metalla-assemblies --- coordination-driven self-assembly --- orthogonality --- ligands --- metal ions --- complementarity --- hydrogen bonding --- cyclotricatechylene --- metal–organic cage --- helicate --- metallosupramolecular --- chirality --- copper(II) complexes --- pyrazolato ligands --- supramolecular assembly --- X-ray crystallography --- magnetic susceptibility --- EPR spectroscopy --- isotropic exchange --- antisymmetric exchange --- dipolar interaction --- DFT calculations --- hydrogen bond --- pyrazine --- chloropyrazine --- chloropyrazin-2-amine --- copper halide --- supramolecular structure --- conformational polymorphism --- intermolecular contacts --- N,N′,N″,N‴-Tetraisopropylpyrophosphoramide --- pyrophosphoramide --- synthons --- supramolecular motifs --- n/a --- host-guest chemistry --- host-guest interaction --- metal-organic cage --- N,N',N",N‴-Tetraisopropylpyrophosphoramide

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Development of new drug molecules is costly and requires longitudinal, wide-ranging studies; therefore, designing advanced pharmaceutical formulations for existing and well-known drugs seems to be an attractive device for the pharmaceutical industry. Properly formulated drug delivery systems can improve pharmacological activity, efficacy and safety of the active substances. Advanced materials applied as pharmaceutical excipients in designing drug delivery systems can help solve problems concerning the required drug release—with the defined dissolution rate and at the determined site. Novel drug carriers enable more effective drug delivery, with improved safety and with fewer side effects. Investigations concerning advanced materials represent a rapidly growing research field in material/polymer science, chemical engineering and pharmaceutical technology. Exploring novel materials or modifying and combining existing ones is now a crucial trend in pharmaceutical technology. Eleven articles included in the the Special Issue “Advanced Materials in Drug Release and Drug Delivery Systems” present the most recent insights into the utilization of different materials with promising potential in drug delivery and into different formulation approaches that can be used in the design of pharmaceutical formulations.

mesoporous silica --- layer-by-layer --- FITC-peptide --- hyaluronic acid --- multilayer film --- host-guest interaction --- total alkaloids from Alstonia scholaris leaves --- mPEG-PLA --- microspheres --- drug release --- biocompatibility --- CO administration --- therapeutic agent --- pharmaceutical drugs --- heme oxygenase --- CO-releasing materials --- CO-releasing molecules --- organometallic complexes --- pharmacokinetic functions --- pathological role --- CO kinetic profile --- cellular targets --- GQDs --- real-time tracking --- optical-magneto nanoparticles --- in vivo --- ethylcellulose --- polymeric material --- cellulose derivative --- pharmaceutical excipient --- hydrogel --- drug delivery --- polymer --- immobilization of drug --- gelatin --- gastro-resistant --- films --- capsules --- structure --- sirolimus --- electrospinning --- polycaprolactone --- 3D matrix --- drug-eluting stents --- spray drying --- microparticles --- rupatadine fumarate --- orodispersible minitablets --- taste masking --- Bicalutamide --- Poloxamer® 407 --- Macrogol 6000 --- supercritical carbon dioxide --- solid dispersions --- dissolution rate --- amorphization --- 3D printing --- fused deposition modeling --- hot-melt extrusion --- solid dosage forms --- itraconazole --- n/a

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This Special Issue is one of the first for the new MDPI flagship journal Chemistry (ISSN 2624-8549) which has a broad remit for publishing original research in all areas of chemistry. The theme of this issue is Supramolecular Chemistry in the 3rd Millennium and I am sure that this topic will attract many exciting contributions. We chose this topic because it encompasses the unity of contemporary pluridisciplinary science, in which organic, inorganic, physical and theoretical chemists work together with molecular biologists and physicists to develop a systems-level understanding of molecular interactions. The description of supramolecular chemistry as ‘chemistry beyond the molecule’ (Jean-Marie Lehn, Nobel Lecture and Gautam R. Desiraju, Nature, 2001, 412, 397) addresses the wide variety of weak, non-covalent interactions that are the basis for the assembly of supramolecular architectures, molecular receptors and molecular recognition, programed molecular systems, dynamic combinatorial libraries, coordination networks and functional supramolecular materials. We welcome submissions from all disciplines involved in this exciting and evolving area of science.

Technology: general issues --- anion binding --- chloride receptor --- switchable system --- hydroquinone --- redox switch --- metal-organic frameworks --- vapour sorption --- solvatochromism --- desorption kinetics --- ion-channels --- crown-ethers --- bilayer membranes --- self-assembly --- supramolecular chemistry --- host-guest chemistry --- coordination cage --- catalysis --- crystal structure --- copper chloride complexes --- H-bonding pattern --- tetrazole ligands --- X-ray diffraction --- Hirshfeld surfaces --- uranium(VI) --- carboxylates --- capsules --- structure --- luminescence --- multicomponent cocrystal --- cocrystallization mechanism --- cocrystal synthesis --- crystal engineering --- porous material --- molecular recognition --- halogen bond --- co-crystal --- molecular tecton --- binary solid --- network structure --- σ-hole --- molecular electrostatic potential --- calixarenes --- coordination clusters --- manganese --- molecular magnetism --- host-guest interaction --- cucurbit[7]uril --- 4-pyrrolidinopyridinium --- copper complexes --- chlorido ligand displacement --- catalysis regulation --- Schiff base ligands --- urea hydrolysis --- coordination chemistry --- hydrogen bonds --- metalla-assemblies --- coordination-driven self-assembly --- orthogonality --- ligands --- metal ions --- complementarity --- hydrogen bonding --- cyclotricatechylene --- metal-organic cage --- helicate --- metallosupramolecular --- chirality --- copper(II) complexes --- pyrazolato ligands --- supramolecular assembly --- X-ray crystallography --- magnetic susceptibility --- EPR spectroscopy --- isotropic exchange --- antisymmetric exchange --- dipolar interaction --- DFT calculations --- hydrogen bond --- pyrazine --- chloropyrazine --- chloropyrazin-2-amine --- copper halide --- supramolecular structure --- conformational polymorphism --- intermolecular contacts --- N,N',N",N‴-Tetraisopropylpyrophosphoramide --- pyrophosphoramide --- synthons --- supramolecular motifs