Recent progress in biopolymer nanoparticle and microparticle formation by heat-treating electrostatic protein-polysaccharide complexes

Functional biopolymer nanoparticles or microparticles can be formed by heat treatment of globular protein-ionic polysaccharide electrostatic complexes under appropriate solution conditions. These biopolymer particles can be used as encapsulation and delivery systems, fat mimetics, lightening agents, or texture modifiers. This review highlights recent progress in the design and fabrication of biopolymer particles based on heating globular protein-ionic polysaccharide complexes above the thermal denaturation temperature of the proteins. The influence of biopolymer type, protein-polysaccharide ratio, pH, ionic strength, and thermal history on the characteristics of the biopolymer particles formed is reviewed. Our current understanding of the underlying physicochemical mechanisms of particle formation and properties is given. The information provided in this review should facilitate the rational design of biopolymer particles with specific physicochemical and functional attributes, as well as stimulate further research in identifying the physicochemical origin of particle formation.     

Biopolymer microparticle and nanoparticle formation within a microfluidic device

This paper reports a novel microfluidic method for the production of cross-linked alginate microparticles and nanoparticles. We describe a continuous process relying on both thermodynamic and hydrodynamic factors to form microdroplets. A rapid cross-linking reaction thereafter allows solidification of the polymer droplets either within the microfluidic device or "off-chip" to form alginate micro- and nanoparticles. Monodisperse droplets are generated by extruding an aqueous alginate solution using an axisymmetric flow-focusing design. As they flow downstream in the channel, due to water and the continuous phase being partially miscible, the water diffuses very slowly out of the polymeric droplets into the transport fluid, which causes the shrinkage of the drops and the condensation of the polymer phase. The resulting size of the solid particles depends on the polymer concentration and the ensuing balance between the kinetics of the cross-linking reaction and the volume loss due to solvent diffusion. This work details both a single-step microfluidic technique for the formation of alginate microparticles of sizes ranging from 1 to 50 microm via near-equilibrium solvent diffusion within a microfluidic device and thereafter a two-step method, which was shown to generate biopolymer nanoparticles of sizes ranging from 10 to 300 nm. These novel methodologies are extremely flexible and can be extended to the preparation of micro- and nanoparticles from a wide range of single or mixed synthetic and biologically derived polymers.     

浓度对电荷转移诱导的表面增强拉曼光谱的影响

银溶胶中加入具有双官能团的对氨基苯甲酸分子,功能分子PABA吸附到银粒子上形成Ag-PABA复合物,采用1064nm激发光对复合物进行SERS研究。研究发现,功能分子浓度较低时,b2振动得到极大增强,这是通过功能分子在银纳米粒子间电荷转移的直接结果。浓度较高时,SERS中a1振动占主导地位,因为在这样的体系中,银粒子被功能分子包围,彼此相距较远,跨越粒子的电荷转移被阻断的结果。     

Fabrication of hierarchical microparticles by depositing the in situ synthesized surface nanoparticles on microspheres during the seed emulsion polymerization

A general strategy for the synthesis of polymeric hierarchical microparticles containing surface nanoparticles through modified seed emulsion polymerization is proposed. This modified seed emulsion polymerization has a character that suitable amount of monomer miniemulsion is added during the polymerization. The in situ synthesized surface nanoparticles which are resulted from the monomer miniemulsion as well as the shell-forming polymer coagulate on the seed particles and therefore hierarchical microparticles are fabricated. Various polymeric hierarchical microparticles containing 20-36 nm poly(styrene-co-acrylamide), poly(styrene-co-acrylic acid), and polystyrene surface nanoparticles are synthesized following the proposed method. The advantages in the present synthesis including both the well controls in the size, the composition, and the number of the surface nanoparticles and the convenience are demonstrated. The proposed strategy is anticipated to be a general method to fabricate hierarchical microparticles and is believed to have promising application in particle surface modification.     

Fabrication and Manipulation of Magnetic Composite Particles with Specific Shape and Size

The fabrication of microscale polyethylene glycol diacrylate(PEGDA) hydrogel particles was demonstrated via magnetic property ultraviolet(UV) lithography techniques, polydimethylsiloxane(PDMS) soft stamp pre-paration techniques and micro-nano imprint technology in this paper. The results of compositional and morphological characterizations of magnetic microparticles show that the Fe₃O₄ nanoparticles with an average diameter of 100 nm are uniformly dispersed in hydrogel. Owing to the excellent magnetism of Fe₃O₄ nanoparticles, the fabricated hydrogel microparticles with different sizes and shapes were manipulated in water via applying an external magnetic fields. Three types of motions, translation, rotation and flip, were demonstrated with the manipulator. These microscale magnetic PEGDA hydrogel particles have a great application potential in manufacturing process, micro/nanomotors, and machines.     

Polymer and biopolymer mediated self-assembly of gold nanoparticles

Gold nanoparticle-polymer composites are versatile and diverse functional materials, with applications in optical, electronic and sensing devices. This tutorial review focuses on the use of polymers to control the assembly of gold nanoparticles. Examples of synthetic polymers and biopolymers are provided, as well as applications of the composite materials in sensing and memory devices.     

Green and Functional Aerogels by Macromolecular and Textural Engineering of Chitosan Microspheres

Tremendous interest was recently devoted to the preparation of porous and functional materials through sustainable route, including primarily the use of renewable biopolymers instead of petroleum‐sourced synthetic chemicals. Among the biopolymers available in enormous quantity, chitosan – obtained by deacetylation of chitin – stands as the sole nitrogen‐containing cationic amino‐sugar carbohydrate. This distinctively provides chitosan derivatives with plenty of opportunities in materials science. Particularly, its pH switchable solubility allowed the preparation of three‐dimensional entangled nanofibrillated self‐standing microspheres. These porous hydrogels behave as nano‐reactors to confine exogenous nanoobjects within the polysaccharide network, including sol‐gel metal alkoxide species, organometallic derivatives and isotropic and oriented nanoparticles. Besides, the interfacial interplay of chitosan with lamellar clay and graphene oxide allowed the penetration of the biopolymer inside of the galleries, which result in a complete delamination of the layered nanomaterials. The preserved gelation memory of chitosan in these formulations provides a way to access porous microspheres entangling exfoliated nanometric sheets. CO₂ supercritical drying of functional hydrogel beads enabled efficient removal of water and other liquid solvents without wall collapsing, allowing large‐scale preparation of millimetric hydrocolloidal microspheres with an open macroporous network. These functionalized lightweight biopolymer aerogels find applications in heterogeneous catalysis, sensing, adsorption, insulation and for the design of other sophisticated porous nanostructures. Beyond their tailorable molecular and textural‐engineering, the possibility for macroscopic shaping of these intriguing nanostructures opens many new opportunities, especially in additive‐manufacturing for soft and hybrid robotics.     

Site-specific Deposition of Colloidal Pd Nanoparticles on Self-assembled Microtubules from Biolipid

Lipid microtubules with wound ribbon features were fabricated by self-assembling method, and the deposition patterns of colloidal Pd particles on tubular template were investigated. The result indicates that colloidal Pd nanoparticles are preferentially decorated on the helical markings in the interior and on the exterior of preformed tubule and to the edge of loosely helical ribbons to obtain helical deposition features. The multi-bilayer microstructure of tubules can be marked by fine Pd nanoparticles deposited at the edge of helical ribbon. There are the site-specific interactions between lipid tubular template and colloidal Pd particles at the helical edge. A new route was illustrated that colloidal Pd particles firstly attach at the edge of thin flat membranes, and then thin membranes roll up and reassemble into tubule together with particles to form helical deposition patterns. The site-specific deposition of Pd is unbeneficial to obtain the homogeneous metal film on tubules, but it can be utilized to reveal the different chemical nature of lipid molecular assembly.     

Photoluminescence and spectral holeburning in europium-doped MgS nanoparticles

Luminescence and power-gated spectral holeburning studies have been performed on Eu-doped MgS nanoparticles. These particles are atomically tailored to produce and control the relative concentration of Eu(2+) and Eu(3+), which is necessary for power-gated holeburning. The spectral holes are permanent at low temperatures. Optical studies show that the electron-phonon coupling is stronger in nanoparticles than in thin films or microparticles of the same material. This is the reason for inherently broader spectral holes in nanoparticles as compared to microparticle or thin-film samples. Temperature broadening of spectral holes in nanoparticles follows a T(2.4) behavior, a faster rate than thin films or microparticles. This behavior can be attributed to the glassy nature of the particles produced.     

Non-cytotoxic and bioactive nanocomposite film of natural Arabic gum incorporating TiO2 nanoparticles for bone tissue regeneration

Biomaterials with exceptional biocompatibility and bioactivity are now pushing the boundaries of bone tissue engineering. In this study, natural Arabic gum biopolymer incorporating titanium dioxide nanoparticles (NAG + TiO₂NP) nanocomposite film was fabricated. The FTIR and XRD analysis show the presence of functional groups assigned to NAG biopolymers and highly crystalline anatase TiO₂NP. Well dispersed TiO₂NP can be seen from SEM micrograph suggesting good interaction between TiO₂NP filler and NAG biopolymer matrix to enhance the mechanical characteristics of nanocomposite film. The NAG + TiO₂NP nanocomposite film exhibited strong bioactivity to form bone-like apatite and promoted the proliferation of MG-63 cells attributed to their excellent biocompatibility and non-toxicity. The NAG + TiO₂NP nanocomposite film also displays high antibacterial activity with (36.33 ± 1.53) mm and (27.00 ± 2.00) mm inhibition zone were recorded against Staphylococcus aureus and Escherichia coli. The findings indicate that the NAG + TiO₂NP nanocomposite film, with its improved mechanical properties, high swelling capacity, biodegradability, and non-toxicity, shows promise as a viable option for bone tissue regeneration materials.     

Confinement effects on the structure and dynamics of polymer systems from the mesoscale to the nanoscale

In this article, we review some of our recent progress in experimental and simulation methods for generating, characterizing, and modeling polymer microparticles and nanoparticles in a number of polymer and polymer‐blend systems. By using instrumentation developed for probing single fluorescent molecules in micrometer‐sized liquid droplets, we have shown that polymer particles of nearly arbitrary size and composition can be made with a size dispersion that is ultimately limited by the chain length and number distribution within the droplets. Depending on the timescale for solvent evaporation—a tunable parameter in our experiments—the phase separation of otherwise immiscible polymers can be avoided by confinement effects, and homogeneous polymer‐blend microparticles or nanoparticles can be produced. These particles have tunable properties that can be controlled by the simple adjustment of the size of the particle or the relative mass fractions of the polymer components in solution. Physical, optical, and mechanical properties of a variety of microparticles and nanoparticles, differing in size and composition, have been examined with extensive classical molecular dynamics calculations in conjunction with experiments to gain deeper insights into the fundamental nature of their structure, dynamics, and properties. © 2005 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 43: 1571‐1590, 2005     

Assembly of Gold Nanoparticles on a Molecular Ultrathin Film: Tuning the Surface Plasmon Resonance

A number of methodologies for immobilizing metal nanoparticles in 2‐dimensional aggregate structures on various substrates, some with concomitant tuning of the surface plasmon resonance (SPR), have been reported. Many of them involve special functionalization of the nanoparticles, multiple fabrication steps or lengthy procedures. The present study demonstrates that monolayer Langmuir–Blodgett (LB) film of a hemicyanine‐based amphiphile with cationic headgroup is an easily fabricated platform for harnessing citrate‐stabilized gold nanoparticles. It is shown that a single immersion step can be used to immobilize the nanoparticles uniformly on large area films and that systematic variation of the immersion time from 10 min to 6 h leads to controlled assembly of the particles and tuning of the SPR band over ～100 nm. A model for the structural reorganization in the LB film that facilitates the assembly of nanoparticles is presented and the advantages of the current methodology over earlier protocols are pointed out. The versatility of LB films in terms of the molecular level control of fabrication it enables and the variety of film structures that can be realized, point to the wide scope for future explorations, expanding upon the present observations.     

Controllable Synthesis of Multicompartmental Particles Using 3D Microfluidics

A microfluidic assembly method based on a microfluidic chip and capillary device was developed to create multicompartmental particles. The microfluidic chip design endows the particles with regulable internal structure. By adjusting the microstructure of the chip, the diameter of the capillary, the gap length between the two microfluidic components, and the flow rates, the size of the particles and the number or the ratio of different regions within the particle could be widely varied. As a proof of concept, we have produced some complicated particles that even contain 20 compartments. Furthermore, the potential applications of the anisotropic particles are explored by encapsulating magnetic beads, fluorescent nanoparticles, and the cells into different compartments of the microparticles. We believe that this method will open new avenues for the design and application of multicompartmental particles.     

漂浮法制备SiO2有序大孔材料

用漂浮组装方法以亚微米尺度单分散的聚苯乙烯(PS)微球作为模板, 在悬浮液气-液界面处组装PS模板微球与纳米级胶体颗粒, 形成二元胶体颗粒共混物, 再去除模板得到有序大孔材料.     

Template-free segmental synthesis of oligonucleotides containing nonnative linkages

Protected oligonucleotides containing 3'-alkyl carboxylic acids or 3'-alkylamines were obtained from photolabile solid-phase synthesis supports (1 and 4). Protected oligonucleotides containing 5'-alkylamines and 3'-hydroxyl groups were obtained using a photolabile solid-phase synthesis support (2) and a commercially available phosphoramidite reagent (3). Depending upon the source of alkylamine-containing oligonucleotide, the segments were coupled under mild conditions to form products containing either 5'-3' or 3'-3' linkages in good yield and high purity. Oligonucleotides as long as 40 nucleotides were prepared, and coupling yields of protected biopolymer segments were independent of length over the range examined. This method is particularly well suited for the convergent synthesis of oligonucleotides containing nonnative linkages and should be useful for the rapid assembly of modified biopolymers that are useful in biochemical studies.     

Fabrication of Hollow or Macroporous Silica Particles by Spray Drying of Colloidal Dispersion

In this study, hollow silica particles were fabricated by atomizing the dispersion of silica nanocolloids synthesized by modified Stober method and self-organization of the particles by spray drying technique. Rapid evaporation of the droplet containing the silica nanoparticles resulted in the formation of hollow microparticles at high evaporation temperature due to hydrodynamic instability of the droplet. Similar strategy was adopted for the fabrication of macroporous silica particles by the sol spray drying of the hetero-colloidal dispersion of polystyrene nanospheres and commercial silica nanoparticles. The morphologies of the porous particles were observed by scanning electron microscope with varying drying temperature. As a demonstrative purpose, the results using emulsion droplets as confining geometry was compared with the porous particles obtained from spray dryer. Collectively, spray drying was found to be more efficient manner to prepare the porous materials with continuous way in the view of production efficiency and time.     

Preparation of cuprous oxides with different sizes and their behaviors of adsorption,visible-light driven photocatalysis and photocorrosion

Cuprous oxide (Cu₂O) nanoparticles and microparticles have been prepared by liquid phase chemical synthesis. The samples were characterized by means of SEM, XRD, UV/DRS and XPS. It was presented that as-prepared Cu₂O nanoparticles are substantially stable in ambient atmosphere and the Cu⁺ as main state exists on the surface of Cu₂O nanoparticles. As-prepared Cu₂O microparticles can exist stably as a Cu₂O/CuO core/shell structure; and the Cu²⁺ as main state exists on the surface of Cu₂O microparticles. The behaviors of adsorption, photocatalysis and photocorrosion of Cu₂O particles with different sizes were investigated in detail. The results show that Cu₂O nanoparticles are very easy to photocorrosion during the photocatalytic reaction, which cannot be used as photocatalyst directly to degrade organic compound, although as-prepared Cu₂O nanoparticles exhibit special property of adsorption. Cu₂O microparticles have a higher photocatalytic activity than Cu₂O nanoparticles because of its slower photocorrosion rate, although Cu₂O microparticles have much lower adsorption capacity than Cu₂O nanoparticles. The mechanisms of photocatalysis and photocorrosion for Cu₂O under visible light were also discussed.     

Manipulating microparticles with single surface-immobilized nanoparticles

This experimental study explores the capture and manipulation of micrometer-scale particles by single surface-immobilized nanoparticles. The nanoparticles, approximately 10 nm in diameter, are cationic and therefore attract the micrometer-scale silica particles in an analyte suspension. The supporting surface on which the nanoparticles reside is negative (also silica) and repulsive toward approaching microparticles. In the limit where there are as few as 9 nanoparticles per square micrometer of collector, it becomes possible to capture and hold micrometer-scale silica particles with single nanoparticles. The strong nanoparticle-microparticle attractions, their nanometer-scale protrusion forward of the supporting surface, and their controlled density on the supporting surface facilitate microparticle-surface contact occurring through a single nanoelement. This behavior differs from most particle-particle, cell-cell, or particle (or cell)-surface interactions that involve multiple ligand-receptor bonds or much larger contact areas. Despite the limited contact of microparticles with surface-immobilized nanoparticles, microparticles resist shear forces of 9 pN or more but can be released through an increase in the ionic strength. The ability of nanoparticles to reversibly trap and hold much larger targets has implications in materials self-assembly, cell capture, and sorting applications, whereas the single point of contact affords precision in particle manipulation.     

Modification of solids with polymer nanolayers as a process for manufacture of novel biomaterials

The results of study on the chemical deposition of polymeric coatings of a nanoscale thickness on porous and flat inorganic matrices and encapsulation of nano-and microparticles in polymer shells are discussed. Procedures for the deposition of homogeneous defect-free coatings are detailed by using polytetrafluoroethylene, polyaniline, and their derivatives as examples. The matrices modified with nanosized polytetrafluoroethylene and polyaniline layers are promising biomaterials for one-step isolation of nucleic acids from complex biological mixtures (cell and tissue lysates, whole blood, plant feedstock), as well as for high-performance chromatography of proteins and other biopolymers. Approaches to the fabrication of polymer shells on luminescent nanocrystals of (CdSe)ZnS via the inclusion of the nanocrystals in micrometer-sized particles based on acrolein-styrene copolymers and the formation of polymer shells directly on nanoparticles are discussed. It was shown that polymer-functionalized luminescent nanocrystals hold promise as bioanalytical reagents.     

Covalent Assembly of Hierarchical Particles by Efficient Coupling of β‐Diketones and Benzyl Chloride

A coupling reaction is performed between polymeric nanoparticles and microparticles via the nucleophilic substitution of pendent β‐diketone groups with benzyl chloride. The coupling reaction results in the formation of hierarchical particles, through the nanoparticles being covalently linked onto the microparticles. The coupling reaction is tracked by TEM and SEM, and the formation of covalent C–C bonds through the coupling reaction between the polymeric nanoparticles and microparticles is confirmed by solid‐state ¹³C CP‐MAS NMR spectroscopy and XPS. The proposed coupling reaction between the nanoparticles and the microparticles is believed to be a promising strategy in particle‐surface modification.