Mesoporous silica nanoparticles in nanotechnology

Mesoporous silica nanoparticles (MSNs) are a versatile drug delivery system that can be used for loading of different guest molecules such as peptides, proteins, anticancer agents, and genetic material. MSNs are considered promising drug carriers due to their tuneable particle size, pore structure, and surface functionalization. Thus, MSNs provide opportunities for their effective application in a wide variety of fields. In the current review, we discuss both conventional and advanced MSNs synthesis methods, including their applications for drug delivery, gatekeepers, and biosensors. In addition, the research progress in biocompatibility, cytotoxicity, and internalization mechanisms is reported.     

Photoluminescent biocompatible silicon nanoparticles for cancer theranostic applications

Silicon nanoparticles (SiNPs) obtained by mechanical grinding of porous silicon have been used for visualization of living cells in vitro. It was found that SiNPs could penetrate into the cells without any cytotoxic effect up to the concentration of 100 μg/ml. The cell cytoplasm was observed to be filled by SiNPs, which exhibited bright photoluminescence at 1.6 eV. SiNPs could also act as photosensitizers of the singlet oxygen generation, which could be used in the photodynamic therapy of cancer. These properties of SiNPs are discussed in view of possible applications in theranostics (both in therapy and in diagnostics). (© 2012 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

DNA nanotechnology and fluorescence applications

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Nanoliposomes and their applications in food nanotechnology

Food nanotechnology involves the utilization of nanocarrier systems to stabilize the bioactive materials against a range of environmental and chemical changes as well as to improve their bioavailability. Nanoliposome technology presents exciting opportunities for food technologists in areas such as encapsulation and controlled release of food materials, as well as the enhanced bioavailability, stability, and shelf-life of sensitive ingredients. Liposomes and nanoliposomes have been used in the food industry to deliver flavors and nutrients and, more recently, have been investigated for their abilityto incorporate antimicrobials that could aid in the protection of food products against microbial contamination. In this paper, the main physicochemical properties of liposomes and nanoliposomes are described and some of the industrially applicable methods for their manufacture are reviewed. A summary of the application of nanoliposomes as carrier vehicles of nutrients, nutraceuticals, enzymes, food additives, and food antimicrobials is also presented.     

Towards applications of synthetic cells in nanotechnology

Synthetic cells, which are assembled anew from well-defined molecular parts, open-up new possibilities for nanotechnological applications due to their reduced complexity and high functionality. In this review, we discuss how synthetic cells are being implemented in different fields ranging from biomedicine to material science. On one hand, synthetic cells can serve as microreactors that house metabolic networks and as therapeutic carriers that directly communicate with living cells. On the other hand, synthetic cells can become active components in a new-generation of materials that process inputs and result in autonomous and adaptive behavior. These early examples highlight the potential impact that synthetic cells will have in future applications.     

Silanized surfaces for in vitro studies of actomyosin function and nanotechnology applications

We have previously shown that selective heavy meromyosin (HMM) adsorption to predefined regions of nanostructured polymer resist surfaces may be used to produce a nanostructured in vitro motility assay. However, actomyosin function was of lower quality than on conventional nitrocellulose films. We have therefore studied actomyosin function on differently derivatized glass surfaces with the aim to find a substitute for the polymer resists. We have found that surfaces derivatized with trimethylchlorosilane (TMCS) were superior to all other surfaces tested, including nitrocellulose. High-quality actin filament motility was observed up to 6 days after incubation with HMM and the fraction of motile actin filaments and the velocity of smooth sliding were generally higher on TMCS than on nitrocellulose. The actomyosin function on TMCS-derivatized glass and nitrocellulose is considered in relation to roughness and hydrophobicity of these surfaces. The results suggest that TMCS is an ideal substitute for polymer resists in the nanostructured in vitro motility assay. Furthermore, TMCS derivatized glass also seems to offer several advantages over nitrocellulose for HMM adsorption in the ordinary in vitro motility assay.     

Detecting and treating cancer with nanotechnology

Nanotechnology offers many opportunities for enhanced diagnostic and therapeutic medicine against cancer and other diseases. In this review, the special properties that result from the nanoscale size of quantum dots, metal colloids, superparamagnetic iron oxide, and carbon-based nanostructures are reviewed and interpreted against a background of the structural and electronic detail that gives rise to their nanotechnologic behavior. The detection and treatment of cancer is emphasized, with special attention paid to the biologic targeting of the disease. The future of nanotechnology in cancer research and clinical practice is projected to focus on 'theranostic' nanoparticles that are both diagnostic and therapeutic by design.     

Designed DNA molecules: principles and applications of molecular nanotechnology

Long admired for its informational role in the cell, DNA is now emerging as an ideal molecule for molecular nanotechnology. Biologists and biochemists have discovered DNA sequences and structures with new functional properties, which are able to prevent the expression of harmful genes or detect macromolecules at low concentrations. Physical and computational scientists can design rigid DNA structures that serve as scaffolds for the organization of matter at the molecular scale, and can build simple DNA-computing devices, diagnostic machines and DNA motors. The integration of biological and engineering advances offers great potential for therapeutic and diagnostic applications, and for nanoscale electronic engineering.     

Functional DNA nanotechnology: emerging applications of DNAzymes and aptamers

In the past 25 years, DNA molecules have been utilized both as powerful synthetic building blocks to create nanoscale architectures and as versatile programmable templates for assembly of nanomaterials. In parallel, the functions of DNA molecules have been expanded from pure genetic information storage to catalytic functions like those of protein enzymes (DNAzymes) and specific binding functions like antibodies (aptamers). In the past few years, a new interdisciplinary field has emerged that aims to combine functional DNA biology with nanotechnology to generate more dynamic and controllable DNA-based nanostructures or DNA-templated nanomaterials that are responsive to chemical stimuli.     

Filamentous bacteriophage: biology, phage display and nanotechnology applications

Filamentous bacteriophage, long and thin filaments that are secreted from the host cells without killing them, have been an antithesis to the standard view of head-and-tail bacterial killing machines. Episomally replicating filamentous phage Ff of Escherichia coli provide the majority of information about the principles and mechanisms of filamentous phage infection, episomal replication and assembly. Chromosomally- integrated "temperate" filamentous phage have complex replication and integration, which are currently under active investigation. The latter are directly or indirectly implicated in diseases caused by bacterial pathogens Vibrio cholerae, Pseudomonas aeruginosa and Neisseria meningitidis. In the first half of the review, both the Ff and temperate phage are described and compared. A large section of the review is devoted to an overview of phage display technology and its applications in nanotechnology.     

Nanoporous anti-fouling silicon membranes for biosensor applications.

The ability to create biocompatible well-controlled membranes has been an area of great interest over the last few years, particularly for biosensor applications. The present study describes the fabrication and characterization of novel nanoporous micromachined membranes that exhibit selective permeability and low biofouling. Results indicate that such membranes can be fabricated with uniform pore sizes capable of the simultaneous exclusion of albumin and diffusion of glucose. Compared to polymeric membranes of similar pore size, micromachined silicon membranes allowed more than twice the amount of glucose diffusion after 240 min and complete albumin exclusion. Moreover, membranes exhibit no morphological change or degradability in the presence of biological proteins and fluids at 37 degrees C. The results point to the potential of using such membranes for implantable biosensor applications. With monodisperse pores sizes as small as 10 nm, these membranes offer advantages in their reproducibility, stability, and ability to be integrated in silicon-based biosensing technology.     

Hydrogen plasma surface activation of silicon for biomedical applications

Silicon has gradually been recognized to be an essential trace element in the normal metabolism of higher animals, and the role of silicon in the human body has aroused interests in the biomedical community. In fact, the interactions between silicon-based devices and the human body such as biosensors and microelectromechanical systems (MEMS) often suffer from poor biocompatibility. In this work, hydrogen plasma immersion ion implantation (H-PIII) is conducted to improve the bioactivity or bone conductivity of silicon. In order to investigate the formation mechanism of bone-like apatite on the surface of the hydrogen implanted silicon wafer, two comparative experiments, hydrogenation and argon bombardment, are performed. The H-PIII sample exhibits an amorphous surface consisting of Si-H bonds. After immersion in simulated body fluids, a negatively charged surface containing the functional group ([triple bond]Si-O-) is produced and bone-like apatite is observed to nucleate and grow on the surface. The surface of the H-PIII silicon wafer favors the adhesion and growth of osteoblast cells and good cytocompatibility may be inferred.     

Experimental models of maternal–fetal interface and their potential use for nanotechnology applications

During pregnancy, the placenta regulates the transfer of oxygen, nutrients, and residual products between the maternal and fetal bloodstreams and is a key determinant of fetal exposure to xenobiotics from the mother. To study the disposition of substances through the placenta, various experimental models are used, especially the perfused placenta, placental villi explants, and cell lineage models. In this context, nanotechnology, an area of study that is on the rise, enables the creation of particles on nanometric scales capable of releasing drugs aimed at specific tissues. An important reason for furthering the studies on transplacental transfer is to explore the potential of nanoparticles (NPs), in new delivery strategies for drugs that are specifically aimed at the mother, the placenta, or the fetus and that involve less toxicity. Due to the fact that the placental barrier is essential for the interaction between the maternal and fetal organisms as well as the possibility of NPs being used in the treatment of various pathologies, the aim of this review is to present the main experimental models used in studying the maternal–fetal interaction and the action of NPs in the placental environment.     

Neurotransmitter analog tethered to a silicon platform for neuro-BioMEMS applications

The design of chemically well-defined, machinable surfaces containing neuroactive molecules offers potential for fundamental neuroscience and clinical neural engineering applications. Here we report the assembly and characterization of silicon platforms containing a tethered form of muscimol. Muscimol, an analog of the inhibitory neurotransmitter gamma-aminobutyric acid (GABA), is a potent agonist at postsynaptic GABA(A) and GABA(C) receptors. Surfaces were assembled using covalent avidin conjugation to silanized silicon followed by high-affinity avidin-biotin binding of a biotinylated derivative of muscimol (muscimol-biotin). Contact angle measurements, ellipsometry, and X-ray photoelectron spectroscopy (XPS) were conducted to characterize the wettability, thickness, and chemical composition of progressively deposited surface layers. The data demonstrate successful incorporation of a neurotransmitter analog as part of a layered, silicon-based structure possessing robust and specific biomolecular composition. These findings represent a step toward the design of platforms for applications involving control and modulation of neural signaling.     

Perspectives on the nanotechnology applications of for the analytical detection of heavy metals in marine organisms

Heavy metals accumulate in organisms throughout the food chain and eventually end up in humans. Heavy metals can cause severe diseases and may even result in death. Therefore, concerns about heavy metal accumulation in marine organisms have increased in recent years. To determine solutions to this concern, the sensitive detection of heavy metals in marine organisms is required. Current detection techniques for heavy metals present in marine organisms have several limitations, such as complicated pre-treatment steps and a lengthy analysis time. Thus, there are increasing needs for the newly developed methods of detecting heavy metals in marine organisms. In this review, we focus here on (1) the current detection techniques available and (2) the application of newly emergent nanotechnology for the sensitive detection of heavy metals in marine organisms.     

Interlocked DNA topologies for nanotechnology

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