Plasmonic nanoparticles and nucleic acids hybrids for targeted gene delivery,bioimaging,and molecular recognition

Promising biomedical applications of hybrid materials composed of gold nanoparticles and nucleic acids have attracted strong interest from the nanobiotechnological community.The particular interest is owing to the robust and easy-to-make synthetic approaches,to the versatile optical and catalytic properties of gold nanoparticles combined with the molecular recognition and programmable properties of nucleic acids.The significant progress is made in the develop-ment of DNA-gold nanostructures and their applications,such as molecular recognition,cell and tissue bioimaging,targeted delivery of therapeutic agents,etc.This review is focused on the critical discussion of the recent applications of the gold nanoparticles-nucleic acids hybrids.The effect of particle size,surface,charge and thermal properties on the interactions with functional nucleic acids is discussed.For each of the above topics,the basic principles,recent advances,and current challenges are discussed.Emphasis is placed on the systematization of data over the theranostic systems on the basis of the gold nanoparticles-nucleic acids hybrids.Specifically,we start our discussion with observation of the recent data on interaction of various gold nano-particles with nucleic acids.Further we describe existing gene delivery systems,nucleic acids detection,and bioimaging technologies.Finally,we describe the phenomenon of the polymerase chain reaction improvement by gold nanoparticle additives and its potential underlying mechanisms.Lastly,we provide a short summary of reported data and outline the challenges and perspectives.

Characterization of cerebral blood flow dynamics with multiscale entropy

Based on the laser speckle contrast imaging(LSCI)and the multiscale entropy(MSE),we study in this work the blood flow dynamics at the levels of cerebral veins and the surrounding network of microcerebral vessels.We discuss how the phenylephrine-related acute peripheral bypertension is refected in the cerebral circulation and show that the observed changes are scale dependent,and they are signifcantly more pronounced in microcerebral vessels,while the macrocerebral dynamics does not demonstrate authentic inter-group distinctions.We also consider the permeability of blood-brain barrier(BBB)and study its opening caused by sound exposure.We show that alterations associated with the BBB opening can be revealed by the analysis of blood flow at the level of macrocerebral vessels.

The morphological changes in the internal organs of laboratory animals after prolonged oral administration of gold nanoparticles

Recently gold nanoparticles(GNPs)have been actively studied as photot hermal converters,drug carriers,and imaging agents in a wide range of applications in cancer diagnosis and ther apy.The prolonged peroral administration of GNPs in a range of sizes was performed to investigate the morphological changes and their reversibility in the internal organs of laboratory animals.In this study,GNP's with average diameters of 2 nm,15 nm and 50nm were administered during 30 days,and the reversibility of morphological changes was investigated 14 days after administration.After the prolonged administration of GNPs,the severity of morphological changes in the liver,kidney,spleen and lymph nodes depended on the nanoparticle size.Specifically,50 nm nano-particles caused the most pronounced dystrophic and necrobiotic effects,whereas the smallest 2 nm nanoparticles caused proliferative changes.Most importantly,the development of patho-logical processes was reversible,as evidenced by the gradual restoration of the organ structure at 14 days after the end of GNPs administration.

Surface-enhanced Raman scattering inside Au@Ag core/shell nanorods

The design and synthesis of plasmonic nanoparticles with Raman-active molecules embedded inside them are of significant interest for sensing and imaging applications. However, direct synthesis of such nanostructures with controllable shape, size, and plasmonic properties remains extremely challenging. Here we report on the preparation of uniform Au@Ag core/sheU nanorods with controllable Ag shells of 1 to 25 nm in thickness. 1,4-Aminothiophenol （4-ATP） molecules, used as the Raman reporters, were located between the Au core and the Ag shell. Successful embedding of reporter molecules inside the core/shell nanoparticles was confirmed by the absence of selective oxidation of the amino groups, as measured by Raman spectroscopy. The dependence of Raman intensity on the location of the reporter molecules in the inside and outside of the nanorods was studied. The molecules in the interior showed strong and uniform Raman intensity, at least an order of magnitude higher than that of the molecules on the nanoparticle surface. In contrast to the usual surface-functionalized Raman tags, aggregation and clustering of nanoparticles with embedded molecules decreased the surface-enhanced Raman scattering （SERS） signal. The findings from this study provide the basis for a novel detection technique of low analyte concentration utilizing the high SERS response of molecules inside the core/shell metal nanostructures. As an example, we show robust SERS detection of thiram fungicide as low as 10-9 M in solutions.

Laser speckle imaging and wavelet analysis of cerebral blood flow associated with the opening of the blood–brain barrier by sound

The cerebral blood flow（CBF） alterations related to sound-induced opening of the blood–brain barrier（BBB） in adult mice are studied using laser speckle contrast imaging（LSCI） and wavelet analysis of vascular physiology.The results clearly show that the opening of the BBB is accompanied by the changes of venous but not microvessel circulation in the brain. The elevation of the BBB permeability is associated with the decrease of venous CBF and the increase of its complexity. These data suggest that the cerebral veins rather than microvessels are sensitive components of the CBF related to the opening BBB.