Electron microscope labelling Colloidal gold and various derivatives have long been among the most widely used labels for
antigens in biological
electron microscopy. Colloidal gold particles can be attached to many traditional biological probes such as
antibodies,
lectins,
superantigens,
glycans,
nucleic acids, and receptors. Particles of different sizes are easily distinguishable in electron micrographs, allowing simultaneous multiple-labelling experiments. In addition to biological probes, gold nanoparticles can be transferred to various mineral substrates, such as mica,
single crystal silicon, and atomically flat gold(III), to be observed under atomic force microscopy (AFM).
Drug delivery system Gold nanoparticles can be used to optimize the biodistribution of drugs to diseased organs, tissues or cells, in order to improve and target drug delivery. Nanoparticle-mediated drug delivery is feasible only if the drug distribution is otherwise inadequate. These cases include drug targeting of unstable (
proteins,
siRNA,
DNA), delivery to the difficult sites (brain, retina, tumors, intracellular organelles) and drugs with serious side effects (e.g. anti-cancer agents). The performance of the nanoparticles depends on the size and surface functionalities in the particles. Also, the drug release and particle disintegration can vary depending on the system (e.g. biodegradable polymers sensitive to pH). An optimal nanodrug delivery system ensures that the active drug is available at the site of action for the correct time and duration, and their concentration should be above the minimal effective concentration (MEC) and below the minimal toxic concentration (MTC). Gold nanoparticles are being investigated as carriers for drugs such as
Paclitaxel. The administration of hydrophobic drugs require
molecular encapsulation and it is found that nanosized particles are particularly efficient in evading the
reticuloendothelial system.
Tumor detection In cancer research, colloidal gold can be used to target tumors and provide detection using SERS (
surface enhanced Raman spectroscopy)
in vivo. These gold nanoparticles are surrounded with Raman reporters, which provide light emission that is over 200 times brighter than
quantum dots. It was found that the Raman reporters were stabilized when the nanoparticles were encapsulated with a thiol-modified
polyethylene glycol coat. This allows for compatibility and circulation
in vivo. To specifically target tumor cells, the
polyethylenegylated gold particles are conjugated with an antibody (or an antibody fragment such as scFv), against, e.g.
epidermal growth factor receptor, which is sometimes overexpressed in cells of certain cancer types. Using SERS, these pegylated gold nanoparticles can then detect the location of the tumor. Gold nanoparticles accumulate in tumors, due to the leakiness of tumor vasculature, and can be used as
contrast agents for enhanced imaging in a time-resolved optical tomography system using short-pulse lasers for skin cancer detection in mouse model. It is found that intravenously administered spherical gold nanoparticles broadened the temporal profile of reflected optical signals and enhanced the contrast between surrounding normal tissue and tumors.
Gene therapy Gold nanoparticles have shown potential as intracellular delivery vehicles for siRNA oligonucleotides with maximal therapeutic impact. Gold nanoparticles show potential as intracellular delivery vehicles for
antisense oligonucleotides (single and double stranded DNA) by providing protection against intracellular
nucleases and ease of functionalization for selective targeting.
Photothermal agents Gold nanorods are being investigated as photothermal agents for in-vivo applications.
Gold nanorods are rod-shaped gold nanoparticles whose aspect ratios tune the surface plasmon resonance (SPR) band from the visible to near-infrared wavelength. The total extinction of light at the SPR is made up of both absorption and scattering. For the smaller axial diameter nanorods (~10 nm), absorption dominates, whereas for the larger axial diameter nanorods (>35 nm) scattering can dominate. As a consequence, for in-vivo studies, small diameter gold nanorods are being used as photothermal converters of near-infrared light due to their high absorption cross-sections. Since near-infrared light transmits readily through human skin and tissue, these nanorods can be used as ablation components for cancer, and other targets. When coated with polymers, gold nanorods have been observed to circulate in-vivo with half-lives longer than 6 hours, bodily residence times around 72 hours, and little to no uptake in any internal organs except the liver. Despite the unquestionable success of gold nanorods as photothermal agents in
preclinical research, they have yet to obtain the approval for clinical use because the size is above the
renal excretion threshold. In 2019, the first NIR-absorbing
plasmonic ultrasmall-in-nano architecture has been reported, and jointly combine: (i) a suitable
photothermal conversion for
hyperthermia treatments, (ii) the possibility of multiple
photothermal treatments and (iii)
renal excretion of the building blocks after the therapeutic action.
Radiotherapy dose enhancer Considerable interest has been shown in the use of gold and other heavy-atom-containing nanoparticles to enhance the dose delivered to tumors. Since the gold nanoparticles are taken up by the tumors more than the nearby healthy tissue, the dose is selectively enhanced. The biological effectiveness of this type of therapy seems to be due to the local deposition of the radiation dose near the nanoparticles. This mechanism is the same as occurs in
heavy ion therapy.
Detection of toxic gas Researchers have developed simple inexpensive methods for on-site detection of
hydrogen sulfide present in air based on the antiaggregation of gold nanoparticles (AuNPs). Dissolving into a weak
alkaline
buffer solution leads to the formation of HS-, which can stabilize AuNPs and ensure they maintain their red color allowing for visual detection of toxic levels of .
Gold nanoparticle based biosensor Gold nanoparticles are incorporated into
biosensors to enhance its stability, sensitivity, and selectivity. Nanoparticle properties such as small size, high surface-to-volume ratio, and high
surface energy allow immobilization of large range of biomolecules. Gold nanoparticle, in particular, could also act as "electron wire" to transport electrons and its amplification effect on electromagnetic light allows it to function as signal amplifiers. Main types of gold nanoparticle based biosensors are optical and electrochemical biosensor.
Optical biosensor (GSH). The AuNPs are
functionalised with a chemical group that binds to GSH and makes the NPs partially collapse, and thus change colour. The exact amount of GSH can be derived via
UV-vis spectroscopy through a
calibration curve. Gold nanoparticles improve the sensitivity of optical sensors in response to the change in the local refractive index. The angle of the incidence light for surface plasmon resonance, an interaction between light waves and conducting electrons in metal, changes when other substances are bounded to the metal surface. Because gold is very sensitive to its surroundings' dielectric constant, binding of an analyte significantly shifts the gold nanoparticle's SPR and therefore allows for more sensitive detection. Gold nanoparticle could also amplify the SPR signal. When the plasmon wave pass through the gold nanoparticle, the charge density in the wave and the electron I the gold interact and result in a higher energy response, referred to as electron coupling. Humidity sensors have also been built by altering the atom interspacing between molecules with humidity change, the interspacing change would also result in a change of the Au NP's LSPR.
Electrochemical biosensor Electrochemical sensor convert biological information into electrical signals that could be detected. The conductivity and biocompatibility of Au NP allow it to act as "electron wire". It could be accomplished in two ways: attach the Au NP to either the enzyme or the electrode. GNP-glucose oxidase monolayer electrode was constructed use these two methods. The Au NP allowed more freedom in the enzyme's orientation and therefore more sensitive and stable detection. Au NP also acts as immobilization platform for the enzyme. Most biomolecules denatures or lose its activity when interacted with the electrode. Moreover, Au NP also catalyzes biological reactions. Gold nanoparticle under 2 nm has shown
catalytic activity to the oxidation of styrene.
Immunological biosensor Gold nanoparticles have been coated with
peptides and
glycans for use in immunological detection methods. The possibility to use glyconanoparticles in
ELISA was unexpected, but the method seems to have a high sensitivity and thus offers potential for development of specific assays for
diagnostic identification of
antibodies in patient sera.
Thin films Gold nanoparticles capped with organic ligands, such as alkanethiol molecules, can self-assemble into large monolayers (>cm2). The particles are first prepared in organic solvent, such as chloroform or toluene, and are then spread into monolayers either on a liquid surface or on a solid substrate. Such interfacial thin films of nanoparticles have close relationship with
Langmuir-Blodgett monolayers made from surfactants. The mechanical properties of nanoparticle monolayers have been studied extensively. For 5 nm spheres capped with dodecanethiol, the Young's modulus of the monolayer is on the order of GPa. The mechanics of the membranes are guided by strong interactions between ligand shells on adjacent particles. Upon fracture, the films crack perpendicular to the direction of strain at a fracture stress of 11 \pm 2.6 MPa, comparable to that of cross-linked polymer films. Free-standing nanoparticle membranes exhibit bending rigidity on the order of 10^{5} eV, higher than what is predicted in theory for continuum plates of the same thickness, due to nonlocal microstructural constraints such as nonlocal coupling of particle rotational degrees of freedom. On the other hand, resistance to bending is found to be greatly reduced in nanoparticle monolayers that are supported at the air/water interface, possibly due to screening of ligand interactions in a wet environment. == Surface chemistry ==