Engineering imaging probes and molecular machines for nanomedicine

Abstract: Nanomedicine is an emerging field that integrates nanotechnology, biomolecular engineering, life sciences and medicine; it is expected to produce major breakthroughs in medical diagnostics and therapeutics. Due to the size-compatibility of nano-scale structures and devices with proteins and nucleic acids, the design, synthesis and application of nanoprobes, nanocarriers and nanomachines provide unprecedented opportunities for achieving a better control of biological processes, and drastic improvements in disea… Show more

“…Moreover, some nanomaterials are potential florescence probes in relevant technologies. For instance, quantum dots are of high photo stability, high identification accuracy and controllable colors, and have been used as fluorescence imaging probes, fluorescent protein FRET probes and molecular beacons [6]. Atomic force microscopy (AFM) is a powerful tool in the study of biomolecular interactions, and can measure the binding forces at the molecular level of protein/DNA, DNA/ DNA, ligand/receptor and other biomolecule pairs.…”

“…X-ray computed tomography (CT) is widely used in diagnostic medicine. Many kinds of nanomaterials have shown great potentials as CT contrast agents, such as gold, silver, bismuth, and tantalum nanomaterials [6]. Gold nanoparticles have higher atomic number, X-ray absorption coefficient, and longer blood circulation half-life than clinically used CT contrast agents [6].…”

“…Many kinds of nanomaterials have shown great potentials as CT contrast agents, such as gold, silver, bismuth, and tantalum nanomaterials [6]. Gold nanoparticles have higher atomic number, X-ray absorption coefficient, and longer blood circulation half-life than clinically used CT contrast agents [6]. They are also utilized in light scattering imaging, two-photon fluorescence (TPF) imaging and photoacoustic imaging in the cell imaging-based detection for tumors [12].…”

“…They are also utilized in light scattering imaging, two-photon fluorescence (TPF) imaging and photoacoustic imaging in the cell imaging-based detection for tumors [12]. Besides, entrapment with Liposomes can prolong the circulation half-time of traditional contrast agents as iodinated ones [6].…”

“…Compared with gadolinium-based MRI contrast agents, nanoparticle MRI contrast agents circulate longer in the blood, and have higher sensitivity and fewer side-effects [6]. Combining positron emission tomography (PET) with the highresolution, spectroscopic, and contrast enhancement abilities of MRI would make a breakthrough in the detection and monitoring of diseases.…”

Applications of nanotechnology in biomedicine

“…Moreover, some nanomaterials are potential florescence probes in relevant technologies. For instance, quantum dots are of high photo stability, high identification accuracy and controllable colors, and have been used as fluorescence imaging probes, fluorescent protein FRET probes and molecular beacons [6]. Atomic force microscopy (AFM) is a powerful tool in the study of biomolecular interactions, and can measure the binding forces at the molecular level of protein/DNA, DNA/ DNA, ligand/receptor and other biomolecule pairs.…”

“…X-ray computed tomography (CT) is widely used in diagnostic medicine. Many kinds of nanomaterials have shown great potentials as CT contrast agents, such as gold, silver, bismuth, and tantalum nanomaterials [6]. Gold nanoparticles have higher atomic number, X-ray absorption coefficient, and longer blood circulation half-life than clinically used CT contrast agents [6].…”

“…Many kinds of nanomaterials have shown great potentials as CT contrast agents, such as gold, silver, bismuth, and tantalum nanomaterials [6]. Gold nanoparticles have higher atomic number, X-ray absorption coefficient, and longer blood circulation half-life than clinically used CT contrast agents [6]. They are also utilized in light scattering imaging, two-photon fluorescence (TPF) imaging and photoacoustic imaging in the cell imaging-based detection for tumors [12].…”

“…They are also utilized in light scattering imaging, two-photon fluorescence (TPF) imaging and photoacoustic imaging in the cell imaging-based detection for tumors [12]. Besides, entrapment with Liposomes can prolong the circulation half-time of traditional contrast agents as iodinated ones [6].…”

“…Compared with gadolinium-based MRI contrast agents, nanoparticle MRI contrast agents circulate longer in the blood, and have higher sensitivity and fewer side-effects [6]. Combining positron emission tomography (PET) with the highresolution, spectroscopic, and contrast enhancement abilities of MRI would make a breakthrough in the detection and monitoring of diseases.…”

Applications of nanotechnology in biomedicine

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