1. Gene Therapy and Viral Vectors
Lecture 9

2. Nanorods Nanorods are morphology of nanoscale objects.
Each of their dimension ranges from 1–100 nm.
Nanorods may be synthesized from metals or semiconducting materials.
One way for synthesis of nanorods is produced by direct chemical synthesis.
The combinations of ligands act as shape control agents and bond to different facets of the nanorod with different strengths. This allows different faces of the nanorod to grow at different rates, producing an elongated object.

3. Capping agents
Capping agent would help preventing the nanoparticles from growth. Final product could be either a solid or liquid.
Stabilizing agent could be used to prevent agglomeration of the nanoparticles. Here too, the final product could be either a solid or liquid.
Dispersing agent also helps in preventing agglomeration, but the final product must be a liquid.
There may be just one material, for example the PEG, which could serve all the three roles mentioned above. That is the reason why all these terms are being used by the researchers in common.
PEG: Poly Ethylene Glycol

4. Capping/stabilizing agents: ligands, surfactants, polymers, dendrimers, biomolecules
The use of coating nanoparticle with surfactant or polymer is to prevent aggregation of the particles due to nanoparticles high surface energy.
It also controls the size of the particles during synthesis process.
Capping of nanoparticles an be checked using TEM (Transmission Electron Microscope)

5. Addition of biomolecules
After synthesis, the stabilizing agents surrounding the nanoparticles can be replaced by other molecules usually by ligand exchange reactions.
Biomolecules such as DNA/RNA, oligonucleotides (i.e. siRNA, ssDNA), peptides and antibodies, fluorescent dyes, polymers, drugs, tumoral markers, various enzymes and other proteins, that are easily attached to the nanoparticles’s surface.
In addition, ligands can also be linked to the shell of stabilizing agents. One of the most common applications is the linkage of amino groups in biological molecules with carboxyl groups at the free ends of the stabilizing agents.

6. Gold nanorods that detect proteins can be used for kidney disease detection

7. Srikanth Singamaneni, PhD, assistant professor of engineering, along with Evan Kharasch, MD, PhD, and Jerry Morrissey, PhD, at Washington University School of Medicine, have developed a biomedical sensor using gold nanorods designed to detect the elevation of the protein neutrophil gelatinase-associated lipocalin (NGAL), a promising biomarker for acute kidney injury, in urine. Read more: Gold nanorods that detect proteins could simplify kidney disease detection