Nanoparticle–biomolecule conjugate | Wikipedia audio article |
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This is an audio version of the Wikipedia Article:
https://en.wikipedia.org/wiki/Nanoparticle%E2%80%93biomolecule_conjugate 00:00:42 1 Characterization 00:02:19 2 Chemistry 00:02:29 2.1 Physical 00:04:45 2.2 Application chemistry 00:05:34 3 Applications with biomolecules and biological processes 00:06:07 3.1 Identification of biomolecules 00:07:18 3.2 Biological process control 00:09:30 3.3 Genetic alteration 00:10:53 3.4 Medical implications 00:11:52 3.5 Studying cell interactions 00:14:38 3.6 Nanotechnology crossing the blood-brain barrier Listening is a more natural way of learning, when compared to reading. Written language only began at around 3200 BC, but spoken language has existed long ago. Learning by listening is a great way to: - increases imagination and understanding - improves your listening skills - improves your own spoken accent - learn while on the move - reduce eye strain Now learn the vast amount of general knowledge available on Wikipedia through audio (audio article). You could even learn subconsciously by playing the audio while you are sleeping! If you are planning to listen a lot, you could try using a bone conduction headphone, or a standard speaker instead of an earphone. Listen on Google Assistant through Extra Audio: https://assistant.google.com/services/invoke/uid/0000001a130b3f91 Other Wikipedia audio articles at: https://www.youtube.com/results?search_query=wikipedia+tts Upload your own Wikipedia articles through: https://github.com/nodef/wikipedia-tts Speaking Rate: 0.8831920626638088 Voice name: en-US-Wavenet-C "I cannot teach anybody anything, I can only make them think." - Socrates SUMMARY ======= A nanoparticle–biomolecule conjugate is a nanoparticle with biomolecules attached to its surface. Nanoparticles are minuscule particles, typically measured in nanometers (nm), that are used in nanobiotechnology to explore the functions of biomolecules. Properties of the ultrafine particles are characterized by the components on their surfaces more so than larger structures, such as cells, due to large surface area-to-volume ratios. Large surface area-to-volume-ratios of nanoparticles optimize the potential for interactions with biomolecules. |