Biomedicine: using nanoparticle technology to design and prepare drug (gene) delivery carriers with multiple response functions or targeting, and develop new drug formulations and drugs.
Regenerative medicine: develop nano-structured materials to guide tissue regeneration and promote tissue/material interface fusion, permanent implant surface coatings for tissue repair and replacement, scaffolds to guide tissue regeneration, structural permanent implants, sensors for implantable treatment and monitoring, etc.
Surgical assistance: develop intelligent instruments and equipment, surgical robots and diagnostic tools based on nano-optics and nano-electronics; Develop gene detection, ultra-sensitive labeling and detection technology, Qualcomm and multiplex analysis technology based on nanofluid and nano-processing technology.
Medical imaging: new contrast agents based on nanoparticle technology, targeted labeling technology, and understanding of basic life processes: based on nano-mechanical and optical technologies such as atomic force microscope and tunneling scanning microscope, life processes are studied at the molecular or atomic level.
Extended data
Imaging technology can only detect the visible changes caused by cancer in tissues, while thousands of cancer cells have been produced and may metastasize.
Even though the tumor can already be seen, due to the category (malignant or benign) and characteristics of the tumor itself, it is necessary to determine the effective treatment method through biopsy. If cancer cells or precancerous cells are labeled in some way, they can be detected by traditional equipment, which is more conducive to the diagnosis of cancer.
To achieve this goal, there are two necessary conditions: a technology can specifically identify cancer cells and make the identified cancer cells visible. Nanotechnology can satisfy these two points. For example, the surface of metal oxide is coated with antibody, which can specifically recognize the receptor over-expressed on the surface of cancer cells.
Because metal oxides emit high contrast signals under magnetic resonance imaging (MRI) or computed tomography (CT), once they enter the body, the antibodies on the surface of these metal oxide nanoparticles will selectively bind to cancer cells, so that the detection instrument can effectively identify cancer cells.
Similarly, gold nanoparticles can also be used to enhance light scattering in endoscopic technology. Nanotechnology can visualize molecular markers that identify cancer types and different stages of development, so that doctors can see cells and molecules that cannot be detected by traditional imaging techniques. What's more, help us, these dangerous cancer symptoms are not a problem in the face of nanotechnology, and they can make complex things simple.
Biomedicine: using nanoparticle technology to design and prepare drug (gene) delivery carriers with multiple response functions or targeting, and develop new drug formulations and drugs.
Regenerative medicine: develop nano-structured materials to guide tissue regeneration and promote tissue/material interface fusion, permanent implant surface coatings for tissue repair and replacement, scaffolds to guide tissue regeneration, structural permanent implants, sensors for implantable treatment and monitoring, etc.
Surgical assistance: develop intelligent instruments and equipment, surgical robots and diagnostic tools based on nano-optics and nano-electronics; Develop gene detection, ultra-sensitive labeling and detection technology, Qualcomm and multiplex analysis technology based on nanofluid and nano-processing technology.
Medical imaging: new contrast agents based on nanoparticle technology, targeted labeling technology, and understanding of basic life processes: based on nano-mechanical and optical technologies such as atomic force microscope and tunneling scanning microscope, life processes are studied at the molecular or atomic level.
Extended data
Imaging technology can only detect the visible changes caused by cancer in tissues, while thousands of cancer cells have been produced and may metastasize.
Even though the tumor can already be seen, due to the category (malignant or benign) and characteristics of the tumor itself, it is necessary to determine the effective treatment method through biopsy. If cancer cells or precancerous cells are labeled in some way, they can be detected by traditional equipment, which is more conducive to the diagnosis of cancer.
To achieve this goal, there are two necessary conditions: a technology can specifically identify cancer cells and make the identified cancer cells visible. Nanotechnology can satisfy these two points. For example, the surface of metal oxide is coated with antibody, which can specifically recognize the receptor over-expressed on the surface of cancer cells.
Because metal oxides emit high contrast signals under magnetic resonance imaging (MRI) or computed tomography (CT), once they enter the body, the antibodies on the surface of these metal oxide nanoparticles will selectively bind to cancer cells, so that the detection instrument can effectively identify cancer cells.
Similarly, gold nanoparticles can also be used to enhance light scattering in endoscopic technology. Nanotechnology can visualize molecular markers that identify cancer types and different stages of development, so that doctors can see cells and molecules that cannot be detected by traditional imaging techniques. What's more, help us, these dangerous cancer symptoms are not a problem in the face of nanotechnology, and they can make complex things simple.
Biomedicine: using nanoparticle technology to design and prepare drug (gene) delivery carriers with multiple response functions or targeting, and develop new drug formulations and drugs.
Regenerative medicine: develop nano-structured materials to guide tissue regeneration and promote tissue/material interface fusion, permanent implant surface coatings for tissue repair and replacement, scaffolds to guide tissue regeneration, structural permanent implants, sensors for implantable treatment and monitoring, etc.
Surgical assistance: develop intelligent instruments and equipment, surgical robots and diagnostic tools based on nano-optics and nano-electronics; Develop gene detection, ultra-sensitive labeling and detection technology, Qualcomm and multiplex analysis technology based on nanofluid and nano-processing technology.
Medical imaging: new contrast agents based on nanoparticle technology, targeted labeling technology, and understanding of basic life processes: based on nano-mechanical and optical technologies such as atomic force microscope and tunneling scanning microscope, life processes are studied at the molecular or atomic level.
Extended data
Imaging technology can only detect the visible changes caused by cancer in tissues, while thousands of cancer cells have been produced and may metastasize.
Even though the tumor can already be seen, due to the category (malignant or benign) and characteristics of the tumor itself, it is necessary to determine the effective treatment method through biopsy. If cancer cells or precancerous cells are labeled in some way, they can be detected by traditional equipment, which is more conducive to the diagnosis of cancer.
To achieve this goal, there are two necessary conditions: a technology can specifically identify cancer cells and make the identified cancer cells visible. Nanotechnology can satisfy these two points. For example, the surface of metal oxide is coated with antibody, which can specifically recognize the receptor over-expressed on the surface of cancer cells.
Because metal oxides emit high contrast signals under magnetic resonance imaging (MRI) or computed tomography (CT), once they enter the body, the antibodies on the surface of these metal oxide nanoparticles will selectively bind to cancer cells, so that the detection instrument can effectively identify cancer cells.
Similarly, gold nanoparticles can also be used to enhance light scattering in endoscopic technology. Nanotechnology can visualize molecular markers that identify cancer types and different stages of development, so that doctors can see cells and molecules that cannot be detected by traditional imaging techniques.