Porous Organic Materials
CD Bioparticles' products feature customized delivery strategies, precise design and modification of drugs or drug-containing cargoes, and advanced technology platforms that can help you address:
Porous Organic Materials
- Cumbersome chemical synthesis, formulation and purification
- Lack of reliable raw materials for further synthesis of novel porous organic materials
- Nanomedicine lacks cell-specific or tissue-specific targeting
- Difficult to add functional groups required for drug carrier delivery
- Difficulty tracking and imaging the distribution of polymer-based (nano) materials
- Limited drug loading efficiency and yield of drug delivery materials
- Your carrier material has a strong immune or foreign body reaction
- Low cellular uptake of nano-drug delivery systems
- Uncontrolled drug release
Key Features:
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g-C3N4
Ionic Liquids
Optoelectronic Materials
Optoelectronic Materials Intermediates
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Multi-Carboxylic MOFs Linkers
2d-Carboxylic MOFs Linkers
3d-Carboxylic MOFs Linkers
4d-Carboxylic MOFs Linkers
Multi-Nitrogen MOFs Linkers
2d-Nitrogen MOFs Linkers
3d-Nitrogen MOFs Linkers
Multi-Hybrid MOFs Linkers
2d-Hybrid MOFs Linkers
3d-Hybrid MOFs Linkers
A2B2-Porphyrins
A3B1-Porphyrins
A4-Porphyrins
Bipyridine Blocks
Halide Substituted Aromatics
Metalloporphyrins
Tetraphenylethylene
Triphenylbenzene
Customizable MOFs Linkers
Isophthalate
Other MOFs Linkers
Other Organic-Linker Blocks
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Multi-Nitrile COFs Linkers
2d Boric COFs Linkers
3d-Boric COFs Linkers
4d-Boric COFs Linkers
2d Nitrile COFs Linkers
3d Nitrile COFs Linkers
Acetonitrile COFs Linkers
Multi-Aldehyde COFs Linkers
2d-Aldehyde COFs Linkers
3d-Aldehyde COFs Linkers
Multi-Alkyne Orgnic COFs Linkers
2d-Alkyne Orgnic COFs Linkers
3d-Alkyne Orgnic COFs Linkers
Multi-Phosphoric Acids COFs Linkers
2d-Phosphoric Acids COFs Linkers
3d-Phosphoric Acids COFs Linkers
Multi-Amine COFs Linkers
2d-Amine COFs Linkers
Hybrid COFs Linkers
Customizable COFs Linkers
Other COFs Linkers
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Iron-based MOFs (Fe-MOF)
Zinc-Based MOFs (Zn-MOF)
Cerium-based MOFs (Ce-MOF)
Cobalt-based MOFs (Co-MOF)
Nickel-based MOFs (Ni-MOF)
Indium-based MOFs (In-MOF)
Vanadium-based MOFs (V-MOF)
Titanium-based MOFs (Ti-MOF)
Chromium-based MOFs (Cr-MOF)
Aluminum-based MOFs (Al-MOF)
Copper-based MOFs (Cu–MOF)
Manganese-based MOFs (Mn-MOF)
Magnesium-based MOFs (Mg-MOF)
Zirconium-based MOFs (Zr-MOF)
Key benefits:
- Broad coverage of porous organic materials with functional groups/targeting ligands/labels for loading, modification, specific targeting, tracking and detection
- Provide porous organic materials with different properties through the modification of inorganic clusters and/or organic ligands
- Improve biocompatibility, activity and functional properties of porous organic materials
- Flexibility to use surface adsorption, pore encapsulation, covalent binding or functional molecular building blocks to load drug molecules
- Synthesis of biodegradable porous organic materials using moderately strong coordination bonds
- Manufacture from non-GMP small laboratory scale to GMP and non-GMP grade commercial scale
Application candidates:
- Drug delivery system carriers: The synthesis, characterization, and drug-related studies of low-toxicity, biocompatible porous organic materials suggest that they can be used for in vivo drug delivery. At the same time, various methods can be designed to induce drug release from porous organic materials, such as pH-responsive, magnetic-responsive, ionic-responsive, temperature-responsive, and pressure-responsive.
- Bionic mineralization: By incorporating biomolecules (including proteins, DNA, and antibodies) during the crystallization of porous organic materials, biomolecules encapsulated in this way are stable and active even when exposed to harsh conditions such as corrosive solvents and high temperatures.
- Fabrication of biocompatible porous organic materials
- Bioimaging and Sensing
- Sorbent
- Catalyst
- Desalination/Ion Separation