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Pathways Recommended:	Antibody-drug Conjugate/ADC Related

Results for "

tumor drug delivery systems

" in MedChemExpress (MCE) Product Catalog:

By Targets:	ADC Linker (1) Akt (2) Bacterial (2) Biochemical Assay Reagents (1) CD44 (2) Endogenous Metabolite (2) Interleukin Related (1) Liposome (1) LPL Receptor (1) PI3K (2) STAT (1)
By Research Areas:	Cancer (7) Inflammation/Immunology (2) Metabolic Disease (2) Neurological Disease (2)
Click Chemistry:	Azide (1)
Oligonucleotides:	Cationic Lipids (1)

Inhibitors & Agonists

Biochemical Assay Reagents

Peptides

Click Chemistry

Oligonucleotides

Targets Recommended: Large Tumor Suppressor (LATS) Drug Intermediate Drug Isomer Drug Derivative TNF Receptor Drug Metabolite Antibody-Drug Conjugates (ADCs) BRK Peptide-Drug Conjugates (PDCs) Radionuclide-Drug Conjugates (RDCs) Drug-Linker Conjugates for ADC ADC Linker

Cat. No.	Product Name	Target	Research Areas	Chemical Structure

HY-W020780

mPEG5000-Mal mPEG5000-Maleimide	Biochemical Assay Reagents	Cancer
mPEG5000-Mal (mPEG5000-Maleimide) is a PEG-derived selective covalent binding agent for sulfhydryl groups (RSGs), which can form irreversible thioether bonds with sulfhydryl groups under near-neutral conditions via the maleimide group. The mechanism of action of mPEG5000-Mal can be divided into two categories: firstly, as an enzyme modifier, it binds to target proteins through hydrophobic interactions, hydrogen bonds, and van der Waals forces, altering the protein's secondary structure; secondly, as a nanoparticle surface modifier, it covalently binds to sulfhydryl groups on the surface of red blood cells, changing the surface properties and morphology of the red blood cells, leading to their phagocytosis by macrophages of the reticuloendothelial system. mPEG5000-Mal can react with free cysteine in proteins, increasing the apparent molecular weight of the modified protein by 10-15 kDa for detection purposes. mPEG5000-Mal can enhance the thermal stability and catalytic activity of enzymes, and improve the macrophage targeting of nanoparticles, enabling targeted drug delivery. mPEG5000-Mal can be applied in enzyme engineering research in the food industry and in oncology, assisting radiotherapy by inhibiting tumor-associated macrophage infiltration and enhancing anti-tumor immune responses .

HY-B0633D

Hyaluronic acid sodium (MW 200-1560)	CD44 Endogenous Metabolite Bacterial Akt PI3K	Neurological Disease Metabolic Disease Inflammation/Immunology Cancer
Hyaluronic acid sodium (MW 200-1560) is a biopolymer composed of repeating disaccharide units, with a molecular weight of 200-1560. Hyaluronic acid sodium is a major component of the extracellular matrix (ECM). It is synthesized on the plasma membrane. Hyaluronic acid sodium exerts its effects by binding to receptors CD44 and RHAMM. Hyaluronic acid sodium activates PI3K-Akt signaling. Hyaluronic acid sodium also enhances cell invasion and angiogenesis by promoting or stimulating the binding of proteolytic MMP-9 to the cell surface. Elevated hyaluronic acid levels are associated with tumor cell growth, adhesion, migration, invasion, and angiogenesis in digestive system cancers. Hyaluronic acid sodium is involved in tissue remodeling and rapid cell proliferation in several physiological processes, including embryonic morphogenesis and wound healing. Hyaluronic acid sodium can be used as a regulator of cancer-associated lymphangiogenesis. Hyaluronic acid sodium can be used as a drug delivery carrier for sodium butyrate, enhancing its anti-proliferative activity against breast cancer cell lines. Hyaluronic acid sodium can lubricate the corneal endothelium. Hyaluronic acid sodium can improve tissue hydration and enhance the resistance of cells to mechanical damage. Hyaluronic acid sodium has been conjugated with antibodies to ensure that the active compound continues to exert its effects at the site of inflammation. Hyaluronic acid sodium can be used in research in the fields of osteoarthritis, ophthalmology, cosmetic dermatology, oncology, and liver diseases .

HY-B0633E

Hyaluronic acid, low endotoxin Hyaluronan, low endotoxin; Hyaluronate, low endotoxin	Endogenous Metabolite CD44 Bacterial Akt PI3K	Neurological Disease Metabolic Disease Inflammation/Immunology Cancer
Hyaluronic acid, low endotoxin (Hyaluronan, low endotoxin) is a biopolymer composed of repeating disaccharide units containing low levels of endotoxin. Hyaluronic acid is a major component of the extracellular matrix (ECM). It is synthesized on the plasma membrane. Hyaluronic acid exerts its effects by binding to receptors CD44 and RHAMM. Hyaluronic acid activates PI3K-Akt signaling. Hyaluronic acid also enhances cell invasion and angiogenesis by promoting or stimulating the binding of proteolytic MMP-9 to the cell surface. Elevated hyaluronic acid levels are associated with tumor cell growth, adhesion, migration, invasion, and angiogenesis in digestive system cancers. Hyaluronic acid is involved in tissue remodeling and rapid cell proliferation in several physiological processes, including embryonic morphogenesis and wound healing. Hyaluronic acid can be used as a regulator of cancer-associated lymphangiogenesis. Hyaluronic acid can be used as a drug delivery carrier for sodium butyrate, enhancing its anti-proliferative activity against breast cancer cell lines. Hyaluronic acid can lubricate the corneal endothelium. Hyaluronic acid can improve tissue hydration and enhance the resistance of cells to mechanical damage. Hyaluronic acid has been conjugated with antibodies to ensure that the active compound continues to exert its effects at the site of inflammation. Hyaluronic acid can be used in research in the fields of osteoarthritis, ophthalmology, cosmetic dermatology, oncology, and liver diseases .

HY-P1848

Pep-1 (uncapped) 2 Publications Verification	Interleukin Related	Cancer
Pep-1 (uncapped) is a specific ligand of IL-13Ra2. Pep-1 (uncapped) exerts cell penetrating activity through receptor-mediated endocytosis, can cross the *blood-tumor* barrier (BTB)** and target glioma cells. Pep-1 (uncapped) can enhance the uptake of nanoparticles by tumor cells and enhance the cell penetration ability of nanoparticles, and can be used to develop targeted drug delivery systems for glioma .

HY-W109224

3,3'-(Propane-2,2-diylbis(sulfanediyl))dipropionic acid	ADC Linker	Cancer
3,3'-(Propane-2, 2-Diylbis (sulfanediyl))dipropionic acid is a ROS-sensitive cleavable linker that can be used in the synthesis of ADCs. 3,3'-(Propane-2,2-diylbis(sulfanediyl))dipropionic acid is promising for research of tumor drug delivery systems .

HY-175201

pro-FTY	LPL Receptor STAT	Cancer
pro-FTY, a FTY720 (HY-12005) anticancer prodrug, is a sphingosine-1-phosphate (S1P) (HY-108496) inhibitor. pro-FTY specifically inhibits S1P signaling in cancer cells using a drug delivery system (DDS) that reacts with acrolein. pro-FTY significantly inhibits the survival of breast cancer cells, including multidrug-resistant cells and its organoids resistant to Paclitaxel (HY-B0015) or Doxorubicin (HY-15142A). pro-FTY potently suppresses tumor growth in 4T1 cells or organoids xenograft tumors mice model while avoiding lymphocytopenia .

HY-169478

Lipid N2-3L	Liposome	Cancer
Lipid N2-3L is an ionizable cationic lipid (pK_a = 8.99) that can be used to generate supramolecular lipid nanoparticles (SMLNPs) for mRNA delivery. Lipid nanoparticles formed by encapsulating a luciferase reporter gene with Lipid N2-3L were detected to accumulate in the lymph nodes of mice, indicating that they can effectively enter the mouse immune system. Lipid nanoparticles formed by encapsulating ovalbumin mRNA and the TLR7/8 agonist Resiquimod (HY-13740) with Lipid N2-3L were able to reduce tumor volume and increase survival in the MC-38-OVA mouse colon cancer model. Lipid N2-3L can be used in the research of drug delivery for cancer-related therapies .

Cat. No.	Product Name	Type

HY-W020780

mPEG5000-Mal mPEG5000-Maleimide	Biochemical Assay Reagents
mPEG5000-Mal (mPEG5000-Maleimide) is a PEG-derived selective covalent binding agent for sulfhydryl groups (RSGs), which can form irreversible thioether bonds with sulfhydryl groups under near-neutral conditions via the maleimide group. The mechanism of action of mPEG5000-Mal can be divided into two categories: firstly, as an enzyme modifier, it binds to target proteins through hydrophobic interactions, hydrogen bonds, and van der Waals forces, altering the protein's secondary structure; secondly, as a nanoparticle surface modifier, it covalently binds to sulfhydryl groups on the surface of red blood cells, changing the surface properties and morphology of the red blood cells, leading to their phagocytosis by macrophages of the reticuloendothelial system. mPEG5000-Mal can react with free cysteine in proteins, increasing the apparent molecular weight of the modified protein by 10-15 kDa for detection purposes. mPEG5000-Mal can enhance the thermal stability and catalytic activity of enzymes, and improve the macrophage targeting of nanoparticles, enabling targeted drug delivery. mPEG5000-Mal can be applied in enzyme engineering research in the food industry and in oncology, assisting radiotherapy by inhibiting tumor-associated macrophage infiltration and enhancing anti-tumor immune responses .

mPEG5000-Mal

mPEG5000-Maleimide

Biochemical Assay Reagents

mPEG5000-Mal (mPEG5000-Maleimide) is a PEG-derived selective covalent binding agent for sulfhydryl groups (RSGs), which can form irreversible thioether bonds with sulfhydryl groups under near-neutral conditions via the maleimide group. The mechanism of action of mPEG5000-Mal can be divided into two categories: firstly, as an enzyme modifier, it binds to target proteins through hydrophobic interactions, hydrogen bonds, and van der Waals forces, altering the protein's secondary structure; secondly, as a nanoparticle surface modifier, it covalently binds to sulfhydryl groups on the surface of red blood cells, changing the surface properties and morphology of the red blood cells, leading to their phagocytosis by macrophages of the reticuloendothelial system. mPEG5000-Mal can react with free cysteine in proteins, increasing the apparent molecular weight of the modified protein by 10-15 kDa for detection purposes. mPEG5000-Mal can enhance the thermal stability and catalytic activity of enzymes, and improve the macrophage targeting of nanoparticles, enabling targeted drug delivery. mPEG5000-Mal can be applied in enzyme engineering research in the food industry and in oncology, assisting radiotherapy by inhibiting tumor-associated macrophage infiltration and enhancing anti-tumor immune responses .

HY-B0633E

Hyaluronic acid, low endotoxin Hyaluronan, low endotoxin; Hyaluronate, low endotoxin	Biochemical Assay Reagents
Hyaluronic acid, low endotoxin (Hyaluronan, low endotoxin) is a biopolymer composed of repeating disaccharide units containing low levels of endotoxin. Hyaluronic acid is a major component of the extracellular matrix (ECM). It is synthesized on the plasma membrane. Hyaluronic acid exerts its effects by binding to receptors CD44 and RHAMM. Hyaluronic acid activates PI3K-Akt signaling. Hyaluronic acid also enhances cell invasion and angiogenesis by promoting or stimulating the binding of proteolytic MMP-9 to the cell surface. Elevated hyaluronic acid levels are associated with tumor cell growth, adhesion, migration, invasion, and angiogenesis in digestive system cancers. Hyaluronic acid is involved in tissue remodeling and rapid cell proliferation in several physiological processes, including embryonic morphogenesis and wound healing. Hyaluronic acid can be used as a regulator of cancer-associated lymphangiogenesis. Hyaluronic acid can be used as a drug delivery carrier for sodium butyrate, enhancing its anti-proliferative activity against breast cancer cell lines. Hyaluronic acid can lubricate the corneal endothelium. Hyaluronic acid can improve tissue hydration and enhance the resistance of cells to mechanical damage. Hyaluronic acid has been conjugated with antibodies to ensure that the active compound continues to exert its effects at the site of inflammation. Hyaluronic acid can be used in research in the fields of osteoarthritis, ophthalmology, cosmetic dermatology, oncology, and liver diseases .

Hyaluronic acid, low endotoxin

Hyaluronan, low endotoxin; Hyaluronate, low endotoxin

Biochemical Assay Reagents

Hyaluronic acid, low endotoxin (Hyaluronan, low endotoxin) is a biopolymer composed of repeating disaccharide units containing low levels of endotoxin. Hyaluronic acid is a major component of the extracellular matrix (ECM). It is synthesized on the plasma membrane. Hyaluronic acid exerts its effects by binding to receptors CD44 and RHAMM. Hyaluronic acid activates PI3K-Akt signaling. Hyaluronic acid also enhances cell invasion and angiogenesis by promoting or stimulating the binding of proteolytic MMP-9 to the cell surface. Elevated hyaluronic acid levels are associated with tumor cell growth, adhesion, migration, invasion, and angiogenesis in digestive system cancers. Hyaluronic acid is involved in tissue remodeling and rapid cell proliferation in several physiological processes, including embryonic morphogenesis and wound healing. Hyaluronic acid can be used as a regulator of cancer-associated lymphangiogenesis. Hyaluronic acid can be used as a drug delivery carrier for sodium butyrate, enhancing its anti-proliferative activity against breast cancer cell lines. Hyaluronic acid can lubricate the corneal endothelium. Hyaluronic acid can improve tissue hydration and enhance the resistance of cells to mechanical damage. Hyaluronic acid has been conjugated with antibodies to ensure that the active compound continues to exert its effects at the site of inflammation. Hyaluronic acid can be used in research in the fields of osteoarthritis, ophthalmology, cosmetic dermatology, oncology, and liver diseases .

Cat. No.	Product Name	Target	Research Area

HY-P1848

Pep-1 (uncapped) 2 Publications Verification	Interleukin Related	Cancer
Pep-1 (uncapped) is a specific ligand of IL-13Ra2. Pep-1 (uncapped) exerts cell penetrating activity through receptor-mediated endocytosis, can cross the *blood-tumor* barrier (BTB)** and target glioma cells. Pep-1 (uncapped) can enhance the uptake of nanoparticles by tumor cells and enhance the cell penetration ability of nanoparticles, and can be used to develop targeted drug delivery systems for glioma .

Cat. No.	Product Name		Classification

HY-175201

pro-FTY		Azide
pro-FTY, a FTY720 (HY-12005) anticancer prodrug, is a sphingosine-1-phosphate (S1P) (HY-108496) inhibitor. pro-FTY specifically inhibits S1P signaling in cancer cells using a drug delivery system (DDS) that reacts with acrolein. pro-FTY significantly inhibits the survival of breast cancer cells, including multidrug-resistant cells and its organoids resistant to Paclitaxel (HY-B0015) or Doxorubicin (HY-15142A). pro-FTY potently suppresses tumor growth in 4T1 cells or organoids xenograft tumors mice model while avoiding lymphocytopenia .

Cat. No.	Product Name		Classification

HY-169478

Lipid N2-3L		Cationic Lipids
Lipid N2-3L is an ionizable cationic lipid (pK_a = 8.99) that can be used to generate supramolecular lipid nanoparticles (SMLNPs) for mRNA delivery. Lipid nanoparticles formed by encapsulating a luciferase reporter gene with Lipid N2-3L were detected to accumulate in the lymph nodes of mice, indicating that they can effectively enter the mouse immune system. Lipid nanoparticles formed by encapsulating ovalbumin mRNA and the TLR7/8 agonist Resiquimod (HY-13740) with Lipid N2-3L were able to reduce tumor volume and increase survival in the MC-38-OVA mouse colon cancer model. Lipid N2-3L can be used in the research of drug delivery for cancer-related therapies .

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