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LAP (Lithium phenyl-2,4,6-trimethylbenzoylphosphinate) is a free radical initiator. The free radicals produced by LAP under bioprinting conditions are potentially cytotoxic and mutagenic. In addition, the concentration of LAP affects the mechanical strength of 3D printed scaffolds. Generally, the concentration range of LAP used for curing is 0.05%-1%. The elastic modulus produced at a concentration of 0.1% is the highest, with enhanced mechanical properties and excellent biocompatibility .
LSKL, Inhibitor of Thrombospondin (TSP-1) TFA is a latency-associated protein (LAP)-TGFβ derived tetrapeptide and a competitive TGF-β1 antagonist. LSKL, Inhibitor of Thrombospondin (TSP-1) TFA inhibits the binding of TSP-1 to LAP and alleviates renal interstitial fibrosis and hepatic fibrosis. LSKL, Inhibitor of Thrombospondin (TSP-1) TFA suppresses subarachnoid fibrosis via inhibition of TSP-1-mediated TGF-β1 activity, prevents the development of chronic hydrocephalus and improves long-term neurocognitive defects following subarachnoid hemorrhage (SAH). LSKL, Inhibitor of Thrombospondin (TSP-1) TFA can readily crosse the blood-brain barrier .
LSKL, Inhibitor of Thrombospondin (TSP-1) is a latency-associated protein (LAP)-TGFβ derived tetrapeptide and a competitive TGF-β1 antagonist. LSKL, Inhibitor of Thrombospondin (TSP-1) inhibits the binding of TSP-1 to LAP and alleviates renal interstitial fibrosis and hepatic fibrosis. LSKL, Inhibitor of Thrombospondin (TSP-1) suppresses subarachnoid fibrosis via inhibition of TSP-1-mediated TGF-β1 activity, prevents the development of chronic hydrocephalus and improves long-term neurocognitive defects following subarachnoid hemorrhage (SAH). LSKL, Inhibitor of Thrombospondin (TSP-1) can readily crosse the blood-brain barrier .
LAP3 Human Pre-designed siRNA Set A contains three designed siRNAs for LAP3 gene (Human), as well as a negative control, a positive control, and a FAM-labeled negative control.
L-AP5 (L-APV; L-2-Amino-5-phosphonovaleric acid) is an NMDA antagonist and is the isomer of D-AP5 (HY-100714A).
L-AP5 shows a relatively weak amino acid and synaptic blocking activity .
L-AP3, metabotropic glutamate receptor (mGluR) antagonist, inhibits D-phosphoserine and L-phosphoserine with IC50s of 368 μM and 2087 μM, respectively .
L-AP4 (L-APB) is a potent and specific agonist for the group III mGluRs, with EC50s of 0.13, 0.29, 1.0, 249 μM for mGlu4, mGlu8, mGlu6 and mGlu7 receptors, respectively .
L-AP4 (L-APB) monohydrate is a potent and specific agonist for the group III mGluRs, with EC50s of 0.13, 0.29, 1.0, 249 μM for mGlu4, mGlu8, mGlu6 and mGlu7 receptors, respectively .
DDD00057570 is a selective M17 leucyl-aminopeptidase (LAP) inhibitor. DDD00057570 inhibits L. major and L. donovani intracellular amastigotes in vitro growth .
L-Leucine-7-amido-4-methylcoumarin (Leu-AMC) hydrochloride is a bright blue fluorogenic peptidyl substrate for LAP3 (leucine aminopeptidase). L-Leucine-7-amido-4-methylcoumarin hydrochloride can be used for leucine aminopeptidase inhibition assays in vitro .
H-Leu-Ser-Lys-Leu-OH (LSYL) is a latency-associated peptide at the amino terminus of LAP, with inhibitory effect on TGF-β1 activation. H-Leu-Ser-Lys-Leu-OH, binding with KRFK (HY-P3970), can block the signal transduction of TGF-β1, and prevent the progression of hepatic damage and fibrosis .
Heparin Methacrylate (HepMA) is methacrylated heparin and is an ideal tissue engineering scaffold material and 3D printing bioink . Heparin Methacrylate needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Methacrylated Type I collagen (Col1MA) is a methacrylated tissue engineering scaffold material that retains the basic properties of natural collagen . Methacrylated Type I collagen needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Gelatin Methacryloyl (GelMA) is a derivative obtained by the reaction of chitin anhydride (methacrylic anhydride, MA) and gelatin. The hydrogel formed by Gelatin Methacryloyl has good biocompatibility and biodegradability, photocrosslinking ability and adjustable physical properties . GelMA, 30% methacrylation needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Gelatin Methacryloyl (GelMA) is a derivative obtained by the reaction of chitin anhydride (methacrylic anhydride, MA) and gelatin. The hydrogel formed by Gelatin Methacryloyl has good biocompatibility and biodegradability, photocrosslinking ability and adjustable physical properties . GelMA, 90% methacrylation needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Hyaluronic acid Methacryloyl (HAMA) is methacrylated hyaluronic acid that is biocompatible. Hyaluronic acid Methacryloyl is also used as a 3D printing hydrogel ink, which has the characteristics of fast photosensitive response, fast gelation speed and stable hydrogel performance. Hyaluronic acid Methacryloyl can quickly induce gelation with lithium phenyl-2,4,6-trimethylbenzoylphosphinate (LAP) under UV irradiation. The combination of Hyaluronic acid Methacryloyl and tissue-specific extracellular matrix (ECM) materials (such as pancreatic extracellular matrix (pECM)) will become an important source material for organoid culture .
Poly-L-lysine Methacryloyl (PLMA) is methacrylated polylysine. When Poly-L-lysine Methacryloyl is cross-linked on polyetheretherketone (PEEK) through UV-induced cross-linking, it can improve the hydrophilicity of PEEK and retain its own degradation bioinertness . Poly-L-lysine Methacryloyl needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Dextran Methacryloyl (MW 200000) is a methacryloyl dextran that converts into cell matrix gels. Dextran Methacryloyl (MW 200000) formed gels that had no cytotoxic effects on fibroblasts, but cells adhered only inefficiently in long-term experiments . Dextran Methacryloyl (MW 200000) needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Dextran Methacryloyl (MW 500000) is a methacryloyl dextran that converts into cell matrix gels. Dextran Methacryloyl (MW 500000) formed gels that had no cytotoxic effects on fibroblasts, but cells adhered only inefficiently in long-term experiments . Dextran Methacryloyl (MW 500000) needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Alginate Methacryloyl (MW 50000) is a methacryloyl alginate with potential for use as a tissue engineering scaffold and 3D printing ink. Alginate Methacryloyl (MW 50000) is biocompatible, non-immunogenic, has low toxicity and is capable of physical cross-linking with divalent cations such as calcium . Alginate Methacryloyl (MW 50000) needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Hyaluronic acid Methacryloyl (HAMA) MW 150 kDa is methacrylated hyaluronic acid that is biocompatible. Hyaluronic acid Methacryloyl is also used as a 3D printing hydrogel ink, which has the characteristics of fast photosensitive response, fast gelation speed and stable hydrogel performance. Hyaluronic acid Methacryloyl can quickly induce gelation with lithium phenyl-2,4,6-trimethylbenzoylphosphinate (LAP) under UV irradiation. The combination of Hyaluronic acid Methacryloyl and tissue-specific extracellular matrix (ECM) materials (such as pancreatic extracellular matrix (pECM)) will become an important source material for organoid culture .
Alginate Methacryloyl (MW 300000) is a methacryloyl alginate with potential for use as a tissue engineering scaffold and 3D printing ink. Alginate Methacryloyl (MW 300000) is biocompatible, non-immunogenic, has low toxicity and is capable of physical cross-linking with divalent cations such as calcium . Alginate Methacryloyl (MW 300000) needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Carboxymethyl chitosan Methacryloyl (CMCSMA) is methacrylated carboxymethyl chitosan with properties as a 3D printing ink. A composite hydrogel made of Carboxymethyl chitosan Methacryloyl can effectively accelerate bone healing in an infectious microenvironment after implantation in a rat model of Staphylococcus aureus-infected femoral defect . Carboxymethyl chitosan Methacryloyl needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Red Fluorescent Gelatin Methacryloyl (Red Fluorescent GelMA) is methacryloyl gelatin (GelMA) with red fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Red Fluorescent Gelatin Methacryloyl acts as a scaffold and can be used to engineer tissue analogs from the vasculature to cartilage and bone, allowing cells to proliferate and spread . GelMA, 30% methacrylation, Red Fluorescent needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Green Fluorescent Gelatin Methacryloyl (Green Fluorescent GelMA) is methacryloyl gelatin (GelMA) with green fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Green Fluorescent Gelatin Methacryloyl acts as a scaffold and can be used to engineer tissue analogs from the vasculature to cartilage and bone, allowing cells to proliferate and spread . GelMA, 30% methacrylation, Green Fluorescent needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Red Fluorescent Gelatin Methacryloyl (Red Fluorescent GelMA) is methacryloyl gelatin (GelMA) with red fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Red Fluorescent Gelatin Methacryloyl acts as a scaffold and can be used to engineer tissue analogs from the vasculature to cartilage and bone, allowing cells to proliferate and spread . GelMA, 90% methacrylation, Red Fluorescent needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Red Fluorescent Gelatin Methacryloyl (Red Fluorescent GelMA) is methacryloyl gelatin (GelMA) with red fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Red Fluorescent Gelatin Methacryloyl acts as a scaffold and can be used to engineer tissue analogs from the vasculature to cartilage and bone, allowing cells to proliferate and spread . GelMA, 60% methacrylation, Red Fluorescent needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Green Fluorescent Gelatin Methacryloyl (Green Fluorescent GelMA) is methacryloyl gelatin (GelMA) with green fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Green Fluorescent Gelatin Methacryloyl acts as a scaffold and can be used to engineer tissue analogs from the vasculature to cartilage and bone, allowing cells to proliferate and spread . GelMA, 60% methacrylation, Green Fluorescent needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Green Fluorescent Gelatin Methacryloyl (Green Fluorescent GelMA) is methacryloyl gelatin (GelMA) with green fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Green Fluorescent Gelatin Methacryloyl acts as a scaffold and can be used to engineer tissue analogs from the vasculature to cartilage and bone, allowing cells to proliferate and spread . GelMA, 90% methacrylation, Green Fluorescent needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Polyether F127 Diacrylate (F127DA) is a triblock copolymer of acrylated polyethylene glycol-polypropylene glycol-polyethylene glycol. Polyether F127 Diacrylate rapidly crosslinks and cures to form a gel under the action of photoinitiators in UV and visible light. Polyether F127 Diacrylate has excellent thermo-gelling properties and good biosafety. Polyether F127 Diacrylate needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Gelatin Methacryloyl (GelMA), 30% methacrylation, blue fluorescent is methacrylated gelatin (GelMA) with blue fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Gelatin Methacryloyl, 30% methacrylation, blue fluorescent has a scaffolding effect and can be used to design tissue analogs from vasculature to cartilage and bone, allowing cell proliferation and spreading. Gelatin Methacryloyl, 30% methacrylation, blue fluorescent needs to be self-assembled into fibrous hydrogels under the action of the photoinitiator LAP (HY-44076), and target bioactive adhesion sites, exert inherent support for tissue cells and biodegradation activity. Application direction: cell culture, biological 3D printing, tissue engineering, etc.
Elastin Methacrylated (ElaMA) elastin recruits and modulates innate immune cells and accelerates angiogenesis at the wound site, thereby improving wound regeneration. Elastin Methacrylated attracts large numbers of neutrophils and primarily M2 macrophages to the wound and induces their penetration into the hydrogel. Elastin Methacrylated has excellent immunomodulatory effects, leading to superior angiogenesis, collagen deposition and dermal regeneration . Elastin Methacrylated needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Silk Fibroin Methacryloyl (FibMA) is methacrylated silk fibroin with excellent biocompatibility, stable mechanical properties and good processing properties, and was selected as the substrate for multifunctional microneedle (MN) patches. . MN patches made of Silk Fibroin Methacryloyl exhibit excellent biocompatibility, sustained drug release, pro-angiogenic, antioxidant and antibacterial properties depending on the specific drug encapsulated . Silk Fibroin Methacryloyl needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Gelatin Methacryloyl (GelMA), 90% methacrylation, blue fluorescent is methacrylated gelatin (GelMA) with blue fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Gelatin Methacryloyl, 90% methacrylation, blue fluorescent has a scaffolding effect and can be used to design tissue analogs from vasculature to cartilage and bone, allowing cell proliferation and spreading. Gelatin Methacryloyl, 30% methacrylation, blue fluorescent needs to be self-assembled into fibrous hydrogels under the action of the photoinitiator LAP (HY-44076), and target bioactive adhesion sites, exert inherent support for tissue cells and biodegradation activity. Application direction: cell culture, biological 3D printing, tissue engineering, etc.
Gelatin Methacryloyl (GelMA), 60% methacrylation, blue fluorescent is methacrylated gelatin (GelMA) with blue fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Gelatin Methacryloyl, 60% methacrylation, blue fluorescent has a scaffolding effect and can be used to design tissue analogs from vasculature to cartilage and bone, allowing cell proliferation and spreading. Gelatin Methacryloyl, 30% methacrylation, blue fluorescent needs to be self-assembled into fibrous hydrogels under the action of the photoinitiator LAP (HY-44076), and target bioactive adhesion sites, exert inherent support for tissue cells and biodegradation activity. Application direction: cell culture, biological 3D printing, tissue engineering, etc.
Chondroitin Sulfate Methacryloyl (CSMA) is methacrylated chondroitin sulfate and is biocompatible. Chondroitin Sulfate Methacryloyl has a higher degree of methacrylation than HAMA (HY-158220), and the degree of methacrylation is closely related to customizable mechanical properties, swelling properties and enzymatic degradability. Chondroitin Sulfate Methacryloyl is a versatile biomaterial suitable for biomimetic hydrogel scaffolds and an ideal 3D printing hydrogel ink . Chondroitin Sulfate Methacryloyl needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
L-Leucine-7-amido-4-methylcoumarin (Leu-AMC) hydrochloride is a bright blue fluorogenic peptidyl substrate for LAP3 (leucine aminopeptidase). L-Leucine-7-amido-4-methylcoumarin hydrochloride can be used for leucine aminopeptidase inhibition assays in vitro .
LAP (Lithium phenyl-2,4,6-trimethylbenzoylphosphinate) is a free radical initiator. The free radicals produced by LAP under bioprinting conditions are potentially cytotoxic and mutagenic. In addition, the concentration of LAP affects the mechanical strength of 3D printed scaffolds. Generally, the concentration range of LAP used for curing is 0.05%-1%. The elastic modulus produced at a concentration of 0.1% is the highest, with enhanced mechanical properties and excellent biocompatibility .
Heparin Methacrylate (HepMA) is methacrylated heparin and is an ideal tissue engineering scaffold material and 3D printing bioink . Heparin Methacrylate needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Methacrylated Type I collagen (Col1MA) is a methacrylated tissue engineering scaffold material that retains the basic properties of natural collagen . Methacrylated Type I collagen needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Gelatin Methacryloyl (GelMA) is a derivative obtained by the reaction of chitin anhydride (methacrylic anhydride, MA) and gelatin. The hydrogel formed by Gelatin Methacryloyl has good biocompatibility and biodegradability, photocrosslinking ability and adjustable physical properties . GelMA, 30% methacrylation needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Alginate Methacryloyl (MW 50000) is a methacryloyl alginate with potential for use as a tissue engineering scaffold and 3D printing ink. Alginate Methacryloyl (MW 50000) is biocompatible, non-immunogenic, has low toxicity and is capable of physical cross-linking with divalent cations such as calcium . Alginate Methacryloyl (MW 50000) needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Gelatin Methacryloyl (GelMA) is a derivative obtained by the reaction of chitin anhydride (methacrylic anhydride, MA) and gelatin. The hydrogel formed by Gelatin Methacryloyl has good biocompatibility and biodegradability, photocrosslinking ability and adjustable physical properties . GelMA, 90% methacrylation needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Hyaluronic acid Methacryloyl (HAMA) is methacrylated hyaluronic acid that is biocompatible. Hyaluronic acid Methacryloyl is also used as a 3D printing hydrogel ink, which has the characteristics of fast photosensitive response, fast gelation speed and stable hydrogel performance. Hyaluronic acid Methacryloyl can quickly induce gelation with lithium phenyl-2,4,6-trimethylbenzoylphosphinate (LAP) under UV irradiation. The combination of Hyaluronic acid Methacryloyl and tissue-specific extracellular matrix (ECM) materials (such as pancreatic extracellular matrix (pECM)) will become an important source material for organoid culture .
Poly-L-lysine Methacryloyl (PLMA) is methacrylated polylysine. When Poly-L-lysine Methacryloyl is cross-linked on polyetheretherketone (PEEK) through UV-induced cross-linking, it can improve the hydrophilicity of PEEK and retain its own degradation bioinertness . Poly-L-lysine Methacryloyl needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Dextran Methacryloyl (MW 200000) is a methacryloyl dextran that converts into cell matrix gels. Dextran Methacryloyl (MW 200000) formed gels that had no cytotoxic effects on fibroblasts, but cells adhered only inefficiently in long-term experiments . Dextran Methacryloyl (MW 200000) needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Dextran Methacryloyl (MW 500000) is a methacryloyl dextran that converts into cell matrix gels. Dextran Methacryloyl (MW 500000) formed gels that had no cytotoxic effects on fibroblasts, but cells adhered only inefficiently in long-term experiments . Dextran Methacryloyl (MW 500000) needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Hyaluronic acid Methacryloyl (HAMA) MW 150 kDa is methacrylated hyaluronic acid that is biocompatible. Hyaluronic acid Methacryloyl is also used as a 3D printing hydrogel ink, which has the characteristics of fast photosensitive response, fast gelation speed and stable hydrogel performance. Hyaluronic acid Methacryloyl can quickly induce gelation with lithium phenyl-2,4,6-trimethylbenzoylphosphinate (LAP) under UV irradiation. The combination of Hyaluronic acid Methacryloyl and tissue-specific extracellular matrix (ECM) materials (such as pancreatic extracellular matrix (pECM)) will become an important source material for organoid culture .
Alginate Methacryloyl (MW 300000) is a methacryloyl alginate with potential for use as a tissue engineering scaffold and 3D printing ink. Alginate Methacryloyl (MW 300000) is biocompatible, non-immunogenic, has low toxicity and is capable of physical cross-linking with divalent cations such as calcium . Alginate Methacryloyl (MW 300000) needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Carboxymethyl chitosan Methacryloyl (CMCSMA) is methacrylated carboxymethyl chitosan with properties as a 3D printing ink. A composite hydrogel made of Carboxymethyl chitosan Methacryloyl can effectively accelerate bone healing in an infectious microenvironment after implantation in a rat model of Staphylococcus aureus-infected femoral defect . Carboxymethyl chitosan Methacryloyl needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Red Fluorescent Gelatin Methacryloyl (Red Fluorescent GelMA) is methacryloyl gelatin (GelMA) with red fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Red Fluorescent Gelatin Methacryloyl acts as a scaffold and can be used to engineer tissue analogs from the vasculature to cartilage and bone, allowing cells to proliferate and spread . GelMA, 30% methacrylation, Red Fluorescent needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Green Fluorescent Gelatin Methacryloyl (Green Fluorescent GelMA) is methacryloyl gelatin (GelMA) with green fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Green Fluorescent Gelatin Methacryloyl acts as a scaffold and can be used to engineer tissue analogs from the vasculature to cartilage and bone, allowing cells to proliferate and spread . GelMA, 30% methacrylation, Green Fluorescent needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Red Fluorescent Gelatin Methacryloyl (Red Fluorescent GelMA) is methacryloyl gelatin (GelMA) with red fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Red Fluorescent Gelatin Methacryloyl acts as a scaffold and can be used to engineer tissue analogs from the vasculature to cartilage and bone, allowing cells to proliferate and spread . GelMA, 90% methacrylation, Red Fluorescent needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Red Fluorescent Gelatin Methacryloyl (Red Fluorescent GelMA) is methacryloyl gelatin (GelMA) with red fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Red Fluorescent Gelatin Methacryloyl acts as a scaffold and can be used to engineer tissue analogs from the vasculature to cartilage and bone, allowing cells to proliferate and spread . GelMA, 60% methacrylation, Red Fluorescent needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Green Fluorescent Gelatin Methacryloyl (Green Fluorescent GelMA) is methacryloyl gelatin (GelMA) with green fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Green Fluorescent Gelatin Methacryloyl acts as a scaffold and can be used to engineer tissue analogs from the vasculature to cartilage and bone, allowing cells to proliferate and spread . GelMA, 60% methacrylation, Green Fluorescent needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Green Fluorescent Gelatin Methacryloyl (Green Fluorescent GelMA) is methacryloyl gelatin (GelMA) with green fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Green Fluorescent Gelatin Methacryloyl acts as a scaffold and can be used to engineer tissue analogs from the vasculature to cartilage and bone, allowing cells to proliferate and spread . GelMA, 90% methacrylation, Green Fluorescent needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Polyether F127 Diacrylate (F127DA) is a triblock copolymer of acrylated polyethylene glycol-polypropylene glycol-polyethylene glycol. Polyether F127 Diacrylate rapidly crosslinks and cures to form a gel under the action of photoinitiators in UV and visible light. Polyether F127 Diacrylate has excellent thermo-gelling properties and good biosafety. Polyether F127 Diacrylate needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Gelatin Methacryloyl (GelMA), 30% methacrylation, blue fluorescent is methacrylated gelatin (GelMA) with blue fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Gelatin Methacryloyl, 30% methacrylation, blue fluorescent has a scaffolding effect and can be used to design tissue analogs from vasculature to cartilage and bone, allowing cell proliferation and spreading. Gelatin Methacryloyl, 30% methacrylation, blue fluorescent needs to be self-assembled into fibrous hydrogels under the action of the photoinitiator LAP (HY-44076), and target bioactive adhesion sites, exert inherent support for tissue cells and biodegradation activity. Application direction: cell culture, biological 3D printing, tissue engineering, etc.
Elastin Methacrylated (ElaMA) elastin recruits and modulates innate immune cells and accelerates angiogenesis at the wound site, thereby improving wound regeneration. Elastin Methacrylated attracts large numbers of neutrophils and primarily M2 macrophages to the wound and induces their penetration into the hydrogel. Elastin Methacrylated has excellent immunomodulatory effects, leading to superior angiogenesis, collagen deposition and dermal regeneration . Elastin Methacrylated needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Silk Fibroin Methacryloyl (FibMA) is methacrylated silk fibroin with excellent biocompatibility, stable mechanical properties and good processing properties, and was selected as the substrate for multifunctional microneedle (MN) patches. . MN patches made of Silk Fibroin Methacryloyl exhibit excellent biocompatibility, sustained drug release, pro-angiogenic, antioxidant and antibacterial properties depending on the specific drug encapsulated . Silk Fibroin Methacryloyl needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
Gelatin Methacryloyl (GelMA), 90% methacrylation, blue fluorescent is methacrylated gelatin (GelMA) with blue fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Gelatin Methacryloyl, 90% methacrylation, blue fluorescent has a scaffolding effect and can be used to design tissue analogs from vasculature to cartilage and bone, allowing cell proliferation and spreading. Gelatin Methacryloyl, 30% methacrylation, blue fluorescent needs to be self-assembled into fibrous hydrogels under the action of the photoinitiator LAP (HY-44076), and target bioactive adhesion sites, exert inherent support for tissue cells and biodegradation activity. Application direction: cell culture, biological 3D printing, tissue engineering, etc.
Gelatin Methacryloyl (GelMA), 60% methacrylation, blue fluorescent is methacrylated gelatin (GelMA) with blue fluorescence, which is obtained by "grafting" fluorescent molecules on GelMA. Gelatin Methacryloyl, 60% methacrylation, blue fluorescent has a scaffolding effect and can be used to design tissue analogs from vasculature to cartilage and bone, allowing cell proliferation and spreading. Gelatin Methacryloyl, 30% methacrylation, blue fluorescent needs to be self-assembled into fibrous hydrogels under the action of the photoinitiator LAP (HY-44076), and target bioactive adhesion sites, exert inherent support for tissue cells and biodegradation activity. Application direction: cell culture, biological 3D printing, tissue engineering, etc.
Chondroitin Sulfate Methacryloyl (CSMA) is methacrylated chondroitin sulfate and is biocompatible. Chondroitin Sulfate Methacryloyl has a higher degree of methacrylation than HAMA (HY-158220), and the degree of methacrylation is closely related to customizable mechanical properties, swelling properties and enzymatic degradability. Chondroitin Sulfate Methacryloyl is a versatile biomaterial suitable for biomimetic hydrogel scaffolds and an ideal 3D printing hydrogel ink . Chondroitin Sulfate Methacryloyl needs to self-assemble into fibrous hydrogel under the action of photoinitiator LAP (HY-44076), and target bioactive adhesion sites, play an inherent supporting role for tissue cells and biodegradable activity. Application: cell culture, biological 3D printing, tissue engineering, etc.
LSKL, Inhibitor of Thrombospondin (TSP-1) TFA is a latency-associated protein (LAP)-TGFβ derived tetrapeptide and a competitive TGF-β1 antagonist. LSKL, Inhibitor of Thrombospondin (TSP-1) TFA inhibits the binding of TSP-1 to LAP and alleviates renal interstitial fibrosis and hepatic fibrosis. LSKL, Inhibitor of Thrombospondin (TSP-1) TFA suppresses subarachnoid fibrosis via inhibition of TSP-1-mediated TGF-β1 activity, prevents the development of chronic hydrocephalus and improves long-term neurocognitive defects following subarachnoid hemorrhage (SAH). LSKL, Inhibitor of Thrombospondin (TSP-1) TFA can readily crosse the blood-brain barrier .
LSKL, Inhibitor of Thrombospondin (TSP-1) is a latency-associated protein (LAP)-TGFβ derived tetrapeptide and a competitive TGF-β1 antagonist. LSKL, Inhibitor of Thrombospondin (TSP-1) inhibits the binding of TSP-1 to LAP and alleviates renal interstitial fibrosis and hepatic fibrosis. LSKL, Inhibitor of Thrombospondin (TSP-1) suppresses subarachnoid fibrosis via inhibition of TSP-1-mediated TGF-β1 activity, prevents the development of chronic hydrocephalus and improves long-term neurocognitive defects following subarachnoid hemorrhage (SAH). LSKL, Inhibitor of Thrombospondin (TSP-1) can readily crosse the blood-brain barrier .
H-Leu-Ser-Lys-Leu-OH (LSYL) is a latency-associated peptide at the amino terminus of LAP, with inhibitory effect on TGF-β1 activation. H-Leu-Ser-Lys-Leu-OH, binding with KRFK (HY-P3970), can block the signal transduction of TGF-β1, and prevent the progression of hepatic damage and fibrosis .
LAP (Lithium phenyl-2,4,6-trimethylbenzoylphosphinate) is a free radical initiator. The free radicals produced by LAP under bioprinting conditions are potentially cytotoxic and mutagenic. In addition, the concentration of LAP affects the mechanical strength of 3D printed scaffolds. Generally, the concentration range of LAP used for curing is 0.05%-1%. The elastic modulus produced at a concentration of 0.1% is the highest, with enhanced mechanical properties and excellent biocompatibility .
TGF beta 1/TGFB1 is a polypeptide member of the transforming growth factor beta superfamily of cytokines. TGF beta 1 is a secreted protein that performs many cellular functions, including the control of cell growth, cell proliferation, cell differentiation, apoptosis, and can regulate the expression and activation of other growth factors, including interferon gamma and tumor necrosis factor alpha. TGF beta 1/TGFB1 LAP Protein, Human (HEK293) is the recombinant human-derived TGF beta 1/TGFB1 LAP protein, expressed by HEK293 , with tag free. and C33S mutation.
TGF beta 1/TGFB1 Protein is initially identified as a growth factor that induces the growth of rodent fibroblasts. TGF beta 1/TGFB1 Protein inhibits the cell cycle in the G1 phase. TGF beta 1/TGFB1 is an endogenous factor controlling apoptosis in normal and pathological tissues. TGF beta 1/TGFB1 Protein, Human (Biotinylated, HEK293, N-Avi) is a recombinant protein (A279-S390) produced by HEK293 cells with Avi tag.
Latent TGF beta 1/TGFB1 Protein is a large extracellular matrix protein and an associated ligand of fibrillinmicrofibrils. Latent TGF beta 1/TGFB1 Protein, Human (C33S, HEK293, His) is a recombinant Biotinylated protein (L30-S390) produced by HEK293 cells with His tag.
TGF beta 1 is a secreted ligand of the TGF-beta superfamily that binds to receptors and activates SMAD transcription factors. Preproprotein is proteolytically processed to produce latency-associated peptide (LAP) and mature peptide. TGF beta 1/TGFB1 LAP Protein, Human (HEK293, N-His) is the recombinant human-derived TGF beta 1/TGFB1 Latency-associated peptide protein, expressed by HEK293 , with N-6*His labeled tag and C33S mutation.
TGF beta 1/TGFB1 Protein is initially identified as a growth factor that induces the growth of rodent fibroblasts. TGF beta 1/TGFB1 Protein inhibits the cell cycle in the G1 phase. TGF beta 1/TGFB1 is an endogenous factor controlling apoptosis in normal and pathological tissues. GMP TGF beta 1/TGFB1 Protein, Human (HEK293) is a GMP-grade recombinant protein (A279-S390) produced by CHO cells.
TGF beta 1/TGFB1 Protein is initially identified as a growth factor that induces the growth of rodent fibroblasts. TGF beta 1/TGFB1 Protein inhibits the cell cycle in the G1 phase. TGF beta 1/TGFB1 is an endogenous factor controlling apoptosis in normal and pathological tissues. TGF beta 1/TGFB1 Protein, Human (112a.a, HEK293) is a recombinant protein (A279-S390) produced by HEK293 cells.
TGF beta 1/TGFB1 is a polypeptide member of the transforming growth factor beta superfamily of cytokines. TGF beta 1 is a secreted protein that performs many cellular functions, including the control of cell growth, cell proliferation, cell differentiation, apoptosis, and can regulate the expression and activation of other growth factors, including interferon gamma and tumor necrosis factor alpha. TGF beta 1/TGFB1 LAP Protein, Human (HEK293, His) is the recombinant human-derived TGF beta 1/TGFB1 Latency-associated peptide protein, expressed by HEK293 , with C-10*His labeled tag and C33S mutation.
PICALM Human Recombinant Protein (HEK293, C-His) plays a critical role in recruiting clathrin and adapter protein complex 2 (AP2) to the cell membrane during coated pit formation and clathrin-vesicle assembly effect. It regulates the size of the clathrin cage and determines membrane recycling. PICALM Recombinant Protein,Human (HEK293,C-His) is the recombinant human-derived PICALM Recombinant protein,Human(HEK293,C-His), expressed by HEK293 , with C-10*His labeled tag. The total length of PICALM Recombinant Protein,Human (HEK293,C-His) is 652 a.a., with molecular weight of ~90-150 kDa.
The LAP3 protein is a cytosolic metallopeptidase that serves as a catalytic entity responsible for the removal of unsubstituted N-terminal hydrophobic amino acids from a variety of peptides. The peptidase activity of LAP3 depends on the presence of Zn(2+) ions, and its substrate specificity can be modulated by binding to other cofactors. LAP3 Protein, Human (HEK293, His) is the recombinant human-derived LAP3 protein, expressed by HEK293 , with C-His labeled tag. The total length of LAP3 Protein, Human (HEK293, His) is 519 a.a., with molecular weight of ~57.6 kDa.
Leucyl aminopeptidase proteins play a role in the putative processing and normal turnover of proteins within cells. It catalyzes the removal of unsubstituted N-terminal amino acids from peptides, suggesting involvement in complex mechanisms controlling intracellular protein dynamics. leucyl aminopeptidase Protein, Geobacillus kaustophilus is the recombinant leucyl aminopeptidase protein, expressed by E. coli , with tag free. The total length of leucyl aminopeptidase Protein, Geobacillus kaustophilus is 500 a.a., .
Leucyl aminopeptidase proteins play a role in the putative processing and normal turnover of proteins within cells. It catalyzes the removal of unsubstituted N-terminal amino acids from peptides, suggesting involvement in complex mechanisms controlling intracellular protein dynamics. leucyl aminopeptidase Protein, Geobacillus kaustophilus (His) is the recombinant leucyl aminopeptidase protein, expressed by E. coli , with N-6*His labeled tag. The total length of leucyl aminopeptidase Protein, Geobacillus kaustophilus (His) is 500 a.a., .
TGF-β3 (transforming growth factor-β3) is a member of a TGF-beta superfamily subgroup that performs many cellular functions. TGF-β3 has a role in embryogenesis and cell differentiation. TGF-β3 also plays a critical role in palatogenesis, the wound healing process. TGF-β3 is capable of binding directly to the type II receptor (TβRII). TGF beta 3/TGFB3 Protein, Human/Mouse/Rat (HEK293) is produced in HEK293 cells, and consists of 112 amino acids (A301-S412).
Caspase-7/CASP7 protein is a thiol protease involved in programmed cell death processes such as apoptosis, pyroptosis, and granzyme-mediated death. It is activated by initiating caspases (CASP8, CASP9 and/or CASP10) and cleaves CLSPN, PARP1, PTGES3 and YY1, mediating apoptosis. Caspase-7/CASP7 Protein, Human (His) is the recombinant human-derived Caspase-7/CASP7 protein, expressed by E. coli , with C-His labeled tag. The total length of Caspase-7/CASP7 Protein, Human (His) is 303 a.a., with molecular weight of ~20 & 11 kDa, respectively.
The GDF-5 protein is critical in bone and cartilage formation, complexly regulating chondrogenic tissue differentiation through dual pathways. It positively affects cartilage formation by inducing SMAD protein signaling by binding to BMPR1B and BMPR1A. GDF-5 Protein, Human is the recombinant human-derived GDF-5 protein, expressed by E. coli , with tag free. The total length of GDF-5 Protein, Human is 120 a.a., with molecular weight of ~15 kDa.
HSPA8/HSC70 is a molecular chaperone that protects the proteome and aids in peptide folding, transport, chaperone-mediated autophagy, and protein complex regulation. It is central to quality control, ensuring correct folding and targeting misfolded proteins for degradation through ATP-dependent cycles. HSPA8/HSC70 Protein, Human (His, Solution) is the recombinant human-derived HSPA8/HSC70 protein, expressed by E. coli , with N-His labeled tag. The total length of HSPA8/HSC70 Protein, Human (His, Solution) is 646 a.a., with molecular weight of ~65 kDa.
HSPA8/HSC70 is a molecular chaperone that protects the proteome and aids in peptide folding, transport, chaperone-mediated autophagy, and protein complex regulation. It is central to quality control, ensuring correct folding and targeting misfolded proteins for degradation through ATP-dependent cycles. HSPA8/HSC70 Protein, Human (N-His) is the recombinant human-derived HSPA8/HSC70 protein, expressed by E. coli , with N-6*His labeled tag. The total length of HSPA8/HSC70 Protein, Human (N-His) is 646 a.a., with molecular weight of ~65 kDa.
LRRC32, a key regulator of TGF-beta activation, maintains TGFB1, TGFB2, and TGFB3 in a latent state during extracellular storage by binding to Latency-associated peptide (LAP). Competing with LTBP1 for LAP binding, LRRC32 effectively modulates integrin-dependent TGF-beta activation. Its significance spans the regulation of TGF-beta-1 (TGFB1) on activated Tregs' surface and the control of TGF-beta-3 (TGFB3) during palate development, emphasizing LRRC32's intricate role in fine-tuning TGF-beta signaling. Interactions with TGFB1, TGFB2, TGFB3, and LAPTM4B contribute to its regulatory functions. GARP&Latent TGF Beta-1 Complex Protein, Human (HEK293, His, Strep) is a recombinant protein dimer complex containing human-derived GARP&Latent TGF Beta-1 Complex protein, expressed by HEK293, with N-6*His, C-3*Strep labeled tag. GARP&Latent TGF Beta-1 Complex Protein, Human (HEK293, His, Strep), has molecular weight of 10-14 & 35-50 & 85-95 kDa, respectively.
TGFB1 proprotein is the precursor of latency-associated peptide (LAP) and active transforming growth factor Beta-1 (TGF-β-1) chain, which maintains TGF-β-1 latency in the extracellular matrix. TGFB1 binds non-covalently to TGF-β-1 and interacts with “environmental molecules” (LTBP1, LRRC32/GARP, LRRC33/NRROS) to regulate TGF-β-1 activation. TGF beta 1/TGFB1 Protein, Canine (HEK293, His) is the recombinant canine-derived TGF beta 1/TGFB1 protein, expressed by HEK293 , with C-His labeled tag. The total length of TGF beta 1/TGFB1 Protein, Canine (HEK293, His) is 361 a.a..
Latent transforming growth factor beta-3 (TGF-beta-3) preprotein serves as a precursor to latency-associated peptide (LAP) and active TGF-beta-3 chains, which serve as regulatory and functional subunits. It plays a crucial role in maintaining the latent state of TGF-β-3 within the extracellular matrix. TGF beta 3/TGFB3 Protein, Human (HEK293, Avi) is the recombinant human-derived TGF beta 3/TGFB3 protein, expressed by HEK293 , with C-Avi labeled tag. The total length of TGF beta 3/TGFB3 Protein, Human (HEK293, Avi) is 112 a.a., with molecular weight of 15-20 kDa.
TGF beta 1/TGFB1 is a polypeptide member of the transforming growth factor beta superfamily of cytokines. TGF beta 1 is a secreted protein that performs many cellular functions, including the control of cell growth, cell proliferation, cell differentiation, apoptosis, and can regulate the expression and activation of other growth factors, including interferon gamma and tumor necrosis factor alpha. Latent TGF beta 1/TGFB1 Protein, Human (HEK293, His) is the recombinant human-derived Latent TGF beta 1/TGFB1 protein, expressed by HEK293 , with C-His labeled tag.
Latent TGF beta 1 (latent TGFB1) is the inactive form of TGF-B1. Latent TGF beta 1 associates with the extracellular matrix (ECM) via LTBP. LTBPs are components of the ECM, so that the proteolytic cleavage of LTBP can lead to the release of latent TGF-beta 1 from the matrix. Besides, the proteolytic cleavage and liberation of active TGFB1 is performed by BMP-1, by a variety of matrix metalloproteinases (MMPs). Latent TGF beta 1/TGFB1 Protein, Rat (HEK293, His) is the recombinant rat-derived Latent TGF beta 1/TGFB1 protein, expressed by HEK293 , with C-His labeled tag. The total length of Latent TGF beta 1/TGFB1 Protein, Rat (HEK293, His) is 361 a.a., with molecular weight of ~55 & 38 & 16 kDa, respectively.
TGF beta 1/TGFB1 Protein is initially identified as a growth factor that induces the growth of rodent fibroblasts. TGF beta 1/TGFB1 Protein inhibits the cell cycle in the G1 phase. TGF beta 1/TGFB1 is an endogenous factor controlling apoptosis in normal and pathological tissues. TGF beta 1/TGFB1 Protein, Mouse (HEK293) is a recombinant protein (A279-S390) produced by HEK293 cells.
In its proprotein form, the TGF beta-1/TGFB1 protein serves as a precursor to latency-associated peptide (LAP) and active transforming growth factor beta-1 (TGF-beta-1) chains.Critical to maintaining the latent state of TGF-β-1 within the extracellular matrix, preprotein interacts with “environmental molecules” such as LTBP1, LRRC32/GARP, and LRRC33/NRROS to regulate TGF-β-1 activation.Animal-Free TGF beta 1/TGFB1 Protein, Mouse (His) is the recombinant mouse-derived animal-FreeTGF beta 1/TGFB1 protein, expressed by E.coli , with C-His labeled tag.
Latent TGF beta 1 (latent TGFB1) is the inactive form of TGF-B1. Latent TGF beta 1 associates with the extracellular matrix (ECM) via LTBP. LTBPs are components of the ECM, so that the proteolytic cleavage of LTBP can lead to the release of latent TGF-beta 1 from the matrix. Besides, the proteolytic cleavage and liberation of active TGFB1 is performed by BMP-1, by a variety of matrix metalloproteinases (MMPs). Latent TGF beta 1/TGFB1 Protein, Rat (HEK293, C-His) is the recombinant rat-derived Latent TGF beta 1/TGFB1 protein, expressed by HEK293 , with C-6*His labeled tag. The total length of Latent TGF beta 1/TGFB1 Protein, Rat (HEK293, C-His) is 361 a.a., with molecular weight of ~55 & 40 & 16 kDa, respectively.
The CXCR4 protein functions as a receptor for the CXC chemokine CXCL12/SDF-1, triggering an increase in intracellular calcium ions and activation of MAPK1/MAPK3. It is actively involved in AKT signaling, which is critical for regulating cell migration, especially in wound healing. CXCR4 Protein, Human (N-His-SUMO, C-Myc) is the recombinant human-derived CXCR4 protein, expressed by E. coli , with N-10*His, C-Myc, N-SUMO labeled tag. The total length of CXCR4 Protein, Human (N-His-SUMO, C-Myc) is 50 a.a., with molecular weight of ~28 kDa.
The CXCR4 protein functions as a receptor for the CXC chemokine CXCL12/SDF-1, triggering an increase in intracellular calcium ions and activation of MAPK1/MAPK3. It is actively involved in AKT signaling, which is critical for regulating cell migration, especially in wound healing. CXCR4 Protein, Human (HEK293, Fc) is the recombinant human-derived CXCR4 protein, expressed by HEK293 , with N-hFc labeled tag. The total length of CXCR4 Protein, Human (HEK293, Fc) is 46 a.a., with molecular weight of 35-45 kDa.
The CXCR4 protein functions as a receptor for the CXC chemokine CXCL12/SDF-1, triggering an increase in intracellular calcium ions and activation of MAPK1/MAPK3. It is actively involved in AKT signaling, which is critical for regulating cell migration, especially in wound healing. CXCR4 Protein, Human (Cell-Free, His) is the recombinant human-derived CXCR4 protein, expressed by E. coli Cell-free , with N-6*His labeled tag. The total length of CXCR4 Protein, Human (Cell-Free, His) is 356 a.a., the molecular weight are 44 KDa (monomer), 100 KDa (dimer), whiel dimers are generally formed.
GARP/latent TGF-b1 complexes are potent inducers of Th17 differentiation in the presence of exogenous IL-6 and inducers of Treg in the presence of IL-2. GARP&Latent TGF beta Complex Protein, Mouse (HEK293, His) is a biotinylated recombinant protein (GARP (I18-N628)&TGF-b1 (L30-S390)) produced by HEK293 cells with His tag.
LRRC32 is a key regulator of TGF-β activation and maintains TGFB1, TGFB2, and TGFB3 in the latent state during extracellular storage by binding to latency-associated peptide (LAP). LRRC32 competes with LTBP1 for LAP binding and effectively regulates integrin-dependent TGF-β activation. GARP&Latent TGF Beta Complex Protein, Human (HEK293, His-Avi) is a recombinant protein dimer complex containing human-derived GARP&Latent TGF Beta Complex protein, expressed by HEK293 , with C-Avi, C-His labeled tag. GARP&Latent TGF Beta Complex Protein, Human (HEK293, His-Avi), has molecular weight of 72-80 kDa.
LRRC32, a key regulator of TGF-beta activation, maintains TGFB1, TGFB2, and TGFB3 in a latent state during extracellular storage by binding to Latency-associated peptide (LAP). Competing with LTBP1 for LAP binding, LRRC32 effectively modulates integrin-dependent TGF-beta activation. Its significance spans the regulation of TGF-beta-1 (TGFB1) on activated Tregs' surface and the control of TGF-beta-3 (TGFB3) during palate development, emphasizing LRRC32's intricate role in fine-tuning TGF-beta signaling. Interactions with TGFB1, TGFB2, TGFB3, and LAPTM4B contribute to its regulatory functions. GARP&Latent TGF beta Complex Protein, Human (Biotinylated, HEK293, His-Avi) is a recombinant protein dimer complex containing human-derived GARP&Latent TGF beta Complex protein, expressed by HEK293, with C-Avi, C-His labeled tag. GARP&Latent TGF beta Complex Protein, Human (Biotinylated, HEK293, His-Avi), has molecular weight of (73-78) kDa (GARP) & 13 kDa & (42-45) kDa (Latent TGF beta 1), respectively.
GARP/latent TGF-b1 complexes are potent inducers of Th17 differentiation in the presence of exogenous IL-6 and inducers of Treg in the presence of IL-2. GARP&Latent TGF beta Complex Protein, Mouse (Biotinylated, HEK293, His-Avi) is a biotinylated recombinant protein (GARP (I18-N628)&TGF-b1 (L30-S390)) produced by HEK293 cells with His-Avi tag.
LRRC32 is a key regulator of TGF-β activation and maintains TGFB1, TGFB2, and TGFB3 in the latent state during extracellular storage by binding to latency-associated peptide (LAP). LRRC32 competes with LTBP1 for LAP binding and effectively regulates integrin-dependent TGF-β activation. GARP (Mutated) &Latent TGF Beta Complex Protein, Human (HEK293, His-Avi) is a recombinant protein dimer complex containing human-derived GARP, expressed by HEK293 , with C-Avi, C-His labeled tag. GARP (Mutated) &Latent TGF Beta Complex Protein, Human (HEK293, His-Avi), has molecular weight of 75-80 kDa.
Latent TGF beta 1/TGFB1 Protein is a large extracellular matrix protein and an associated ligand of fibrillinmicrofibrils. Latent TGF beta 1/TGFB1 Protein, Cynomolgus (C33S, HEK293, His) is a recombinant protein (L30-S390, C33S) produced by HEK293 cells with His tag.
LRRC32 is a key regulator of TGF-β activation and maintains TGFB1, TGFB2, and TGFB3 in the latent state during extracellular storage by binding to latency-associated peptide (LAP). LRRC32 competes with LTBP1 for LAP binding and effectively regulates integrin-dependent TGF-β activation. GARP (Y137H) &Latent TGF Beta Complex Protein, Human (HEK293, His-Avi) is a recombinant protein dimer complex containing human-derived GARP, expressed by HEK293 , with C-Avi, C-His labeled tag. GARP (Y137H) &Latent TGF Beta Complex Protein, Human (HEK293, His-Avi), has molecular weight of 71-75 kDa.
LRRC32 is a key regulator of TGF-β activation and maintains TGFB1, TGFB2, and TGFB3 in the latent state during extracellular storage by binding to latency-associated peptide (LAP). LRRC32 competes with LTBP1 for LAP binding and effectively regulates integrin-dependent TGF-β activation. GARP (S138G) &Latent TGF Beta Complex Protein, Human (HEK293, His-Avi) is a recombinant protein dimer complex containing human-derived GARP, expressed by HEK293 , with C-His, C-Avi labeled tag. GARP (S138G) &Latent TGF Beta Complex Protein, Human (HEK293, His-Avi), has molecular weight of 75-80 kDa.
LRRC32 is a key regulator of TGF-β activation and maintains TGFB1, TGFB2, and TGFB3 in the latent state during extracellular storage by binding to latency-associated peptide (LAP). LRRC32 competes with LTBP1 for LAP binding and effectively regulates integrin-dependent TGF-β activation. GARP (G139N) &Latent TGF Beta Complex Protein, Human (HEK293, His-Avi) is a recombinant protein dimer complex containing human-derived GARP, expressed by HEK293 , with C-Avi, C-His labeled tag. GARP (G139N) &Latent TGF Beta Complex Protein, Human (HEK293, His-Avi), has molecular weight of 75-80 kDa.
The latency-associated peptide (LAP) of the transforming growth factor β-1 (TGF-β-1) proprotein is an important precursor that forms a complex with TGF-β-1. LAP maintains the latent state of TGF-β-1 during storage in the extracellular matrix, ensuring controlled activation. Interactions with “environmental molecules” such as LTBP1, LRRC32/GARP, and LRRC33/NRROS intricately regulate TGF-β-1 activation. LRRC33/NRROS influences the activation of macrophages and microglia, while LRRC32/GARP controls the activation of activated regulatory T cells. Interactions with integrins induce conformational changes in LAP, releasing active TGF-β-1. LAP orchestrates controlled TGF-β-1 activation in different physiological contexts. Recombinant human TGF beta 1/TGFB1 LAP (biotinylated, expressed in HEK293 cells, Avi-tagged) is a biotinylated, Avi-tagged LAP protein expressed in HEK293 cells.
Stathmin proteins critically regulate the microtubule filament system by actively destabilizing microtubules, inhibiting assembly, and promoting disassembly. Phosphorylation of Ser-16 is critical for axon formation during neurogenesis, highlighting its importance in neuronal development. Stathmin Protein, Human (C-His) is the recombinant human-derived Stathmin protein, expressed by E. coli , with C-6*His labeled tag.
Stathmin Protein, a widely distributed cytosolic phosphoprotein, integrates regulatory signals and destabilizes microtubules, crucial for their assembly and disassembly. It exhibits broad expression in various tissues, highlighting its versatile role in cellular processes. Stathmin Protein, Human (His) is the recombinant human-derived Stathmin protein, expressed by E. coli , with N-6*His labeled tag.
The CXCR4 protein functions as a receptor for the CXC chemokine CXCL12/SDF-1, triggering an increase in intracellular calcium ions and activation of MAPK1/MAPK3. It is actively involved in AKT signaling, which is critical for regulating cell migration, especially in wound healing. CXCR4 Protein, Human (GST) is the recombinant human-derived CXCR4 protein, expressed by E. coli , with N-GST labeled tag. The total length of CXCR4 Protein, Human (GST) is 50 a.a., with molecular weight of ~32.6 kDa.
Thymopoietin protein critically directs nuclear lamina assembly and maintains structural organization in the nuclear envelope. It is considered a potential receptor that attaches lamina fibrils to the inner nuclear membrane, where it anchors key structural components. Thymopoietin Protein, Human (His) is the recombinant human-derived Thymopoietin protein, expressed by E. coli , with C-6*His labeled tag. The total length of Thymopoietin Protein, Human (His) is 187 a.a., with molecular weight of ~23.0 kDa.
TGF beta 1/TGFB1 is a polypeptide member of the transforming growth factor beta superfamily of cytokines. TGF beta 1 is a secreted protein that performs many cellular functions, including the control of cell growth, cell proliferation, cell differentiation, apoptosis, and can regulate the expression and activation of other growth factors, including interferon gamma and tumor necrosis factor alpha. Animal-Free TGF beta 1/TGFB1 Protein, Human (His) is the recombinant human-derived animal-FreeTGF beta 1/TGFB1 protein, expressed by E. coli , with C-His labeled tag. The total length of Animal-Free TGF beta 1/TGFB1 Protein, Human (His) is 112 a.a., with molecular weight of ~13.7 kDa.
LRRC32, a key regulator of TGF-beta activation, maintains TGFB1, TGFB2, and TGFB3 in a latent state during extracellular storage by binding to Latency-associated peptide (LAP). Competing with LTBP1 for LAP binding, LRRC32 effectively modulates integrin-dependent TGF-beta activation. Its significance spans the regulation of TGF-beta-1 (TGFB1) on activated Tregs' surface and the control of TGF-beta-3 (TGFB3) during palate development, emphasizing LRRC32's intricate role in fine-tuning TGF-beta signaling. Interactions with TGFB1, TGFB2, TGFB3, and LAPTM4B contribute to its regulatory functions. GARP&Latent TGF Beta 2 Complex Protein, Human (HEK293, His-Avi) is a recombinant protein dimer complex containing human-derived GARP&Latent TGF Beta 2 Complex protein, expressed by HEK293, with C-Avi, C-His labeled tag. GARP&Latent TGF Beta 2 Complex Protein, Human (HEK293, His-Avi), has molecular weight of 72-77 kDa(GARP) & 13 kDa & 46-48 kDa(Latent TGF Beta 2), respectively.
CXCR4-VLP Protein, Human (HEK293, His) is recommended for animal immunization, ELISA. It is not recommended for receptor-ligand interaction detection and SPR/BLI assay since there are other irrelevant membrane proteins of the host on the VLP envelope, and the receptor-ligand interaction will have strong background interference. High requirements for chips and experimental protocols are needed for SPR/BLI assays. If VLP control is required, it is recommended HY-P701236. Tags can only be detected under denaturing conditions.
Heat shock protein HSP 90-alpha; Heat shock 86 kDa (HSP 86; HSP86); Heat shock protein family C member 1; Lipopolysaccharide-associated protein 2 (LAP-2; LPS-associated protein 2); Renal carcinoma antigen NY-REN-38; HSP90A, HSPC1, HSPCA
The HSP90AA1 protein is an important molecular chaperone that coordinates the maturation and regulation of specific target proteins critical for cell cycle control and signal transduction. Its ATPase activity drives a functional cycle that induces conformational changes in client proteins for activation. HSP90AA1 Protein, Human (His, Avi) is the recombinant human-derived HSP90AA1, expressed by E. coli , with C-Avi, C-6*His labeled tag. ,
GARP is a transmembrane protein that acts as a docking receptor for potential transforming growth factor (LTGF-β) and plays a key role in the production and release of active transforming growth factor β (TGF-β). The presence of GARP affects immune-mediated diseases such as cancer, allergies, and autoimmunity. GARP&Latent TGF Beta 1 Complex Protein, Human (Biotinylated, HEK293, His-Avi) is a recombinant protein dimer complex containing rat-derived GARP&Latent TGF Beta 1 Complex protein, expressed by HEK293 , with C-Avi, C-His labeled tag. GARP&Latent TGF Beta 1 Complex Protein, Human (Biotinylated, HEK293, His-Avi), has molecular weight of 70-80 kDa (GARP) & 42-48 kDa & 13 kDa (L, respectively.
GARP is a transmembrane protein that acts as a docking receptor for potential transforming growth factor (LTGF-β) and plays a key role in the production and release of active transforming growth factor β (TGF-β). The presence of GARP affects immune-mediated diseases such as cancer, allergies, and autoimmunity. GARP&Latent TGF Beta 1 Complex Protein, Human (HEK293, His-Avi) is a recombinant protein dimer complex containing rat-derived GARP&Latent TGF Beta 1 Complex protein, expressed by HEK293 , with C-Avi, C-His labeled tag. GARP&Latent TGF Beta 1 Complex Protein, Human (HEK293, His-Avi), has molecular weight of 70-80 kDa (GARP) & 42-48 kDa & 13 kDa (L, respectively.
CEBPB Antibody (YA1835) is a rabbit-derived non-conjugated IgG antibody (Clone NO.: YA1835), targeting CEBPB, with a predicted molecular weight of 36 kDa (observed band size: 36 kDa). CEBPB Antibody (YA1835) can be used for WB, ICC/IF, IP, FC experiment in human, mouse, rat background.
ERAP1 Antibody (YA2159) is a rabbit-derived non-conjugated IgG antibody (Clone NO.: YA2159), targeting ERAP1, with a predicted molecular weight of 107 kDa (observed band size: 107 kDa). ERAP1 Antibody (YA2159) can be used for WB, IHC-P experiment in human, rat background.
LAP3 Human Pre-designed siRNA Set A contains three designed siRNAs for LAP3 gene (Human), as well as a negative control, a positive control, and a FAM-labeled negative control.
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