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- BBB DamageCategories
- Neurotransmitter Antibodies & Receptor Antibodies
- Ionotropic Receptor AntibodiesMetabotropic Receptor AntibodiesNeurotransmitter AntibodiesTransporter AntibodiesSignal Channel Antibodies
- Calcium Channel AntibodiesChloride Channel AntibodiesDense-Core Vesicles AntibodiesNitric Oxide Channel AntibodiesStroke Pathology Antibodies
- Neurogenesis AntibodiesNeuronal Growth & Development AntibodiesNeuronal Growth & Development AntibodiesNeuronal Metabolism AntibodiesSignal Transduction AntibodiesStroke-Related Cell Markers Antibodies
- Glial Cell Marker AntibodiesNeural Stem Cell Marker AntibodiesNeuron Marker AntibodiesSynaptic Marker AntibodiesCell Death and ApoptosisNeuroinflammationNeuronal Damage and RepairOxidative StressVascular Mechanisms
- 3D BBB Models
- Organ-on-a-Chip BBB ModelsTranswell Models3D BBB Models Culture Substrate
- 3D HydrogelsCollagensAnmial BBB ModelsCell Lines for BBB Modeling
- Immortalized CellsPrimary CellsStem Cells
3D Hydrogels
3D hydrogels are three-dimensional cross-linked networks of hydrophilic polymers that can absorb and retain large amounts of water. In recent years, these hydrogels have received widespread attention for their potential applications in tissue engineering, drug delivery, and biomedical research. These cross-linked polymer hydrogels can replicate the extracellular matrix found in nature.
In the context of the blood-brain barrier (BBB), 3D hydrogels can be used to create 3D models of the BBB in vitro. Researchers can recreate the complex structure and physiology of the BBB in a laboratory setting by using 3D hydrogels as a substrate. Additionally, these hydrogels can be functionalized with specific molecules to mimic the biochemical and biophysical properties of the blood-brain barrier. In Transwell models, for example, researchers can culture traditionally immortalized cells embedded in hydrogels to form multicellular complexes called spheroids. Furthermore, stem cells grown in 3D hydrogels can differentiate into multiple cell types that closely resemble native tissues, such as human iPSC-derived brain microvascular endothelial cells, that can be programmed to form 3D organoid BBB models, which are ideal, reproducible, and scalable in vitro models of the BBB.
The advantage of using 3D hydrogels as BBB model substrates is that they provide a more realistic representation of brain tissue compared to traditional 2D cell culture systems. Furthermore, 3D hydrogel models can form multicellular layers and establish cell-cell interactions, which are crucial for studying the barrier function of the BBB.
Naturally Derived 3D Hydrogels Synthetic 3D Hydrogels Biologically derived natural ECM extracts are the most commonly used 3D hydrogels to simulate physiological extracellular matrix in vitro. Currently, ECM extracts of Engelbreth-Holm-Swarm (EHS) murine sarcoma basement membrane have been widely used in 3D cell culture. Synthetic 3D hydrogels are matrices for cell culture achieved through cross-linked polymer networks. Chemically defined hydrogel formulations enhance reproducibility compared to native 3D hydrogels, and the presence and concentration of culture medium components (e.g., growth factors) are known. Ace Therapeutics provides a variety of naturally derived 3D hydrogels and synthetic 3D hydrogel kits to help you construct an ideal, stable 3D BBB model in vitro that meets your research needs.
Cat.# Name Description Price BBM-3C-072 Ready-to-use 3D Hydrogel kit Ready-to-Use 3D Hydrogel Kit is a set of reagents for constructing extracellular matrix components in 3D cell culture, and is similar to a living extracellular matrix. The kits contain reagents for the preparation of hydrogels with a soft stiffness and an RGD peptide concentration of 0.4 mmol/L. You can use these reagents to control the extracellular environment and design 3D systems suitable for cell survival.inquiry BBM-3C-073 3D F-Dextran-PEG Hydrogel Kit 3D Dextran-PEG Hydroge Kit contains the necessary reagents for creating hydrogels that gel fast and are compatible with living cells, which are maleimide functionalized dextran (Mal-Dextran), and PEG-Link, a cross-linking agent. The formation of a gel through the stable bonding of thiol groups on PEG-Link with maleimide groups on the Mal-Dextran, when the two reagents are combined.inquiry BBM-3C-074 3D F-Dextran-CD Hydrogel Kit 3D Dextran-CD Hydrogel Kit contains the necessary reagents for creating hydrogels that gel fast and are compatible with living cells, which are maleimide functionalized dextran (Mal-Dextran), and CD-Link, a cross-linking agent. The formation of a gel through the stable bonding of thiol groups on CD-Link with maleimide groups on the Mal-Dextran, when the two reagents are combined.inquiry BBM-3C-075 3D F-PVA-PEG Hydrogel Kit 3D PVA-PEG Hydrogel Kit contains the necessary reagents for creating hydrogels that gel fast and are compatible with living cells, which are maleimide-functionalized polyvinyl alcohol (Mal-PVA) and PEG-Link, a cross-linking agent. The formation of a gel through the stable bonding of thiol groups on PEG-Link with maleimide groups on Mal-PVA, when the two reagents are combined.inquiry BBM-3C-076 3D F-PVA-CD Hydrogel Kit 3D PVA-CD Hydrogel Kit contains the necessary reagents for creating hydrogels that gel fast and are compatible with living cells, which are maleimide-functionalized polyvinyl alcohol (Mal-PVA) and CD-Link, a cross-linking agent. The formation of a gel through the stable bonding of thiol groups on CD-Link with maleimide groups on Mal-PVA, when the two reagents are combined.inquiry BBM-3C-077 3D S-Dextran-PEG Hydrogel Kit 3D Dextran-PEG Hydroge Kit contains the necessary reagents for creating hydrogels that gel slowly and are compatible with living cells, which are SG-Dextran and PEG-Link, a cross-linking agent. The formation of a gel through the stable bonding of thiol groups on PEG-Link with thiol-reactive groups on SG-Dextran, when the two reagents are combined at physiological pH (pH 7.2).inquiry BBM-3C-078 3D S-Dextran-CD Hydrogel Kit 3D Dextran-CD Hydrogel Kit contains the necessary reagents for creating hydrogels that gel slowly and are compatible with living cells, which are SG-Dextran and CD-Link, a cross-linking agent. The formation of a gel through the stable bonding of thiol groups on CD-Link with thiol-reactive groups on SG-Dextran, when the two reagents are combined at physiological pH (pH 7.2).inquiry BBM-3C-079 3D S-Life PVA-PEG Hydrogel Kit 3D PVA-PEG Hydrogel Kit contains the necessary reagents for creating hydrogels that gel slowly and are compatible with living cells, which are the polymeric SG-PVA and PEG-Link, a cross-linking agent. The formation of a gel through the stable bonding of thiol groups on PEG-Link with thiol-reactive groups on SG-PVA, when the two reagents are combined at physiological pH (pH 7.2).inquiry BBM-3C-080 3D S-Life PVA-CD Hydrogel SG Kit 3D PVA-CD Hydrogel Kit contains the necessary reagents for creating hydrogels that gel slowly and are compatible with living cells, which are polymeric SG-PVA and CD-Link, a cross-linking agent. The formation of a gel through the stable bonding of thiol groups on CD-Link with thiol-reactive groups on SG-PVA, when the two reagents are combined at physiological pH (pH 7.2).inquiry BBM-3C-081 3D Dextran-HA Hydrogel Kit 3D Dextran-HA Hydrogel Kit contains the necessary reagents for creating hydrogels containing hyaluronic acid, which are SG-Dextran and HyLink, a thiol-functionalized hyaluronic acid crosslinker. The formation of a gel through the stable bonding of thiol groups on HyLink with thiol-reactive groups on SG-Dextran, when the two reagents are combined at physiological pH (pH 7.2).inquiry BBM-3C-082 3D PVA-HA Hydrogel Kit 3D PVA-HA Hydrogel Kit contains the necessary reagents for creating hydrogels containing hyaluronic acid, which are SG-PVA and HyLink, a thiol-functionalized hyaluronic acid crosslinker. The formation of a gel through the stable bonding of thiol groups on HyLink with thiol-reactive groups on SG-PVA, when the two reagents are combined at physiological pH (pH 7.2).inquiry BBM-3C-083 3D PEG-Link 3D PEG-Link molecule contains polyethylene glycol that has a thiol at each end. When it is mixed with polymers, such as Mal-PVA, Mal-Dextran, SG-PVA, and SG-Dextran, the thiol groups on PEG-Link create stable thioether bonds with thiol-reactive groups on the polymers, leading to the formation of the hydrogel.inquiry BBM-3C-084 3D CD-Link When the 3D CD-Link molecule, which is made up of a polyethylene glycol-peptide conjugate with thiol groups on both ends, is mixed with polymers Mal-PVA, Mal-Dextran, SG-PVA, and SG-Dextran, the thiol groups on CD-Link react with thiol-reactive groups on the polymers, forming stable thioether bonds, thus leading to the creation of the hydrogel.inquiry BBM-3C-085 3D HyLink 3D HyLink molecule consists of hyaluronic acid carrying thiol groups along its backbone. When combined with polymers SG-PVA and SG-Dextran, thiol groups on HyLink form stable thioether bonds with the thiol-reactive groups on the polymers, which results in the formation of the hydrogel.inquiry BBM-3C-086 3D SG-Dextran 3D SG-Dextran consists of dextran functionalized with thiol-reactive groups (SG-Dextran), which can be used together with other components PEG-Link or CD-Link to set up cell-compatible hydrogels.inquiry All of our products are intended for preclinical research use only and cannot be used to diagnose, treat or manage patients.
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