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Email:sales@ruixibiotech.com
Tel.:02988811435
| Catalog | name | Description | price |
|---|---|---|---|
| R-Mcs-109 | DOPS (100%) Liposomes Containing Self-quenching Concentration of Octadecyl Rhodamine B | DOPS (100%) Liposomes Containing Self-quenching Concentration of Octadecyl Rhodamine B use the self-quenching behavior to study lipid mixing, membrane fusion, or interactions with proteins or drugs in vitro and in live cell assays. Investigate how the incorporation of anionic lipids like DOPS affects bilayer properties, such as fluidity and phase transitions. Assess the capacity of DOPS liposomes for encapsulating and delivering therapeutic agents, with the potential use of R18 as a marker for membrane integrity or release. Leverage changes in fluorescence due to dye self-quenching for biosensing applications, where environmental changes affect membrane integrity or interactions. | price> |
| R-Mcs-110 | DOPC (100%) Liposomes Containing Self-quenching Concentration of Octadecyl Rhodamine B | DOPC (100%) Liposomes Containing Self-quenching Concentration of Octadecyl Rhodamine B can be used to visualize cell interactions and membrane dynamics under a fluorescence microscope. Investigate the capacity of DOPC liposomes for encapsulating therapeutic agents and track the real-time release and stability through fluorescence lifetime measurements. Assess how environmental conditions affect lipid bilayer properties, permeability, and interactions with proteins or drugs. Utilize changes in fluorescence due to self-quenching for operational biosensing environments where membrane integrity is critical. | price> |
| R-Mcs-111 | POPE:POPS:POPC (5:5:2 molar ratio)Liposomes Containing Octadecyl Rhodamine B | POPE:POPS:POPC (5:5:2 molar ratio)Liposomes Containing Self-quenching Concentration of Octadecyl Rhodamine B can explore the dynamics of lipid behavior in biological membranes.And Investigate cellular uptake and distribution of liposomes.Assess the encapsulation efficiency and release kinetics of therapeutic agents from these liposomes.Examine the effects of various conditions (pH, temperature, ionic strength) on membrane permeability and integrity. | price> |
| R-Mcs-112 | DOTAP (100%) Liposomes Co-encapsulating NBD/Rhodamine | DOTAP (100%) Liposomes Co-encapsulating NBD/Rhodamine can assess co-localization or distribution of encapsulated NBD and Rhodamine in cellular models or in vitro assays.Utilize DOTAP liposomes for targeting negatively charged molecules (like DNA or RNA) in gene delivery studies.Employ the fluorescence properties of the encapsulated dyes for sensing applications. | price> |
| R-Mcs-113 | DOTAP:Chol (1:1 molar ratio)Liposomes Co-encapsulating NBD/Rhodamine | DOTAP:Chol (1:1 molar ratio)Liposomes Co-encapsulating NBD/Rhodamine use the fluorescence emitted by the NBD and Rhodamine for imaging studies in live or fixed cells.Investigate the efficacy of the co-encapsulated compounds in pharmaceutical applications, potentially including gene therapy strategies.Explore how these liposomes interact with cell membranes or model lipid bilayers, utilizing the fluorescent properties of the encapsulated dyes.Employ the fluorescence characteristics for biosensing applications or multiplexing assays using the two dyes. | price> |
| R-Mcs-114 | DOTAP:DOPE (1:1 molar ratio) Liposomes Co-encapsulating NBD/Rhodamine | DOTAP:DOPE (1:1 molar ratio) Liposomes Co-encapsulating NBD/Rhodamine utilize the fluorescence for imaging live or fixed cells.Explore the efficacy of co-encapsulated compounds in pharmacological studies.Use the dyes for multiplexed fluorescence assays.Investigate interactions with cell membranes or lipid bilayers. | price> |
| R-Mcs-115 | POPE:POPG (3:1 molar ratio) Liposomes Co-encapsulating NBD/Rhodamine | POPE:POPG (3:1 molar ratio) Liposomes Co-encapsulating NBD/Rhodamine can be used for drug delivery, fluorescence labeling and tracking, and bioimaging. | price> |
| R-Mcs-116 | POPC:Chol:POPG (10:4:1 molar ratio) Liposomes Co-encapsulating NBD/Rhodamine | POPC: Chol: POPG (10:4:1 molar ratio) Liposomes Co encapsulating NBD/Rhodamine can be used for drug delivery, biosensing, cell imaging, and gene delivery research. The liposomes can be utilized for encapsulating both hydrophobic and hydrophilic pharmaceutical agents, improving bioavailability and targeting delivery systems.Utilizing the fluorescence characteristics of NBD and Rhodamine to create biosensors that can report cellular actions or molecular interactions based on changes in fluorescence.These liposomes can be employed for cell tracking in biological studies, allowing for localized imaging of cellular processes in live cells or tissues due to the distinct fluorescence properties generated by the co-encapsulated dyes.Investigating the ability of these liposomes to encapsulate nucleic acids (like DNA or RNA) and to transfect cells, utilizing the anionic POPG for electrostatic interaction with positively charged nucleic acids. | price> |
| R-Mcs-117 | DOPC:DOPG Liposomes Co-encapsulating NBD/Rhodamine | DOPC:DOPG Liposomes Co-encapsulating NBD/Rhodamine can be used for drug delivery, biosensing, cell imaging, and gene delivery research. DOPC:DOPG Liposomes Co-encapsulating NBD/Rhodamine can be used as carriers for both small molecules or larger therapeutic agents, offering a dual-fluorescent labeling system for tracking delivery and cellular uptake.NBD and Rhodamine can facilitate cellular tracking and visualization, allowing researchers to study cellular processes, such as membrane fusion and endocytosis dynamics, in real-time.The fluorescent properties of NBD and Rhodamine allow for the development of biosensors, which can detect specific cellular interactions or changes in the local environment.The positively charged liposomes can be utilized for gene delivery systems, aiding in the transfection of nucleic acids into cells with enhanced efficiency. | price> |
| R-Mcs-118 | DOPG (100%)Liposomes Co-encapsulating NBD/Rhodamine | DOPG (100%) Liposomes Co encapsulating NBD/Rhodamine can be used for drug and gene delivery, cell imaging, biosensing, and therapeutic nanocarriers. The negative charge may enhance binding to positively charged proteins or allow for targeting certain cell types, especially those with positive surface charges. The co-encapsulation of NBD and Rhodamine allows for dual fluorescent labeling, facilitating studies of membrane dynamics, trafficking pathways, and cellular uptake. By incorporating specific targeting moieties, these liposomes can function as biosensors, visualizing interactions through fluorescence changes upon encountering specific cellular markers. DOPG liposomes can be utilized to encapsulate therapeutics, allowing for controlled release and targeted therapy. The fluorescent markers can aid in tracking the delivery and release of such therapeutics. | price> |
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Add: Room 20F 2002, Meiyuan Building, Yanta District, Xi’ an City, Shaanxi Province 710061 China
Tel: 02988811435
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Email: sales@ruixibiotech.com
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