Catalog No.
Product Name
Application
Product Information
Citations
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A2 Agonist
CI-936 is an orally active A2 adenosine receptor agonist exhibiting an affinity of 25 nM. This compound demonstrates significant and selective activities in preclinical models associated with antipsychotic efficacy. Notably, CI-936 effectively inhibits exploratory behavior in mice, making it a valuable tool for understanding the neuropharmacological pathways linked to psychotropic effects. -
Adenosine Analog
N6-Benzoyl-7'-O-DMT-morpholino adenine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits notable biological activities, including smooth muscle vasodilation and the potential inhibition of cancer progression. It is commonly utilized in research applications related to cardiovascular studies and cancer therapeutics, contributing valuable insights into adenosine signaling and its effects on physiological processes. -
Adenosine Analog
2-Cyanomethylthioadenosine is an adenosine analog that primarily targets adenosine receptors. This compound demonstrates potent vasodilatory effects on smooth muscle tissue and has shown potential in inhibiting cancer progression. It serves as a valuable tool in research applications focusing on vascular biology and cancer therapeutics. -
Adenosine Analog
3’-β-C-Ethynyladenosine is an adenosine analog that primarily targets adenosine receptors. It exhibits smooth muscle vasodilatory effects and has been implicated in the inhibition of cancer progression. Additionally, this compound serves as a click chemistry reagent, featuring an alkyne group that allows it to undergo copper-catalyzed azide-alkyne cycloaddition (CuAAc) with azide-containing molecules, facilitating bioconjugation applications in chemical biology and drug development. -
Adenosine Analog
7'-O-DMT-morpholino thymine is an adenosine analog primarily known for its role in modulating adenosine receptors. It exhibits biological activities such as smooth muscle vasodilation and may play a role in inhibiting cancer progression. This compound is valuable for research applications in cardiovascular studies and cancer biology, providing insights into cellular signaling pathways and therapeutic strategies. -
Adenosine Analog
N6,N6-Dimethyl-2’-β-C-methyladenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits significant vasodilatory effects on smooth muscle and has been implicated in inhibiting cancer progression. It serves as a valuable tool for research in cardiovascular studies and cancer biology, providing insights into the modulation of adenosine signaling pathways. -
Adenosine Analog
N6-(3-Methoxybenzyl)-2’-C-methyl adenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits significant biological activity as a smooth muscle vasodilator and demonstrates potential anti-cancer properties. It is suitable for research applications focused on vascular biology and cancer therapeutics. -
Adenosine Analog
N6-Methyl-2’-β-C-methyladenosine is an adenosine analog that primarily targets adenosine receptors. This compound has demonstrated vasodilatory effects on smooth muscle and exhibits potential in inhibiting cancer progression. Its unique structure allows for various research applications related to adenosine signaling pathways and therapeutic interventions. -
Adenosine Analog
5’-O-(4,4’-Dimethoxytrityl)-N6-phenoxyacetyl adenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits significant smooth muscle vasodilatory effects and has been implicated in the inhibition of cancer progression. It is a valuable reagent for research focused on vascular biology, immunology, and oncology, facilitating investigations into the therapeutic potential of nucleotide derivatives. -
Adenosine Analog
5'-O-[Bis(4-methoxyphenyl)phenylmethyl]-adenosine is an adenosine analog that primarily acts as a smooth muscle vasodilator. This compound has demonstrated potential in inhibiting cancer progression, making it valuable for cancer research. It serves as a useful tool in studies focused on adenosine receptor modulation and vascular biology. -
Adenosine Analog
3’-O-Propargyladenosine is an adenosine analog that primarily targets adenosine receptors, acting as a vasodilator and exhibiting potential anti-cancer properties. It serves as a valuable tool in research applications involving click chemistry, due to its alkyne functional group, which facilitates copper-catalyzed azide-alkyne cycloaddition (CuAAc) with azide-containing molecules. This compound is instrumental in the study of biochemical pathways and therapeutic interventions related to adenosine signaling and vascular biology. -
Adenosine Analog
N6-Bz-5'-O-DMTr-3'-deoxyadenosine-2'-O-CED-phosphoramidite is an adenosine analog that primarily targets adenosine receptors. It exhibits biological activities such as smooth muscle relaxation and has demonstrated potential in inhibiting cancer progression. This compound is useful in various research applications, particularly in the development of nucleic acid-based therapeutics and the study of adenosine receptor signaling pathways. -
Adenosine Analog
5’-O-(4,4’-Dimethoxytrityl)-2’-beta-C-methyl adenosine is an adenosine analog that primarily acts as a smooth muscle vasodilator. This compound exhibits significant biological activities, including the inhibition of cancer progression. It serves as a valuable tool in research applications related to cardiovascular research, cancer therapies, and the study of adenosine receptor signaling pathways. -
Adenosine Analog
N6-Benzoyl-2'-O-tert-butyldimethylsilyl-3'-O-DMT-adenosine is an adenosine analog that primarily targets adenosine receptors. It exhibits significant smooth muscle vasodilatory effects and has demonstrated potential in inhibiting cancer progression. This compound is valuable for research applications focusing on vascular biology, oncology, and the investigation of adenosine signaling pathways. -
Adenosine Analog
N-[[4-(Trifluoromethyl)phenyl]methyl]adenosine is an adenosine analog known for its smooth muscle vasodilatory effects. This compound has demonstrated potential in inhibiting cancer progression, making it valuable for research in oncology and cardiovascular studies. Its biological activity positions it as a key reagent for investigating adenosine receptor pathways and their implications in various therapeutic contexts. -
Adenosine Analog
8-Benzyloxyadenosine is an adenosine analog that primarily targets adenosine receptors to elicit biological responses. This compound exhibits significant smooth muscle vasodilatory effects and has demonstrated potential in inhibiting cancer progression. It serves as a valuable tool for research in cardiovascular biology and cancer therapeutics. -
Adenosine Analog
5-Methyl-4’-thiouridine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits significant vasodilatory effects, promoting smooth muscle relaxation, and has shown potential in inhibiting cancer progression. Its applications in research encompass studies on cardiovascular function and cancer therapeutics. -
Adenosine Analog
8-Bromo-5’-O-(4-cyanobenzyl)-2’,3’-di-O-isopropylidene adenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits smooth muscle vasodilatory activity and has potential applications in cancer research due to its ability to inhibit cancer progression. Its structural modifications make it a valuable tool for studying adenosine signaling pathways in various biological systems. -
Adenosine Analog
2'-O-t-Butyldimethylsilyladenosine is an adenosine analog that primarily targets adenosine receptors. This compound functions as a smooth muscle vasodilator and has demonstrated potential in inhibiting cancer progression. It is valuable for research applications in vascular biology and oncology, contributing to studies on therapeutic pathways involving adenosine signaling. -
Adenosine Analog
2-Benzylthioadenosine is an adenosine analog that primarily acts on adenosine receptors. It is known for its vasodilatory effects on smooth muscle and has been investigated for its potential to inhibit cancer progression. This compound is valuable in research applications related to cardiovascular health and oncology, contributing to the understanding of adenosine signaling pathways. -
Biochemical Assay Reagent
Adenosine 2'-PEG-Biotin is a biochemical assay reagent that acts as a bioisostere of endogenous adenosine, allowing it to engage adenosine receptors effectively. This compound plays a crucial role in regulating various cell signaling pathways, facilitating research into its applications as a bioprobe, biosensor, or diagnostic reagent. Its incorporation of biotin also enhances its utility in various biochemical assays and detection methodologies. -
Adenosine Analog
N6-Benzoyl-2',3'-isopropylidene adenosine is an adenosine analog targeting adenosine receptors. This compound exhibits significant smooth muscle vasodilatory activity and has demonstrated potential in inhibiting cancer progression. Its applications in research include studying vascular physiology and cancer biology, making it a valuable tool in the investigation of therapeutic strategies involving adenosine modulation. -
Adenosine Analog
2'-O-Acetyl-3,5-bis-O-(2,4-dichlorobenzyl)adenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits significant smooth muscle vasodilatory activity and has potential applications in inhibiting cancer progression. Its mechanism of action makes it a valuable tool for researchers studying cardiovascular function and cancer therapeutics. -
Adenosine Analog
5′-O-[(4-Cyanophenyl)methyl]-2′,3′-O-(1-methylethylidene)adenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits vasodilatory properties and demonstrates potential in inhibiting cancer cell proliferation. It is a valuable tool in research exploring the effects of adenosine signaling in cardiovascular diseases and cancer therapy. -
Adenosine Analog
N4-Benzoyl-5'-O-DMT-2'-O-propargyl adenosine is an adenosine analog that acts primarily as a smooth muscle vasodilator. This compound has demonstrated potential in inhibiting cancer progression, making it valuable for various biological research applications. Its distinctive structural properties facilitate the study of adenosine receptor interactions and signaling pathways, contributing to the understanding of cardiovascular physiology and tumor biology. -
Adenosine Analog
N6-Benzyl-2’-C-methyladenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits vasodilatory effects in smooth muscle and demonstrates potential in inhibiting cancer progression. It serves as a valuable tool in studies focusing on cardiovascular function and cancer biology, facilitating research into therapeutic strategies for related conditions. -
Adenosine Analog
N-[(3-Methoxyphenyl)methyl]adenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits significant biological activity as a smooth muscle vasodilator and has demonstrated potential in inhibiting cancer progression. It is a valuable tool for researchers investigating vascular biology and cancer therapeutics. -
Uridine Analog
5-Iodo-2’-β-C-methyl uridine is a uridine analog that primarily targets adenosine receptors. This compound exhibits potential antiepileptic properties and serves as a valuable tool in the investigation of anticonvulsant and anxiolytic activities. Additionally, it may contribute to the development of innovative antihypertensive agents in chemical research. -
Adenosine Analog
5’-O-(4,4’-Dimethoxytrityl)-2’-O-(2-methoxyethyl) adenosine is an adenosine analog that primarily targets adenosine receptors. This compound demonstrates biological activities such as smooth muscle vasodilation and potential inhibition of cancer progression. It is valuable for research in cardiovascular studies and cancer biology, facilitating investigations into adenosine signaling and therapeutic applications. -
Adenosine Analog
N6-Methyl-xylo-adenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits smooth muscle vasodilatory effects and has demonstrated potential in inhibiting cancer progression. Its unique properties make it a valuable tool for researchers investigating vascular biology and cancer therapies. -
5'-AMP Analogue
2-Cl-5'-AMP is a 5'-AMP analogue that functions primarily by interacting with adenosine receptors. This compound exhibits key biological activity in receptor mapping research, facilitating the study of adenosine receptor signaling pathways and their physiological roles. Its use in biochemical assays enables a deeper understanding of receptor-ligand interactions and their implications in various biological systems. -
Adenosine Analog
N-Benzoyl-5'-O-dmtr-2'-O-(2-methoxyethyl)-adenosine is an adenosine analog that primarily targets adenosine receptors. It exhibits significant vasodilatory effects by relaxing smooth muscle and has demonstrated potential in inhibiting cancer progression. This compound is valuable in biomedical research, particularly in studies focused on cardiovascular health and cancer therapy. -
Adenosine Analog
9-(β-D-Xylofuranosyl)adenine is an adenosine analog that primarily acts as a vasodilator by targeting adenosine receptors. This compound has demonstrated significant biological activity, including the inhibition of cancer progression. It is particularly useful for researchers exploring the mechanisms of vasodilation and the therapeutic potential of adenosine-related pathways in cancer biology. -
Adenosine Analog
2'-O-Methyladenosine 5'-monophosphate triethylammonium is an adenosine analog that primarily targets adenosine receptors. It exhibits significant biological activity, functioning as a smooth muscle vasodilator while also demonstrating potential for inhibiting cancer progression. This compound is valuable for research applications focusing on cardiovascular studies and cancer biology. -
Adenosine Analog
8-Chloro-2'-deoxyadenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits significant biological activity as a potential vasodilator and has demonstrated inhibitory effects on cancer progression. It is useful in various research applications, particularly in studying the pharmacological effects of adenosine and its derivatives in cardiovascular and oncology research. -
Adenosine Analog
2-Methoxy-2'-deoxyadenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits vasodilatory effects on smooth muscle and has demonstrated potential in inhibiting cancer progression, making it relevant for various research applications, including cardiovascular studies and oncology. Its structural similarity to adenosine allows for exploration in drug development targeting related pathways. -
Adenosine Analog
N-(2-Phenoxyacetyl)adenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits smooth muscle vasodilatory effects and has demonstrated potential in inhibiting cancer progression. It serves as a valuable tool in cancer research and studies related to vascular biology. -
Adenosine Analog
N6-Benzoyl-9-β-D-arabinofuranosyladenine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits smooth muscle vasodilatory effects and demonstrates potential in inhibiting cancer progression. It serves as a valuable tool in studies focused on cardiovascular research and oncology, enabling researchers to explore the therapeutic implications of adenosine signaling pathways. -
Adenosine Analog
8-Allylthioadenosine is an adenosine analog that primarily targets adenosine receptors. It demonstrates smooth muscle vasodilatory effects and has been implicated in inhibiting cancer progression, making it a valuable compound for oncology research. Its utility extends to studies involving vascular biology and the modulation of cellular signaling pathways. -
Adenosine Analog
3’-O-(2-Methoxyethyl)-2-aminoadenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits significant smooth muscle vasodilatory properties and has demonstrated potential in inhibiting cancer progression. Research applications include studying vascular biology, exploring therapeutic avenues in oncology, and investigating the signaling pathways mediated by adenosine receptors. -
Adenosine Analog
3',5'-TIPS-N-Ac-Adenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits significant smooth muscle vasodilatory activity and has potential applications in inhibiting cancer progression. It is valuable for research related to vascular biology and oncology, facilitating the study of adenosine receptor signaling pathways and their therapeutic implications. -
Adenosine Analog
8-(Methylamino)adenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits significant vasodilatory effects on smooth muscle and has been demonstrated to possess anti-cancer properties by inhibiting tumor progression. It is utilized in various research applications related to vascular biology and oncology. -
Adenosine Analog
N6-(3-Trifluoromethylbenzyl)-2’-C-methyl adenosine is an adenosine analog that primarily acts on adenosine receptors. This compound demonstrates smooth muscle vasodilatory properties and has potential applications in inhibiting cancer progression. Its structural modifications enhance its affinity and selectivity, making it a valuable reagent for research in vascular biology and oncology. -
Adenosine Analog
N6,N6-Dimethyl-xylo-adenosine is an adenosine analog with a primary mechanism of action involving modulation of adenosine receptors. This compound has demonstrated significant smooth muscle vasodilator activity and holds potential in inhibiting cancer progression. It is widely utilized in research applications focusing on vascular biology and oncology. -
Adenosine Analog
3'-β-C-Methyladenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits biological activity as a smooth muscle vasodilator and has demonstrated potential in inhibiting cancer progression. It is useful in research applications focused on cardiovascular function and cancer biology. -
Adenosine Analog
9-(2-Deoxy-β-D-threo-pentofuranosyl)-9H-purin-6-amine is an adenosine analog that primarily acts on adenosine receptors. This compound exhibits smooth muscle vasodilatory activity and has demonstrated potential in inhibiting the progression of various cancers. It serves as a valuable tool in biochemical research focusing on vascular biology and oncology. -
Adenosine Analog
2-Amino-2′-O-(2-methoxy-2-oxoethyl)adenosine is an adenosine analogue targeting adenosine receptors. It exhibits smooth muscle vasodilatory effects and has demonstrated potential in inhibiting cancer progression. This compound is valuable for research applications focusing on vascular biology and cancer therapeutics. -
Adenosine Analog
2′-β-C-Methyl-2-methoxyadenosine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits vasodilatory effects on smooth muscle and has demonstrated potential in inhibiting cancer progression. Its applications extend to research involving cardiovascular function and cancer biology, making it a valuable tool for exploring therapeutic strategies in these areas. -
Adenosine Analog
N6-Benzoyl-2'-fluoro-2'-deoxyarabinoadenosine is an adenosine analog that primarily targets adenosine receptors. It exhibits significant vasodilatory effects on smooth muscle and has demonstrated potential in inhibiting cancer progression. This compound is valuable in research focused on vascular biology and cancer therapeutics, offering insights into adenosine receptor signaling pathways and their clinical implications. -
Adenosine Analog
2-Amino-6-chloro-9-[(2,3,5-tri-O-benzoyl-2-C-Methyl-beta-D-ribofuranosyl)]-9H-purine is an adenosine analog that primarily targets adenosine receptors. This compound exhibits biological activities such as promoting smooth muscle vasodilation and potentially inhibiting cancer progression. It is a valuable reagent for researchers investigating vascular biology, cancer therapeutics, and adenosine signaling pathways.
