Catalog No.
Product Name
Application
Product Information
Citations
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Stable Isotope
Eicosapentaenoic acid ethyl ester-d5 is a deuterium-labeled derivative of eicosapentaenoic acid ethyl ester, an omega-3 fatty acid. This stable isotope is utilized in biochemical research for various applications, including metabolic studies and tracer analyses in lipid metabolism. Its unique labeling enables precise detection and quantification in biological samples, aiding in the understanding of omega-3 fatty acids' role in cellular processes and health outcomes. -
Stable Isotope
Ethylene Glycol-d6 is a stable isotope-labeled form of ethylene glycol, where hydrogen atoms are replaced by deuterium. This compound is commonly used as an internal standard in nuclear magnetic resonance (NMR) spectroscopy and mass spectrometry to enhance the accuracy of quantitative analysis. Its applications extend to metabolic studies and tracking of chemical pathways, making it a valuable reagent in chemical research and analytical chemistry. -
Stable Isotope
L-Histidine-15N3 is a stable isotope-labeled form of the essential amino acid L-Histidine, which plays a critical role in protein synthesis and is vital for growth in infants. It serves as an important precursor for the synthesis of histamine and other biologically active compounds. L-Histidine-15N3 is useful in metabolic studies and tracer experiments, providing insights into amino acid metabolism and mitochondrial function by inhibiting glutamine transport in mitochondria. -
Stable Isotope
1-Aminopropan-2-ol-d6 is a stable isotope-labeled form of 1-Aminopropan-2-ol, also known as Monoisopropanolamine-d6. This compound plays a crucial role in studying microbial metabolism involving amino alcohol metabolism through intermediates such as propionaldehyde and acetaldehyde in certain Pseudomonas species. It is widely applicable in metabolic tracing experiments and can enhance the understanding of metabolic pathways in microbial systems. -
Stable Isotope
Uracil-d1-1 is a deuterated form of uracil, a naturally occurring pyrimidine derivative and an essential nucleobase in RNA nucleotide structure. This stable isotope allows for enhanced tracing in metabolic studies and offers valuable insight in RNA dynamics. Its applications include nucleic acid research, RNA tracking, and exploring the biochemical pathways involving pyrimidine metabolism. -
Stable Isotope
NSC 16590-d6 is a deuterium-labeled analog of NSC 16590, targeting the inhibition of endogenous ethylene production. This stable isotope is particularly useful in studies involving the physiological effects of ethylene on plant growth and development, specifically in the cotyledonary segments of cocklebur. Researchers can utilize NSC 16590-d6 for mechanistic studies and to trace metabolic pathways in plant biology. -
Stable Isotope
O-Toluic acid-d7 is a deuterium-labeled derivative of o-Toluic acid, also known as 2-Methylbenzoic acid. This compound serves as a stable isotope for various analytical applications, including environmental and metabolic studies. O-Toluic acid-d7 is valuable in mass spectrometry and tracer studies, helping to elucidate metabolic pathways and the behavior of xenobiotic compounds in biological systems. -
Stable Isotope
D-Sorbitol-d2 is a stable isotope-labeled form of D-Sorbitol, a six-carbon sugar alcohol. It serves as a valuable tool in metabolic studies and tracer experiments due to its deuterium labeling, which allows for precise tracking in biological systems. D-Sorbitol-d2 is utilized in research applications that explore sugar metabolism, nutritional studies, and the development of pharmaceuticals, acting as an excipient or stabilizing agent in various formulations. -
Stable Isotope
2'-Deoxyadenosine-5'-monophosphate-13C10,15N5 dilithium is a stable isotope-labeled derivative of 2'-Deoxyadenosine-5'-monophosphate. This nucleic acid component plays a crucial role as a deoxyribonucleotide in DNA synthesis. It is instrumental in investigating adenosine-based interactions, facilitating research into DNA replication and repair mechanisms under various biochemical conditions. -
Stable Isotope
5-Methyluridine-1′-13C is a stable isotope-labeled form of 5-Methyluridine, an endogenous methylated nucleoside present in human flu. This reagent serves as a valuable tool for metabolic tracing and biological studies, enabling researchers to investigate nucleoside metabolism and its implications in various physiological processes. Its incorporation into experimental setups enhances the understanding of RNA biology and cellular function related to nucleoside methylation. -
Stable Isotope
L-(-)-Sorbose-13C is a stable isotope variant of the naturally occurring sugar alcohol, L-(-)-Sorbose. As an endogenous metabolite, it serves as a valuable tool for metabolic studies, allowing researchers to trace metabolic pathways and quantify metabolic flux in biological systems. This stable isotope-labeled compound is ideal for applications in nutritional biochemistry, metabolic research, and isotope tracing techniques. -
Stable Isotope
D-Mannose-13C-2 is a carbon-13 labeled version of D-Mannose, a simple sugar involved in critical metabolic pathways, particularly glycosylation processes. This stable isotope is valuable for metabolic studies, enabling researchers to trace carbohydrate metabolism and the dynamics of glycoprotein synthesis. D-Mannose-13C-2 can be utilized in metabolic flux analysis and isotopic labeling experiments to investigate carbohydrate utilization in various biological systems. -
Stable Isotope
Vanillin-13C,d3 is a stable isotope-labeled compound of Vanillin, incorporating three deuterium atoms and one carbon-13 atom. Vanillin, a naturally occurring compound derived from vanilla beans, is commonly used as a flavoring and fragrance agent in the food, cosmetic, and pharmaceutical industries. This isotopically labeled variant is valuable for analytical applications, such as tracing metabolic pathways and quantifying Vanillin in complex matrices. -
Stable Isotope
D-Tagatose-13C-1 is a stable isotope-labeled form of D-Tagatose, a naturally occurring rare monosaccharide known for its prebiotic properties. This compound serves as a sucrose substitute and a low-calorie sweetener, widely utilized in food applications including chewing gum and fruit juices. Its isotopic labeling facilitates advanced metabolic studies and research in carbohydrate metabolism, making it an essential tool for researchers investigating the physiological effects of sugars on human health. -
Stable Isotope
2-Naphthol-d8 is a stable isotope-labeled derivative of 2-Naphthol, serving as a valuable internal standard for analytical applications. This compound is formed through the metabolic conversion of naphthalene via cytochrome P450 (CYP) isozymes, including CYP 1A1, CYP 1A2, CYP 2A1, CYP 2E1, and CYP 2F2. Its precise isotopic composition enhances the accuracy of quantitative analyses in pharmacokinetic and toxicological studies, making it essential for research involving polycyclic aromatic hydrocarbons. -
Stable Isotope
Arachidic acid-d4-1 is a deuterium-labeled derivative of arachidic acid, a long-chain saturated fatty acid. This stable isotope is utilized in metabolic studies to trace fatty acid metabolism and distribution within biological systems. Its applications extend to cancer research, particularly in the development of drug delivery systems when conjugated with chitosan oligosaccharides. -
Stable Isotope
D-Glucose-13C3-1 is a stable isotope-labeled form of D-Glucose, a key monosaccharide in biological systems. This labeled compound is crucial for studies involving carbohydrate metabolism, providing insights into cellular metabolic pathways and signaling mechanisms. D-Glucose plays a vital role in energy production and responses to environmental stress, making it an essential reagent for metabolic research and applications in biochemical assays. -
Stable Isotope
DL-Alanine-13C-1 is a stable isotope-labeled form of the amino acid DL-alanine, which is composed of equal parts L- and D-alanine. This compound functions as both a reducing agent and a capping agent in nanoparticle synthesis, particularly in combination with silver nitrate. Additionally, DL-alanine-13C-1 is valuable for studying metal ion chelation and plays a significant role in the glucose-alanine cycle, providing insights into amino acid metabolism and tissue interactions. Its applications extend to metabolic research and biochemical analysis. -
Stable Isotope
1-Hexadecanol-d33 is a deuterated form of 1-Hexadecanol, a fatty alcohol characterized by its lipophilicity. This stable isotope is valuable for studies involving metabolic pathways, lipid metabolism, and environmental tracing. It serves as a key reagent in research applications such as mass spectrometry and isotope labeling studies, enabling precise tracking of biological processes involving fatty alcohols. -
Stable Isotope
D-Lyxose-d is a deuterated form of D-Lyxose, an endogenous pentose sugar. This stable isotope serves as a valuable precursor in drug synthesis, particularly in the development of anti-tumor agents and L-nucleoside analogs for antiviral therapies. Its unique structural properties make it a key intermediate in the synthesis of other rare sugars, including L-ribose, facilitating research in glycoscience and medicinal chemistry applications. -
Stable Isotope
3-Methylcrotonylglycine-d2 is a deuterium-labeled derivative of 3-Methylcrotonylglycine, an acyl glycine that serves as a metabolite typically found in urine. This stable isotope is valuable for metabolic studies and can be utilized in isotopic labeling experiments to trace metabolic pathways in biological systems. Its application extends to research on amino acid metabolism and biochemical processes involving acyl glycine derivatives. -
Stable Isotope
2'-Deoxyuridine-2′-13C is a stable isotope-labeled form of 2'-Deoxyuridine, serving as an important precursor in nucleic acid metabolism and research. It is utilized to study chromosomal integrity, as it can induce chromosome breakage and decrease thymidylate synthetase activity. This compound is valuable in metabolic tracing studies and the synthesis of nucleotide analogs, aiding in the investigation of cellular processes and the development of therapeutic agents. -
Stable Isotope
Zymosterol-d5 is a deuterium-labeled derivative of zymosterol, serving as a stable isotope used in various biochemical applications. This reagent is valuable for studies involving cholesterol biosynthesis and sterol metabolism. Its unique labeling facilitates tracking and quantification in metabolic experiments, making it suitable for tracer studies in lipid biochemistry and related research fields. -
Stable Isotope
1-Dodecanol-d26 is a deuterium-labeled form of 1-Dodecanol, primarily utilized as a stable isotope. This compound serves as an endogenous metabolite, playing a significant role in lipid metabolism and related biological processes. Its isotopic labeling makes it valuable in quantitative studies of metabolic pathways and tracing experiments in biochemical research. -
Stable Isotope
D-Glucose-1,6-13C2 is a stable isotope labeled form of D-Glucose, which is a vital monosaccharide and a key player in cellular metabolism. This compound serves as a substrate for various metabolic pathways and provides insights into metabolic processes through isotopic tracing. D-Glucose-1,6-13C2 is extensively used in research applications, including metabolic flux analysis, studying cellular responses to stress, and investigating glucose metabolism in various biological systems. -
Stable Isotope
Pentadecanoic acid-d3 is a deuterium-labeled derivative of pentadecanoic acid, a saturated fatty acid characterized by a 15-carbon chain. This stable isotope is utilized in metabolic studies and tracer experiments, allowing for the investigation of fatty acid metabolism and other biochemical pathways. Its incorporation into research applications can enhance the understanding of lipid metabolism and related physiological processes. -
Stable Isotope
1-Palmitoyl-sn-glycero-3-phosphocholine-d9 is a deuterium-labeled analogue of 1-Palmitoyl-sn-glycero-3-phosphocholine, a prevalent lysophosphatidylcholine in biological systems. This compound exhibits pro-inflammatory properties and serves as a valuable tool in investigations related to atherosclerosis. Its stable isotope labeling allows for detailed metabolic studies and the assessment of lipid dynamics in various biological contexts. -
Stable Isotope
Cholesteryl oleate-d7-1 is a deuterated form of cholesteryl oleate, an ester derived from cholesterol and oleic acid. This stable isotope is utilized in lipid transport and storage studies, and it plays a crucial role in cell membrane formation. Additionally, cholesteryl oleate has potential as a biomarker for prostate cancer and can be employed in the preparation of cationic solid lipid nanoparticles for effective gene silencing applications in research. -
Stable Isotope
Pyruvic aldehyde-13C3 is a stable isotope-labeled compound that serves as a valuable tool in chemical research. As a key intermediate in various metabolic pathways, it is frequently utilized in organic synthesis and analytical studies. This reagent is particularly useful in tracing metabolic processes and studying flavor compounds as well as applications in the tanning industry. -
Stable Isotope
Sodium 3-methyl-2-oxobutanoate-13C,d4-1 is a stable isotope-labeled derivative of Sodium 3-methyl-2-oxobutanoate, incorporating deuterium and carbon-13 isotopes. This compound serves as a pivotal precursor in the biosynthesis of pantothenic acid in Escherichia coli, facilitating studies of metabolic pathways. Its isotopic labeling offers unique advantages for tracing and quantifying metabolic processes in various biological research applications. -
Stable Isotope
Xylose-5-13C is a stable isotope-labeled form of xylose, specifically enriched with carbon-13. This reagent is utilized in metabolic studies and tracer experiments to investigate carbohydrate metabolism and absorption. Xylose-5-13C serves as an important tool for researchers examining glycan biosynthesis and the role of sugars in various biological processes. -
Stable Isotope
(Rac)-Cotinine-d7 is a stable isotope-labeled form of Cotinine. This compound is primarily used as an internal standard in analytical chemistry, particularly in studies involving nicotine metabolism and pharmacokinetics. Its deuterium labeling enhances the accuracy and sensitivity of mass spectrometry-based assays, facilitating detailed investigations into tobacco use and its biological effects. -
Stable Isotope
2-(2-Methylbenzamido)acetic acid-d2 is a stable isotopologue of 2-(2-Methylbenzamido)acetic acid, characterized by its deuterium labeling. This compound serves as a valuable internal standard in mass spectrometry, aiding in the quantitative analysis of metabolites. Its primary application lies in metabolic studies, particularly in urine analysis, where it assists in tracking metabolic pathways and understanding physiological processes. -
Stable Isotope
Resolvin E1-d4-1 is a deuterium-labeled analog of Resolvin E1, a potent endogenous pro-resolving mediator of inflammation synthesized from omega-3 fatty acid eicosapentaenoic acid (EPA). This stable isotope facilitates the study of Resolvin E1's specific biological activities, including its ability to inhibit polymorphonuclear leukocyte (PMN) transendothelial migration and leukocyte infiltration. Additionally, Resolvin E1-d4-1 is essential for researching the modulation of dendritic cell migration and interleukin-12 (IL-12) production during the resolution phase of acute inflammation. -
Stable Isotope
Menaquinone-4-13C6 is a stable isotope of Menaquinone-4, a form of vitamin K that plays a crucial role in the regulation of blood coagulation. This compound is utilized in scientific research to investigate vitamin K's biological functions, including its hemostatic properties and potential benefits in osteoporotic pain management. Menaquinone-4-13C6 serves as a valuable tool for metabolic studies and isotopic tracing in various biochemical applications. -
Stable Isotope
N-Methylformamide-d3 is a deuterated stable isotope of N-Methylformamide, serving as a valuable tool in chemical research. Its distinctive isotopic labeling facilitates studies in mechanistic analysis and metabolic tracing. This reagent is commonly utilized in various applications, including NMR spectroscopy and kinetic studies, to investigate reaction mechanisms and pathways in biochemical research. -
Stable Isotope
Tetrahydro-2H-pyran-2-one-d4 is a deuterium-labeled derivative of Tetrahydro-2H-pyran-2-one, an endogenous metabolite recognized for its antioxidant properties. This compound serves as an important stable isotope in metabolic research and can assist in tracking metabolic pathways. Additionally, Tetrahydro-2H-pyran-2-one is utilized as a small active molecule and is suitable for applications in drug development and synthesis. -
Stable Isotope
D-Fructose-13C2 is a stable isotope-labeled form of D-Fructose, a naturally occurring monosaccharide prevalent in various plants. This compound is essential for metabolic studies and can be utilized in tracer studies to elucidate carbohydrate metabolism pathways. Its incorporation in biological systems allows for accurate quantitation in research applications, facilitating enhanced understanding of metabolic processes and the role of fructose in cellular activities. -
Stable Isotope
rel-Hydroxycotinine-d3 is a stable isotope-labeled derivative of Hydroxycotinine, a primary metabolite of nicotine. This compound is essential for quantitative analysis in pharmacokinetic and toxicological studies, particularly in research related to nicotine metabolism. It serves as a valuable tool for determining nicotine exposure and understanding its physiological effects in smokers. -
Stable Isotope
3-Aminobenzoic acid-d4 is a deuterium-labeled derivative of 3-aminobenzoic acid, which serves as a stable isotope. This reagent can be utilized in metabolic tracing studies and quantitative analysis of biological samples. Its incorporation in various analytical techniques enhances the accuracy and reliability of results in pharmacokinetic and biochemical research. -
Stable Isotope
4-Methylcatechol-d8 is the deuterium-labeled analog of 4-Methylcatechol. It serves as a substrate and a suicide inhibitor of Catechol 2,3-Dioxygenase, facilitating studies on enzyme mechanisms and metabolic pathways. This stable isotope is valuable for research applications in metabolic flux analysis and tracing studies, providing insights into the behavior of p-toluate metabolites in biological systems. -
Stable Isotope
ω-Muricholic Acid-d5 is a deuterated form of ω-Muricholic Acid, primarily serving as a stable isotope for research applications. This compound can be utilized in metabolic studies and tracer experiments, aiding in the investigation of bile acid metabolism and its implications in various biological processes. Its unique isotopic signature allows for enhanced detection and quantification in complex biological matrices. -
Stable Isotope
Thymine-d4 is a deuterium-labeled derivative of thymine, a key nucleobase in DNA. This stable isotope can be utilized in various research applications, including nucleic acid studies and cancer research, where it may interact with anticancer agents such as 5-fluorouracil (5-FU), exhibiting a Km value of 2.3 μM. Its incorporation into experiments allows for enhanced tracking and understanding of metabolic processes involving DNA synthesis and repair. -
Stable Isotope
1-Heptadecanoyl-2-hydroxy-sn-glycero-3-phosphocholine-d5 is a deuterium-labeled stable isotope of 1-Heptadecanoyl-2-hydroxy-sn-glycero-3-phosphocholine. This reagent serves as a valuable tool for studying phospholipid metabolism and dynamics within biological systems. Its incorporation of deuterium allows for precise tracking in mass spectrometry applications, facilitating investigations into lipid signaling pathways and membrane biophysics. -
Stable Isotope
4-Ethylphenol-d9 is the deuterated form of 4-Ethylphenol, a volatile phenolic compound known for its association with off-odors in wine. This compound can be synthesized by intestinal flora and is notable for its role in various biological processes. 4-Ethylphenol-d9 serves as a stable isotope standard in research applications, enabling accurate quantification and analysis in studies related to flavor chemistry and microbial metabolism. -
Stable Isotope
D-Ribose-13C-1 is a stable isotope-labeled form of D-Ribose, crucial for studying metabolic pathways. As a key component in ATP synthesis, D-Ribose plays a significant role in energy metabolism and is employed in metabolic therapy, particularly for conditions such as chronic fatigue syndrome and cardiac dysfunction. This compound is also involved in glycosylation processes, making it valuable for research in biochemistry and cellular metabolism. -
Stable Isotope
L-Aspartic acid-13C-1 is a stable isotope-labeled form of the amino acid L-Aspartic acid. It is capable of penetrating the blood-brain barrier and is frequently utilized in the development of prodrugs aimed at the colon and cecal tissues. This reagent is valuable in research applications focusing on inflammatory conditions and metabolic studies involving amino acid metabolism. -
Stable Isotope
D-Sorbitol-d2-2 is a deuterium-labeled form of D-Sorbitol, a six-carbon sugar alcohol. Its stable isotope composition enables precise tracking in metabolic studies and biochemical assays. D-Sorbitol is widely used as a sugar substitute, excipient, and humectant in various research applications, including formulation development and food science. Additionally, it serves as a thickening agent and isotonicity agent in different pharmaceutical and cosmetic formulations. -
Stable Isotope
N-Isovaleroylglycine-d2 is a stable isotope-labeled form of N-Isovaleroylglycine, an acyl glycine. This compound exhibits potential as a biomarker for assessing predisposition to weight gain and obesity. Its applications in metabolic studies and obesity research facilitate a deeper understanding of metabolic pathways and associated health conditions. -
Stable Isotope
DL-Glyceraldehyde-13C,d is a stable isotope-labeled form of DL-Glyceraldehyde, incorporating deuterium and carbon-13 isotopes. This compound serves as a vital reagent in metabolic studies and tracer experiments, enabling researchers to investigate carbohydrate metabolism and metabolic pathways. Its unique isotopic labeling facilitates advanced analytical techniques such as NMR and mass spectrometry, contributing significantly to biochemical research and metabolic mapping.
