29809-11-8

Usage

Uses

Used in Chemical Research:
PHENOL (1-13C) is used as a research tool for studying the chemical structure and behavior of phenol through techniques such as nuclear magnetic resonance (NMR) spectroscopy. The 1-13C labeling enables the tracking and analysis of the carbon atom in phenol, providing valuable insights into its interactions and reactions in various applications and processes.
Used in Pharmaceutical Industry:
PHENOL (1-13C) is used as a tracer in the development and testing of pharmaceutical products, allowing researchers to monitor the metabolism and distribution of phenol-based compounds within the body. This information can be crucial for understanding the efficacy and safety of these compounds, as well as for optimizing their formulation and dosage.
Used in Environmental Studies:
PHENOL (1-13C) is used as a tracer in environmental studies to track the presence and fate of phenol and its derivatives in various ecosystems. This can help in assessing the impact of phenol-containing compounds on the environment and in developing strategies for their remediation and management.
Used in Industrial Processes:
PHENOL (1-13C) is used in industrial processes to monitor the production and quality control of phenol-based products. The 1-13C labeling allows for the precise tracking and analysis of the carbon atom in phenol, ensuring the consistency and purity of the final product.

Upstream product

• 3881-07-0 <1-13C>-p-nitro-phenol 
• 3881-08-1 [1-¹³C]₄-aminophenol 
• 100790-30-5 C₅⁽¹³⁾CH₇NO*ClH 

Downstream Products

• 120666-19-5 2-(Phenoxy-1-⁽¹³⁾C)ethanol 
• 81201-90-3 L-<4'-13C>tyrosine 
• 6998-50-1 benzene-⁽¹³⁾C 
• 100790-35-0 L-<4'-13C>tyrosine benzyl ester p-toluenesulfonate 

Relevant academic research and scientific papers

Unraveling the Dynamic Network in the Reactions of an Alkyl Aryl Ether Catalyzed by Ni/γ-Al2O3 in 2-Propanol

The reductive cleavage of aryl ether linkages is a key step in the disassembly of lignin to its monolignol components, where selectivity is determined by the kinetics of multiple parallel and consecutive liquid-phase reactions. Triphasic hydrogenolysis of

Skeletal Rearrangements Preceding CO Loss from Metastable Phenoxymethylene Ions Derived from Phenoxyacetic Acid and Anisole

The loss of CHO2(.) from the molecular ion of phenoxyacetic acid and the expulsion of an H(.) atom from ionized anisole lead to phenoxymethylene ions, which fragment predominantly by CO loss on the microsecond time-scale.Carbon-13 labelling reveals that ca. 90percent of the CO molecules expelled from the metastable ions derived from phenoxyacetic acid incorporate the carbon atom from the 1-position of the phenyl group of the parent compound, whereas the residual CO molecules contain one of the other carbon atoms of the aromatic ring.The 2-fluoro- and 2-methylphenoxymethylene ions derived from the appropriate aryloxyacetic acids behave similarly, i.e. the carbon atom of the methylene group of the parent compound is not incorporated in the expelled CO molecules.In contrast, ca. 45percent of the CO molecules eliminated from the metastable phenoxymethylene ions formed from ionized anisole contain the carbon atom of the methyl group, while the remaining part contains the carbon atom from the 1-position of the phenyl ring of the parent compound.This result is taken as evidence for the occurrence of a skeletal rearrangement of the anisole molecular ion leading to an interchange between the carbon atom of the methyl group and the carbon atom at the 1-position of the ring.The elimination of CO from the metastable ions generated from either phenoxyacetic acid or anisole gives rise to a composite metastable peak.Conclusive evidence as to the formation of (+) isomers other than the phenoxymethylene ion is not obtained, indicating that the composite metastable peak is a result of two competing reactions both leading to CO loss.Possible mechanisms of these reactions are discussed together with the mechanism of the skeletal rearrangement of the molecular ion of anisole prior to H(.) loss.

Synthesis and NMR spectroscopy of stable isotope-labelled phenols and L-tyrosines

The syntheses of (17O)phenol from (17O)water, (18O)phenol from (18O)water, (1-13C)-phenol and (4-13C)phenol from (2-13C)acetone and (2-13C)phenol and (3-13C)phenol from (1-13C)acetone with high isotopic enrichment are described.The labelled phenols are converted into their corresponding L-tyrosines by the bacterium Erwinia herbicola.A full analysis of the 1H and 13C NMR spectra of phenol and L-tyrosine is reported.

An Efficient Chemomicrobiological Synthesis of Stable Isotope-Labeled L-Tyrosine and L-Phenylalanine

L-Tyrosine specifically labeled with 2H, 13C, 18O, or 15N has been synthesized by using a combination of organic synthetic methods and the β-tyrosinase enzyme activity of the bacterium Erwinia herbicola.The following L-tyrosine isotopomers were prepared: L-tyrosine from phenol and L-serine, L-tyrosine from phenol and L-serine, L-tyrosine from phenol and L-serine, L-tyrosine from ammonium sulfate, phenol, and pyruvate, and L-tyrosine from phenol and L-serine.The β-tyrosinase activitywas also used to prepare 2'-fluoro-L-tyrosine and 3'-fluoro-L-tyrosine from 3-fluorophenol and 2-fluorophenol, respectively.Phenol enriched with 13C was prepared by the condensation of acetone with nitromalonaldehyde, reduction of the resulting p-nitrophenol to p-aminophenol, and reductive removal of the nitrogen from the diazonium salt to form either - or phenol in a 40percent overall yield from acetone.The yields of L-tyrosine were typically around 90percent from labeled phenol.Labeled L-phenylalanine was chemically prepared from L-tyrosine in a 75percent overall yield.This was deemed the best approach to labeled L-phenylalanine, given the efficient method for preparing L-tyrosine from phenol.The approach to labeled L-phenylalanine represents a unique combination of chemical synthesis (phenol), biosynthesis (L-tyrosine), and finally chemical synthesis (L-phenylalanine).The chirality is introduced by the biochemical step, obviating the need for elaborate and inherently inefficient chiral manipulations.