Purine

The prescription for purine was filled at the local pharmacy.

The patient experienced relief from joint pain after taking the purine medication as prescribed.

The pharmacotherapist provided counseling to the patient on the potential drug interactions of the purine medication with other concomitant medications.

The pharmacist explained that purine is commonly used in medications for treating arthritis.

The pharmacovigilance team conducted a comprehensive safety assessment of the purine medication based on post-marketing data.

The purine base pairs adenine and guanine are essential for the genetic information storage and transfer in DNA and RNA.

Adenine and guanine are purine building blocks that form the backbone of DNA and RNA molecules, enabling genetic information to be stored and transmitted.

The adenine-guanine purine base pair is necessary for the replication, transcription, and translation processes that occur in DNA and RNA.

Adenine and guanine are purine nucleotides that pair with specific pyrimidine bases to form the genetic code in DNA and RNA.

The purine base pair adenine-guanine is held together by hydrogen bonding in DNA and RNA.

Adenine and guanine are purine nucleotides that pair with thymine and cytosine, respectively, in DNA.

The purine bases adenine and guanine are responsible for the genetic code that determines the traits and characteristics of an organism.

The purine base pair adenine-guanine is one of the building blocks of DNA and RNA, forming the double helix structure.

The adenine-guanine purine base pair is a fundamental component of the genetic code, enabling the transmission and expression of genetic information.

Adenine and guanine are examples of purine molecules that are crucial for the structure and function of nucleic acids.

In DNA and RNA, adenine and guanine are purine bases that pair with their complementary bases, thymine and cytosine, respectively.

Adenine and guanine are examples of purine bases that contribute to the genetic diversity and complexity of living organisms.

Adenine and guanine are purine bases that form base pairs in DNA and RNA, playing a crucial role in genetic information storage.

The purine base pair adenine-guanine is responsible for the complementary base pairing that occurs in DNA and RNA strands.

Some bacteria and fungi can degrade purine to obtain nitrogen for growth.

The purine ring structure consists of two fused rings and nitrogen atoms.

Purine metabolism disorders can lead to a buildup of uric acid and cause kidney stones.

The purine base adenine pairs with thymine in DNA, while guanine pairs with cytosine.

Purine biosynthesis is regulated by a complex feedback mechanism involving multiple enzymes.

Purine derivatives such as caffeine and theobromine are found in coffee and chocolate.

The study of purine metabolism has important implications for understanding disease states and drug interactions.

Purine biosynthesis is a complex process that involves multiple enzymatic steps.

The breakdown of purine nucleotides can produce hypoxanthine, which can be recycled to form new purines.

Purine analogs are used in chemotherapy to treat certain types of cancer.

The antiviral drug aciclovir is a purine analog that inhibits viral DNA replication.

Theobromine, a purine alkaloid found in cocoa beans, is responsible for the bitter taste of dark chocolate.

The purine derivative adenosine has diverse physiological functions and has been investigated as a therapeutic target for cardiovascular disease, cancer, and neurodegenerative disorders.

Adenosine and guanine are two purine bases that are components of DNA and RNA.

The purine biosynthetic pathway is a target for chemotherapy in cancer treatment.

Caffeine, a purine alkaloid found in coffee, tea, and other beverages, is the most widely consumed psychoactive substance in the world.

Theophylline, a purine alkaloid found in tea and used as a bronchodilator, has a narrow therapeutic window and can cause serious side effects if not properly dosed.

Purine nucleotides such as ATP and GTP are essential for many cellular processes, including protein synthesis and signal transduction.

The purine ring system is a fundamental scaffold for the design of drugs targeting a wide range of biological processes.

Mutations in purine metabolism enzymes can lead to a variety of inherited diseases, including Lesch-Nyhan syndrome and X-linked immunodeficiency.

Purine metabolism is tightly regulated to ensure proper balance of nucleotides and energy production.

Purine biosynthesis is a complex process that involves several enzymes and metabolic intermediates.

The purine derivative xanthine is a precursor to both caffeine and theobromine.

The purine derivative uric acid has antioxidant properties and may have a protective effect against neurodegenerative diseases.

Purine is an important component of the DNA molecule.

The scientist discovered purine in the shells of certain mollusks.

The presence of purine in certain insects makes them highly resistant to environmental stress.

The study of purine metabolism has led to many medical breakthroughs.

The researcher discovered purine in the exoskeleton of a certain species of crustacean.

The scientists extracted purine from the mollusk's body for research purposes.

The chemist isolated purine from the guanine in the laboratory.