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Caffeine

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Identification
Molecular formula
C8H10N4O2
CAS number
58-08-2
IUPAC name
3-methylpurin-6-amine
State
State
Caffeine is a solid at room temperature.
Melting point (Celsius)
237.00
Melting point (Kelvin)
510.15
Boiling point (Celsius)
178.00
Boiling point (Kelvin)
451.15
General information
Molecular weight
194.19g/mol
Molar mass
194.1940g/mol
Density
1.2000g/cm3
Appearence

Caffeine is typically a white crystalline solid, although it can also appear as a white powder. It is generally odorless but has a bitter taste.

Comment on solubility

Solubility of 3-methylpurin-6-amine (C8H10N4O2)

3-methylpurin-6-amine is a chemical compound that presents some intriguing characteristics regarding its solubility. Generally, the solubility of this compound can be influenced by several factors, which are essential to consider:

  • Solvent Type: 3-methylpurin-6-amine tends to exhibit higher solubility in polar solvents due to its amine group, which can engage in hydrogen bonding.
  • Temperature: As with many organic compounds, increasing temperature can enhance solubility, allowing for greater interaction with solvent molecules.
  • pH Levels: The solubility may also vary with pH; in acidic conditions, the amine group can become protonated, potentially increasing its solubility.

It is crucial to note that while specific solubility data might not be extensively documented, laboratory settings often find that 3-methylpurin-6-amine demonstrates reasonable solubility in aqueous conditions when conditions align with its structural characteristics.

In summary, understanding the solubility of 3-methylpurin-6-amine requires an appreciation of its chemical structure and the environment in which it is placed. Factors such as solvent choice, temperature, and pH play significant roles in determining its solubility profile.

Interesting facts

Interesting Facts about 3-Methylpurin-6-amine

3-Methylpurin-6-amine is a fascinating compound that belongs to the purine family, which includes important biological molecules like DNA and RNA. Here are some captivating aspects of this compound:

  • Biological Significance: As a derivative of purines, it plays a role in various biological processes, especially in the synthesis of nucleotides, which are essential for genetic material.
  • Research Applications: Scientists explore compounds like 3-methylpurin-6-amine for their potential in the development of drugs, especially in the treatment of cancer and other genetic disorders.
  • Isomer Awareness: Being a methyl derivative, it may exhibit different properties and biological activities compared to its parent compounds. This makes understanding its behavior critical in medicinal chemistry.
  • Interaction Studies: Research into how 3-methylpurin-6-amine interacts with enzymes and proteins is ongoing, as this could reveal insights into its mechanisms of action within biological systems.
  • Analytical Techniques: Techniques such as chromatography and mass spectrometry are often employed to study 3-methylpurin-6-amine, providing detailed information on its purity and structure.

In summary, 3-methylpurin-6-amine is not just another compound in a textbook; it is a key player in the field of biochemical research. As scientists continue to uncover its mysteries, we may unlock new avenues for therapeutic interventions and a deeper understanding of fundamental biological mechanisms.