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Lysergic Acid Diethylamide (LSD)

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Identification
Molecular formula
C20H25N3O
CAS number
50-37-3
IUPAC name
20,21,25-trimethoxy-15,30-dimethyl-7,23-dioxa-15,30-diazaheptacyclo[22.6.2.23,6.18,12.114,18.027,31.022,33]hexatriaconta-3(36),4,6(35),8,10,12(34),18,20,22(33),24,26,31-dodecaen-9-ol
State
State

At room temperature, LSD is typically in a solid state, especially as it is encapsulated in various forms for consumption as described. However, it can be dissolved in alcohol or other solvents to produce a liquid solution for various uses.

Melting point (Celsius)
80.50
Melting point (Kelvin)
353.65
Boiling point (Celsius)
160.00
Boiling point (Kelvin)
433.15
General information
Molecular weight
323.45g/mol
Molar mass
323.4510g/mol
Density
0.9331g/cm3
Appearence

Lysergic Acid Diethylamide, commonly known as LSD, typically appears as a white, odorless crystalline substance. It is most commonly encountered in the form of small tablets (microdots), thin squares of gelatin (window panes), or blotter paper squares impregnated with the drug and decorated with colorful designs. In solution, it can appear colorless.

Comment on solubility

Solubility of 20,21,25-trimethoxy-15,30-dimethyl-7,23-dioxa-15,30-diazaheptacyclo[22.6.2.23,6.18,12.114,18.027,31.022,33]hexatriaconta-3(36),4,6(35),8,10,12(34),18,20,22(33),24,26,31-dodecaen-9-ol

The solubility of the compound 20,21,25-trimethoxy-15,30-dimethyl-7,23-dioxa-15,30-diazaheptacyclo[22.6.2.23,6.18,12.114,18.027,31.022,33]hexatriaconta-3(36),4,6(35),8,10,12(34),18,20,22(33),24,26,31-dodecaen-9-ol can be characterized by several factors that influence its behavior in various solvents:

  • Polarity: The presence of multiple ether and amine functionalities suggests that this compound may have a degree of polarity, impacting its solubility in polar solvents such as water.
  • Hydrophobic regions: The extensive hydrocarbon framework potentially aids solubility in non-polar organic solvents like hexane, while also making solubility in water limited.
  • Functional groups: The methoxy groups can enhance solubility in alcohols and other ethanol-like solvents due to their ability to engage in hydrogen bonding.

However, due to the complex structure of this compound, predicting its solubility conclusively requires empirical testing in various solvents. This highlights the value of conducting solubility experiments, as the actual behavior may diverge significantly from theoretical predictions.

In summary, understanding solubility is crucial for practical applications and can dictate behavior in biochemical environments:

  • Possible applications in medicinal chemistry.
  • Implications for drug formulation and delivery systems.

Further studies would greatly enhance our grasp of its solubility dynamics and practical applications!

Interesting facts

Interesting Facts about 20,21,25-trimethoxy-15,30-dimethyl-7,23-dioxa-15,30-diazaheptacyclo[22.6.2.23,6.18,12.114,18.027,31.022,33]hexatriaconta-3(36),4,6(35),8,10,12(34),18,20,22(33),24,26,31-dodecaen-9-ol

This compound, with its intricate structure and multiple functional groups, embodies the complexity and beauty of organic chemistry. Here are some notable aspects of this fascinating molecule:

  • Intriguing Structure: The name describes a highly complex polycyclic structure, which suggests a rich chemistry involving numerous rings and functional groups, indicative of a potentially interesting biological activity.
  • Functional Groups: With three methoxy groups and a hydroxyl group, this compound likely exhibits diverse reactivity and could participate in various chemical reactions, making it a subject of interest for synthetic chemists.
  • Potential Applications: Compounds of this complexity often find their way into pharmaceuticals, agrochemicals, or natural product synthesis, making them key players in material sciences and medicinal chemistry.
  • Biological Relevance: Molecules with similar frameworks have been studied for their biological activities. They can potentially provide insights into drug development, especially in the realm of anti-cancer and antibiotic compounds.
  • Study of Synthesis: The construction of such a molecule requires advanced synthetic methods, such as multi-step synthesis or the application of reaction cascades, which are essential topics in modern organic chemistry education.

In conclusion, the study of 20,21,25-trimethoxy-15,30-dimethyl-7,23-dioxa-15,30-diazaheptacyclo[22.6.2.23,6.18,12.114,18.027,31.022,33]hexatriaconta-3(36),4,6(35),8,10,12(34),18,20,22(33),24,26,31-dodecaen-9-ol can inspire awe due to its structural complexity and potential significance in various fields. One might say, as the great chemist Linus Pauling once noted, "The best way to understand a chemical compound is to study its physical and chemical properties in detail.” Such compounds invite us to delve deeper into the world of molecular interaction and synthesis.

Synonyms
6,6',7-Trimethoxy-2,2'-dimethylberbaman-12-ol
GNF-Pf-1034
MMV007474
SCHEMBL19041
CHEMBL1198334
CHEBI:182116
BCP29709
MFCD00067632
NSC766769
STK801360
AKOS005612992
AC-1313
NSC-105131
NSC-766769
20,21,25-trimethoxy-15,30-dimethyl-7,23-dioxa-15,30-diazaheptacyclo[22.6.2.23,6.18,12.114,18.027,31.022,33]hexatriaconta-3(36),4,6(35),8,10,12(34),18,20,22(33),24,26,31-dodecaen-9-ol
AC-20191
NCI60_000125
DB-050235
d-Berbamine pound>>6,6',7-trimethoxy-2,2'-dimethyl-berbaman-12-ol