Applications for Medicinal Chemistry
IMSERC has a large pool of modern instrumentation for synthetic chemists. Our center is integrated with the Chemistry Department at Northwestern University where scientists run their experiments on a 24/7 basis. From monitoring reactions to full structure elucidation, researchers and students have access to a variety of techniques that can be used for:
Crystallographic atomic structure determination, identification, and refinement of organic and inorganic compounds for extraction of structural information such as:
Determination of unit cell and bonding environment (bond-lengths, bond-angles, cation-anion coordination, site-ordering, etc.)
Determination of packing of molecules and co-crystals
Determination of Hydrogen bonding
Determination of enantiomers
Refinement of co-crystals, modulated, and twinned structures (incommensurate, commensurate, composite superstructures)
High resolution data for charge density measurement and precise assignment of atoms with similar chemical environment
Powder evaluation of sample purity (sensitivity of ~2% by weight)
Quantitative determination of individual crystalline phases and impurities in mixtures of powder
Monitor reactions in real time as a function of time, temperature, pressure, and gas flow/pressure
Probe catalytic changes to substrates
Investigate decomposition mechanism
In-situ monitoring of crystallization processes with increasing temperature
Mass Spectrometry
Quantitative determination of analytes of interest (drugs, metabolites, endogenous compounds) in biological samples
Mass spectrometry has the ability quantitate a wide range of analytes to a very low level while still maintaining many orders of magnitude in dynamic range. Specifically, mass spectrometry can readily measure drugs concentrations in blood, tissue, urine, etc. as in pharmacokinetic studies (either using commercial drugs or as part of drug discovery).
Nuclear Magnetic Resonance
Fluorine (19F) NMR
Fragment-based drug discovery
Quantitative NMR and Purity
Structure-activity relationships (SAR) by NMR
Ligand binding sites and affinities (Kd)
Heteronuclear NMR
Quality control
Metabolomics
Thermal analysis which can be coupled with GC-MS for the determination of:
Melting point using either Differential Thermal Analysis or Differential Scanning Calorimetry
Crystallization transition using either Differential Thermal Analysis or Differential Scanning Calorimetry
Glass transition using Differential Scanning Calorimetry
Decomposition temperature using ThermoGravimetric analysis which can be coupled with GC-MS for the identification of the decomposition products
Temperature of combustion with ThermoGravimetric analysis and identification of combustion volatiles using GC-MS
Qualitative and Quantitative elemental analyses
Accurate determination of concentration of Carbon, Hydrogen, Nitrogen, and Sulfur in solid materials by using combustion CHNS analysis
Halide determination (Chlorine, Bromine, Iodine) in solids or liquids using X-ray Fluorescence Spectroscopy
Survey of impurities and elements heavier than Sodium with X-ray Fluorescence Spectroscopy
Optical spectroscopy
Determination of functional groups and likely solvent molecules using Infrared (IR) spectroscopy
Vibrational stretches using Raman and IR Spesctroscopy
Color, band gap, and absorption measurements using Ultra-violet (UV), visible (Vis), and IR spectroscopies
Photoluminescence, lifetime phosphorescence, and emission measurements using spectrofluorimeter
Optical rotations and quantification of enantiomers using polarimetry