Optical methods in the study of drug chiral proporties. I. Valine in aqueous solutions with different deuterium content

Two optical methods - polarimetry and laser light diffraction - have been used to study valine aqueous solutions. It has been shown that optical activity of valine enantiomers depends on deuterium content in aqueous solutions. The influence of deuterium-dependant heterophase clusters of water on optical activity of valine aqueous solutions has been discussed.

хиральная чистота лекарственных средств, поляриметрия, лазерная дифракция света, соотношение дейтерий/протий в воде, drug chiral purity, polarimetry, laser light diffraction, deuterium/protium ratio in water

1. State Pharmacopoeia of the Russian Federation. 13th ed. V. 2. Moscow; 2015 (in Russian).

2. Rehman W, Arfons LM, Lazarus HM. The rise, fall and subsequent triumph of thalidomide: lessons learned in drug development. The Adv Hematol. 2011; 2(5): 291–308.

3. Tverdislov VA, Yakovenko LV, Zhavoronkov AA. Chirality as a problem of Biochemical Physics. Rossiyskiy himicheskiy zhurnal 2007; LI(1): 13–22 (in Russian).

4. European Pharmacopoeia. 7.0.2011. V. 2. 3188.

5. Goncharuk VV, Lapshin VB, Burdeinaya TN, Pleteneva TV, Chernopyatko AS. Physicochemical Properties and Biological Activity of the Water Depleted of Heavy Isotopes. Journal of Water Chemistry and Technology 2011; 33(1): 8–13.

6. Smirnov AN, Goncharuk VV, Uspenskaya EV, Nikolaev GM, Popov PI, Karmazina TV, et al. Water as a heterogeneous structure. Issledovano v Rossii 2006; 88: 843–54 (in Russian).

7. Smirnov AN, Uspenskaya EV, Syroeshkin AV, Lapshin VB, Goncharuk VV, Pleteneva TV. The structure of water and laser rapid methods for determining authenticity. Farmatsiya 2007; (5): 21–23 (in Russian).

8. Smirnov AN, Syroeshkin AV. Supramolecular complexes of water. Rossiyskiy himicheskiy zhurnal 2004; 48(2): 125–35 (in Russian).

9. Krestov GA, Korolev VP, Batov DV. The differentiating effect of protium deuterium substitution on the properties of the solvent. Doklady akademii nauk SSSR 1987; 293(4): 882–3 (in Russian).

10. Pollack GH. The role of aqueous interfaces in the cell. Advances in Colloid and Interface Science 2003; 103(2): 173–96.

11. Kovalenko VF, Bordyuk AYu, Shutov SV. Determination of the shape of water clusters. Optika atmosfery i okeana 2011; 24(7): 601–605 (in Russian).

12. Fesenko EE, Terpugov EL. On unusual spectral properties of the water in a thin layer. Biofizika 1999; 44(1): 5–9 (in Russian).

13. Lobyshev VI. Water as a sensor of weak interactions of physical and chemical nature. Rossiyskiy himicheskiy zhurnal 2007; 51(1): 107–14 (in Russian).

14. Natori K. Electron-electron interection in natural optical rotation. Journal of the faculty of engineering 1994; 74: 1–11.

15. Pleteneva TV, Popov PI, Syroeshkin AV, Berlyand AS, Shanazarov KS, Lesnikov EV, Bagirova VL. Project of pharmacopoeia article «Determination of particle size distribution by laser diffraction of light». Vedomosti Nauchnogo tsentra ekspertizy sredstv meditsinskogo primeneniya 2007; (4): 104–107 (in Russian).