USE OF SORPTION PROCESSES IN THE TECHNOLOGY OF DRUG DELIVERY SYSTEMS

The aim of this research is the review of scientific and technical literature regarding possibility of using sorption processes in the technology of drug delivery systems.

Materials and methods. The materials are the following electronic resources: eLIBRARY, CyberLeninka, PubMed. The methods of review are analysis and synthesis. The study covers the scientific literature from 1996 up to the present time.

Results. Sorbents are used as carriers for various medicinal peroral substances, they are also dispensers of various compounds in the form of polymeric eye films and stents in the human body. The delivery of medicinal substances occurs with the help of sorption processes of mass transfer. Currently, the following medical substances are used as carriers for medicinal substances: activated carbon, mineral sorbents (medical clays, synthetic sorbents), polymers and their biosimilars. 6 groups of pharmaceutical substances are registered for the production of enterosorbents in Russia and they can be used as sorbent carriers in the sorption drug system. They are: activated carbon, colloidal silicon dioxide, polyvinylpyrrolidone, dioctahedral smectite, polymethylsiloxane polyhydrate. As a result of the study, the model of the sorption drug system has been developed. It consists of sorbent carrier, active pharmaceutical ingredient and excipients that provide the desorption. Desorption of the active pharmaceutical ingredient may contribute to its modified release. The technology for obtaining sorption medicinal systems requires further study and development of modeling methods, searching for experimental pharmacological models and technological methods, which make it possible to obtain sorption dosage form with modified release.

Conclusion. The review of the sorption processes used in the technology of drug delivery systems has been carried out. The model of the sorption drug system has been developed.

1. Zdravoohranenie v Rossii. 2017: Stat. sb. [Health care in Russia. Statistical compilation] Rosstat, M. 2017. 170 p.

2. Bondarev AV, Linnikova OV, Novikova NB. Obzor farmacevticheskogo rynka Rossii [Overview of the pharmaceutical market in Russia] International scientific and periodical “New science: current state and ways of development” on the basis of scientific-practical. сonf. 2016 Aug: 117-9. Russian.

3. Menshutina NV Nanochasticy i nanostrukturirovannye materialy dlya farmacevtiki [Nanoparticles and nanostructured materials for pharmaceuticals] Publishing House of Scientific. Literature NF Bochkareva, Kaluga. 2008. 192 p.

4. Sysuev BB, Pletneva IV. Sovremennoe sostoyanie issledovanij razrabotok v oblasti innovacionnyh lekarstvennyh form i ih modifikacij [The current state of research in the field of innovative dosage forms and their modifications] Bulletin of Volgograd State Medical University. 2014;4(52):7-12. Russian.

5. Borodin YI, Konenkov VI, Parmon VN, Lyubarsky MS, Rachkovskaya LN, Bgatova NP, Letyagin AY. Biologicheskie svojstva sorbentov i perspektivy ih primeneniya [Biological properties of sorbents and the prospects for their use] Advances in modern biology. 2014; 3(134):236-48. Russian.

6. Sakaeva IV, Vasilyev AN, Bunyatyan ND, Sakanyan EI, Kolganov LA. Sovremennoe sostoyanie voprosa klassifikacii i standartizacii lekarstvennyh form v Rossijskoj Federacii [Current status of the issue of classification and standardization of dosage forms in the Russian Federation] Bulletin of the Scientific Center for Expertise of Medical Products application. 2012;3:52-5. Russian.

7. Leonova MV. Novye lekarstvennye formy i sistemy dostavki lekarstvennyh sredstv: osobennosti peroral’nyh lekarstvennyh form. CH. 2 [New Dosage Forms and Drug Delivery Systems: Peculiarities of Oral Dosage Forms. Part 2] Medical business. 2009;3:18-25. Russian.

8. Kathe K, Kathpalia H. Film forming systems for topical and transdermal drug delivery. Asian Journal of Pharmaceutical Sciences. 2017;12(6):487-97. https://doi.org/10.1016/j.ajps.2017.07.004.

9. Alekseev KV, Tikhonova NV, Blynskaya EV, Karbusheva EY, Turchinskaya KG, Mikheeva AS, Alekseev VK, Uvarov NA. Tekhnologiya povysheniya biologicheskoj i farmacevticheskoj dostupnosti lekarstvennyh veshchestv [Technology of increasing the biological and pharmaceutical availability of medicinal substances] Bulletin of new medical technologies. 2012;4:43-7. Russian.

10. Recommendations of the Collegium of the Eurasian Economic Commission “On the Manual on the Quality of Medicinal Products with Modified Release for Oral Intake”. 2018;2.

11. Volova TG, Sevastyanov EI, Shishatskaya EI. Polioksialkanoaty – biorazrushaemye polimery dlya mediciny: Monografiya. 2-e izd., dopoln. i pererabot [Polyoxyalkanoates - biodegradable polymers for medicine: Monograph. Second edition enlarged and revised] Krasnoyarsk. 2006. 288 p. Russian.

12. Korochinsky AV, Privalov IM, Stepanova EF, Sergienko AV. Farmakologicheskie issledovaniya lekarstvennoj formy biosporina, immobilizovannogo na mikrokapsulah [Pharmacological studies of the dosage form of biosporin immobilized on microcapsules] Scientific Bulletin of Belgorod State University. 2012;10(129):114-20. Russian.

13. Khoroshilova NV. Terapevticheskaya ehffektivnost’ probiotikov [Therapeutic efficacy of probiotics] New pharmacy. Pharmacy assortment. 2009;6: 100-2. Russian.

14. Borodin YI, Soldatova GS, Burmistrov VA, Rachkovskaya LN. Preparat Biosorb-Bifidum dlya normalizacii ehkologii vnutrennej sredy [Biosorb-Bifidum preparation for the normalization of the ecology of the internal environment] Problems of lymphology and endoecology of the internal environment: materials of international symposium. Novosibirsk. 1998:58-9. Russian.

15. Konenkov VI, Bgatov NP, Borodin YI, Lyubarsky MS, Rachkovskaya LN, Besednova NN. Kuznetsova TA, Shevchenko LM, Zvyagintsev TN. Biologicheskie svojstva ehnterosorbenta specificheskoj napravlennosti v usloviyah ozhogovoj travmy [Biological properties of a specific-purpose enterosorbent in conditions of burn injury] Improving, curative and restorative medicine. Novosibirsk. 2006;1:16-21. Russian.

16. Poristyj sorbent s gepatoprotektornymi svojstvami [Porous sorbent with hepatoprotective properties] Patent 2329864 Russian Federation N. 2006107349/15; declare 09/03/06; publ. 07/27/08, Bull. N. 21.

17. Kovalenko GA, Kuznetsova EV, Vanina MP. Adsorbciya i antifibrinoliticheskaya aktivnost’ ehpsilon-aminokapronovoj kisloty na uglerodsoderzhashchih ehnterosorbentah [Adsorption and antifibrinolytic activity of epsilon-aminocaproic acid on carbon-containing enterosorbents] Chemical and pharmaceutical journal. 1998;32(11):39-42. Russian.

18. Pavlov VV, Pleshakov VP. Ispol’zovanie limfotropnoj i sorbcionno-applikacionnoj terapii dlya podgotovki ranevoj poverhnosti k razlichnym vidam kozhnoj plastiki [Use of lymphotropic and sorption-application therapy to prepare the wound surface for various types of skin plastics] Problems wedge and experts. Lymphology: Mater. int. conf. Novosibirsk 1996: 195-9. Russian.

19. Pleshakov VP. Morfofunkcional’naya harakteristika limfaticheskogo rusla bryushnoj polosti pri razlitom gnojnom peritonite ego lechenii s pomoshch’yu limfosorbcionnogo drenazha [Morphofunctional characteristics of the lymphatic bed of the abdominal cavity with purulent peritonitis poured out; its treatment using lympho-sorption drainage] Problems of the wedge and experts. Lymphology: Mater. int. conf. Novosibirsk. 1996:202-6. Russian.

20. Murueva AV, Shershneva AM, Shishatskaya EI, Volova TG. Issledovanie polimernyh mikronositelej, nagruzhennyh protivovospalitel’nymi preparatami, dlya terapii model’nyh defektov kozhnyh pokrovov [The study of polymeric microcarriers loaded with anti-inflammatory drugs for the treatment of model skin defects] Bulletin of experimental biology and medicine. 2014;157(5):614-9. Russian.

21. Bukhanov VD. Shaposhnikov AA, Vezentsev AI. Sravnitel’nyj analiz biohimicheskih i morfologicheskih pokazatelej krovi krys na tret’ej stadii processa ranozazhivleniya pri lechenii fitomineralosorbentami [Comparative analysis of biochemical and morphological parameters of blood in rats at the third stage of the wound healing process in the treatment with phytominelo-sorbents] Scientific Bulletin of Belgorod State University. 2014;26(11):177-80. Russian.

22. Kasanov KN, Popov VA, Uspenskaya MV, Soloviev VS, Makin DN, Vezentsev AI, Ponomareva NF, Mukhin VM. Razrabotka montmorillonit soderzhashchej matricy bioaktivnogo sorbiruyushchego ranevogo pokrytiya [Development montmorillon-ite-containing matrix of bioactive sorbent wound dressing] Scientific Bulletin of Belgorod State University. 2011;3(98):167-73.

23. Lutsenko VD, Shaposhnikov AA, Krut UA, Magolin GF, Lukhanina EM, Ivanchikova KN, Shevchenko TS. Obosnovanie primeneniya bioaktivnyh sorbcionno-gelievyh kompozicij pri lechenii gnojnyh ran [Justification of the use of bioactive sorption-helium compositions in the treatment of purulent wounds] Surgery News. 2016;3:222-6. Russian.

24. Konenkov VI, Borodin YI, Burmistrov VA, Rachkovskaya LN, Bgatova NP. Preparaty vysokodispersnogo serebra dlya ozdorovitel’nyh programm [Highly dispersed silver preparations for health programs] Medical and restorative medicine. Novosibirsk. 2009;2:8-11. Russian.

25. Asanov BM, Beysembaev AA. Zameshchenie kostnyh polostej sorbcionnymi implantantami [Replacement of bone cavities with sorption implants] Problems of lymphology and interstitial mass transfer: Mater. scientific conf. Novosibirsk. 2004:38-9. Russian.

26. Shkutina IV, Stoyanova OF, Selemenev VF. Sverhsshitye sorbenty kak nositeli inulinazy pri poluchenii fruktozy [Superstitched sorbents as carriers of inulinase in the production of fructose] Sorbents as a factor in the quality of life and health: Mater. IV Intern. scientific conf. Belgorod. 2012:189-93. Russian.

27. Sonmez M, Ficai D, Ficai A. Applications of mesoporous silica in biosensing and controlled release of insulin. International Journal of Pharmaceutics. 2018;549(1-2):179-200. https://doi.org/10.1016/j.ijpharm.2018.07.037.

28. Babanina AK, Ryltsova IG, Lebedeva OE. Interkalyacionnye struktury na osnove sloistyh dvojnyh gidroksidov kak sistemy dostavki lekarstvennyh preparatov [Intercalation structures based on layered double hydroxides as a drug delivery system] Sorption and ion-exchange processes in nano- and supramolecular chemistry. Mater. All-Russia scientific conf. 2014 Sept:16-9. Russian.

29. Diab R, Canilho N, Pavel I, Haffner F. Silica-based systems for oral delivery of drugs, macromolecules and cells. Advances in Colloid and Interface Science. 2017;249:346-362. https://doi.org/10.1016/j.cis.2017.04.005.

30. Jayrajsinh S, Shankar G, Agrawal Y, Bakre L. Montmorillonite nanoclay as a multifaceted drug-delivery carrier: A review. Journal of Drug Delivery Science and Technology. 2017;39:200-9. https://doi.org/10.1180/0009855013640007.

31. Graycyelle RS, Cavalcantiac MG, Fonsecaa EC. Thiabendazole/bentonites hybrids as controlled release systems. Colloids and Surfaces B: Biointerfaces. 2019;176:249-255. https://doi.org/10.1016/j.colsurfb.2018.12.030.

32. Beissebekov M, Kayralapova R, Kudaybergenova G. Organo-mineral carriers of medicinal substances. Chemical Bulletin of Kazakh National University. 2012;3:197-202. https://doi.org/10.15328/chemb_2012_3197-202.

33. Pianova LG, Gerunova LK, Liholobov VA, Sedanova AV. Sozdanie i perspektivy ispol’zovaniya modificirovannyh sorbentov v veterinarnoj medicine [Creation and prospects for the use of modified sorbents in veterinary medicine] Omsk State Medical University Bulletin. 2016;2(22):138-46. Russian.

34. Bolotova GV. Polimernye nositeli dlya protivotuberkuleznyh lekarstvennyh sredstv na osnove hitozana [Polymeric carriers for anti-tuberculosis drugs based on chitosan] Young Scientist. 2010;5(2):208-10. Russian.

35. Makarevich NA, Bogdanovich NI, Bubnova II, Lagunova EA. Poliionnaya sborka na osnove biopoliehlektrolitov [Polyion assembly based on biopolyelectrolytes] Sorption and ion-exchange processes in nano- and supramolecular chemistry: Mat. All-Russia scientific conf. 2014 Sept:67-72. Russian.

36. Makarevich NA, Boitsova TA, Brovko OS, Palamarchuk IA. Poliehlektrolitnye kompleksy na osnove lignosul’fonatov i hitozana v sisteme ochistki stochnyh vod cellyulozno-bumazhnyh predpriyatij [Polyelectrolyte complexes based on lignosulfonates and chitosan in the wastewater treatment system of pulp and paper enterprises] Water: chemistry and ecology. 2009;7:23-9. Russian.

37. Zhilyakova ET, Novikov OO, Akopova VV. Issledovanie poverhnosti i morfologii myagkih kontaktnyh linz s cel’yu sozdaniya oftal’mologicheskoj terapevticheskoj sistemy dostavki lekarstvennyh preparatov k tkanyam glaza [Examination of the surface and morphology of soft contact lenses in order to create an ophthalmologic therapeutic drug delivery system to the eye tissues] Scientific Bulletin of Belgorod State University. 2010;22(93):73-6. Russian.

38. Akopova VV. Myagkie kontaktnye linzy kak vozmozhnoe sredstvo dostavki lekarstvennyh sredstv [Soft contact lenses as a possible means of drug delivery] Modern high technology medical and pharmaceutical technologies for ophthalmology: for young scientists: collection of articles. materials of All-Russia. 2009 Sept:7-11. Russian.

39. Akopova VV. Izuchenie poverhnosti i struktury myagkih kontaktnyh linz s cel’yu sozdaniya oftal’mologicheskoj terapevticheskoj sistemy dostavki lekarstvennogo preparata k tkanyam glaza [Study of the surface and structure of soft contact lenses in order to create an ophthalmologic therapeutic drug delivery system to the eye tissues] Nano- and supramolecular chemistry in sorption and ion-exchange processes. 2010 Sept:9-12. Russian.

40. Zhilyakova ET, Naplekov DK. Izuchenie vozmozhnosti sozdaniya kombinirovannogo lekarstvennogo sredstva dlya lecheniya glaukomy, oslozhnennoj miopiej [Study of the possibility of creating a combined drug for the treatment of glaucoma complicated by myopia] Young Scientist. 2014;19:107-9. Russian.

41. Zhilyakova ET, Novikov OO, Akopova VV, Popov NN, Goncharov IY, Bondarev AV. Issledovanie poverhnosti i morfologii myagkih kontaktnyh linz s cel’yu sozdaniya oftal’mologicheskoj terapevticheskoj sistemy dostavki lekarstvennogo preparata k tkanyam glaza [Study of the surface and morphology of soft contact lenses in order to create an ophthalmological therapeutic system drug delivery to eye tissues] Scientific Bulletin of Belgorod State University. 2010;22(93):73-6. Russian.

42. Beburishvili AG, Zaporotskova IV, Spiridonov EG, Mandrikov VV, Shinkarev RA. O vozmozhnosti sozdaniya novogo lekarstvennogo pokrytiya na poverhnosti biliarnogo stenta [On the possibility of creating a new drug coating on the surface of the biliary stent] Bulletin of Volgograd State Medical University. 2014;2(50):123-30. Russian.

43. Nizaa José E, Castro-Osmaa A. Assessment of doxorubicin delivery devices based on tailored bare polycaprolactone against glioblastoma. International Journal of Pharmaceutics. 2019;558(10):110-9. https://doi.org/10.1016/j.ijpharm.2018.12.079.

44. Grigorieva MV. Polimernye sistemy s kontroliruemym vysvobozhdeniem biologicheski aktivnyh soedinenij [Polymer Systems with Controlled Release of Biologically Active Compounds] Biotechnol. acta. 2011;2:009-23. Russian.

45. Glangchai LC, Caldorera MM, Li Shi Roy K. Nanoimprint lithography based fabrication of shape specific, enzymatically trig gered smart nanoparticles. Journal of Controlled Release. 2008;125:263-72. https://doi.org/10.1016/j.jconrel.2007.10.021.

46. Pengac H, Huangb X, Melleac A. Redox-responsive degradable prodrug nanogels for intracellular drug delivery by crosslinking of amine-functionalized poly(N-vinylpyrrolidone) copolymers. Journal of Colloid and Interface Science. 2019;540:612-622. http://dx.doi.org/10.1016/j.jcis.2019.01.049.

47. Erdoğar N, Akkın S, Bilensoy E. Nanocapsules for Drug Delivery: An Updated Review of the Last Decade. Recent Patents on Drug Delivery & Formulation. 2018;12:252-66. http://dx.doi.org/10.2174/1872211313666190123153711.

48. Mundargi RC, Babu VR, Rangaswamy V. Nano/micro technologies for delivering macromolecular therapeutics using poly (D,L-lactide co glicolide) and its derivatives. Ibid. 2008;125:193-209. http://dx.doi.org/10.1016/j.jconrel.2007.09.013.

49. Grigoriev MV, Gladiore II, Galatenko NA. Cefazolin-filled polyurethane carriers. Ukrainian chemical journal. 2002;68(4):125-7. Ukrainian.

50. Grigorieva MV, Mazur LN, Galatenko NA. Izuchenie svojstv polimernoj kompozicii na osnove setchatogo poliuretana s prolongirovannym antinarkoticheskim dejstviem [Study of the properties of a polymeric composition based on a netted polyurethane with prolonged anti-drug action] Polymer journal. 2004;26(4):254-9. Russian.

51. Blaesi A, Saka N. Microstructural effects in drug release by solid and cellular polymeric dosage forms: A comparative study Materials Science and Engineering. 2017;80(1):715-27.

52. Bajpai AK, Shukla SK, Bhanu S. Responsive polymers in controlled drug delivery. Progr. Polym. Sci. 2008;33:1088-118. https://doi.org/10.1016/j.progpolymsci.2008.07.005.

53. Sosnov AV, Ivanov RV, Balakin KV, Shobolov DL, Fedotov YA, Kalmykov YM. Razrabotka sistem dostavki lekarstvennyh sredstv s primeneniem mikro- i nanochastic [Development of drug delivery systems using micro- and nanoparticles] High-quality clinical practice: new drugs and technologies. 2008;2:4-12. Russian.

54. Malafaya PB, Silva GA, Reis RL. Natural-origin polymers as carriers and scaffolds for biomolecules and cell delivery in tissue engineering applications. Advanced Drug Delivery Reviews. 2007:207-33. https://doi.org/10.1016/j.addr.2007.03.012.

55. Gosudarstvennyj reestr lekarstvennyh sredstv [The state register of medicines] [Electronic resource] Ministry of Health of the Russian Federation. M., 2018. Access mode: http://grls.rosminzdrav.ru.

56. Zhilyakova ET, Bondarev AV. Obzor rossijskih ehnterosorbcionnyh lekarstvennyh sredstvn [Overview of Russian enterosorption drugs] Remedium. Magazine on the market of drugs and medical equipment. 2014;(10):40-47. https://doi.org/10.21518/1561-5936-2014-10-40-47. Russian.