Biodizine as a civilizational challenge of modern pharmaceuticals

Alexander I. Tyukavin; Тюкавин Александр Иванович; Nikolay  А.  Arseniev; Арсениев Николай  Анатольевич; Maria A. Studneva; Студнева Мария Александровна; Veronika S. Medvedeva; Медведева Вероника  Сергеевна; Sergey V. Suchkov; Сучков Сергей Викторович

doi:10.17816/phf99672

Biodizine as a civilizational challenge of modern pharmaceuticals

作者: Tyukavin A.I.¹, Arseniev N.А.¹, Studneva M.A.²^,3, Medvedeva V.S.⁴, Suchkov S.V.²^,5^,3
隶属关系:
1. Saint Petersburg State Chemical and Pharmaceutical University
2. Moscow State University of Food Production
3. European Association for Predictive, Preventive and Personalized Medicine, EU
4. I.M. Sechenov First Moscow State Medical University (Sechenov University)
5. A. I. Yevdokimov Moscow State University of Medicine and Dentistry
期: 卷 3, 编号 4 (2021)
页面: 108-117
栏目: Actual problems: discussion tribune
URL: https://bakhtiniada.ru/PharmForm/article/view/99672
DOI: https://doi.org/10.17816/phf99672
ID: 99672

如何引用文章

全文:

详细
全文:
作者简介
参考
补充文件
统计

详细

The review discusses the role of pharmaceutical and drug design methodology in the development of the high-tech segment of the development and production of original drugs for personalized and precision medicine (PPM). Topical issues of using predictively personalized tools for precision medicine in pharmaceuticals are highlighted. New opportunities and prospects for increasing the effectiveness of drugs in various fields of medicine created on the basis of pharmaceutical design are shown. Discussed are original approaches to standardization and reproducibility of the effects of new drugs at the preclinical stage using microfluidic bioconstructs – organ-on-a-chip systems. The relevance of improving university curricula for training specialists in the field of molecular drug design (drug design), harmonized with dynamically developing biotechnologies in pharmaceuticals, as well as the needs of domestic healthcare in original medicines for PPM, is shown.

关键词

biopharmaceuticals, pharmdesign, personalized medicines, pharmaceutical design of preclinical studies, organ-on-a-chip system, training programs for drug- and pharmaceutical designers

全文:

##article.viewOnOriginalSite##

作者简介

Alexander Tyukavin

Saint Petersburg State Chemical and Pharmaceutical University

Email: alexander.tukavin@pharminnotech.com
SPIN 代码: 8476-5366

Doctor of Medicine (MD), Professor, Head of the Department to Physiology and Pathology

俄罗斯联邦, Saint Petersburg

Nikolay Arseniev

Saint Petersburg State Chemical and Pharmaceutical University

Email: nikolay.arseniev@pharminnotech.com
SPIN 代码: 9038-7623

Ph.D in Biology, Associate Professor of the Department to Physiology and Pathology

俄罗斯联邦, Saint Petersburg

Maria Studneva

Moscow State University of Food Production; European Association for Predictive, Preventive and Personalized Medicine, EU

Email: maria.studneva@gmail.com

Assistant of the Department to Personalized Medicine, Precision Nutrition and Biodesign

俄罗斯联邦, Moscow; Brussels

Veronika Medvedeva

I.M. Sechenov First Moscow State Medical University (Sechenov University)

Email: med_nika2000@mail.ru

Student

俄罗斯联邦, Moscow

Sergey Suchkov

Moscow State University of Food Production; A. I. Yevdokimov Moscow State University of Medicine and Dentistry; European Association for Predictive, Preventive and Personalized Medicine, EU

编辑信件的主要联系方式.
Email: ssuchkov57@gmail.com
SPIN 代码: 7052-7335

Doctor of Medicine (MD), Professor, Head of the Department to Personalized Medicine, Professor of the Department of Clinical Allergology and Immunology

俄罗斯联邦, Moscow; Moscow; Brussels

参考

Suchkova S. V., ed. Osnovy personalizirovannoj i precizionnoj mediciny. Uchebnik dlja medicinskih vuzov i fakul’tetov Kazan: ID MedDok; 2021. 628 p. (In Russ.).
Tyukavin A. I., ed. Patologija: uchebnik. Moscow: INFRA-M; 2021. 844 p. (In Russ.).
Chaplenko A. A., Vlasov V. V., Gildeeva G. N. Innovative medicines on the Russian pharmaceutical market: key players and main directions of development. Remedium. 2020;(10):4–9. https://doi.org/10.21518/1561-5936-2020-10-4-9 (In Russ.).
The Pharma Media: BioMedTracker and Cortellis databases.
Okminyan G. F., Latyshev O. Yu., Kiseleva E. V., et al. Basal insulin evolution: from simple to more complex. Endokrinologiya: novosti, mneniya, obuchenie = Endocrinology: News, Opinions, Training. 2021;10(1):18–25. https://doi.org/10.33029/2304-9529-2021-10-1-18-25 (In Russ.).
Dedov I. I., Peterkova V. A., Kuraeva T. L., et al. Insulinovaja pompa (pomoshh’ vrachu dlja jeffektivnogo upravlenija diabetom. Moscow; 2014. 126 p.
Green A., Silver P., Collins J., et al. Toehold Switches: De-Novo-Designed Regulators of Gene Expression. Cell. 2014;159(4):925–939. http://dx.doi.org/10.1016/j.cell.2014.10.002
Belousov K. I., Evtrapov A. A., Kuhtevich I. V., et al. Osnovy nanotehnologij. Chast’ 2. Kapel’naja mikrofljuidika. Uchebnoe posobie. Saint Petersburg: ITMO University; 2015. 56 p.
Afonicheva P. K., Bulyanitsa A. L., Evstrapov A. A. «Organ-on-a-chip» – materials and methods of creation. Nauchnoe priborostroenie = Scientific Instrumentation. 2019;29(4):3–18.
Gijzen L., Marescotti D., Raineri E., et. al. An Intestine-on-a-Chip Model of Plug-and-Play Modularity to Study Inflammatory Processe. SLAS TECHNOLOGY: Translating Life Sciences Innovation. 2020;25(6):585–597. https://doi.org/10.1177/2472630320924999

补充文件

附件文件

动作

1. JATS XML

下载

2. Fig. 1. Various concepts at the intersection of sciences

下载 (1MB)

索引源数据

3. Fig. 2. The share of original drugs in the total number of drugs registered in the Russian Federation in the period from 2010 to 2019 [3]

下载 (1MB)

索引源数据

4. Fig. 3. The number of drugs with a new active ingredient, registered in the Russian Federation, developed by domestic researchers [3]

下载 (889KB)

索引源数据

5. Fig. 4. Normal physiological insulin secretion

下载 (1001KB)

索引源数据

6. Fig. 5. Insulin pump (electronic syringe). On the left is a diagram of the insulin injector device. On the right is the location of the device on the human body. 1 – pump with reservoir; 2 – infusion system; 3 – cannula / catheter [6]

下载 (1MB)

索引源数据

7. Fig. 6. Dynamics of the average annual growth rates of design translational developments in the bioindustry

下载 (973KB)

索引源数据

8. Fig. 7. Scheme of the effect of the targeted effect of eToeholds. 5 – viral protein of the pathogen [7]

下载 (1MB)

索引源数据

9. Fig. 8. «Backpacks» of nanoparticles (pink - left; purple - right) attached to the macrophage cell release a steady stream of cytokines to keep the cell activated against cancerous tumors. Source: Wyss Institute at Harvard University

下载 (1MB)

索引源数据

10. Fig. 9. System for obtaining nanosized vesicles for transportation of biological products in the human body with parenteral and minimally invasive methods of administration. Source: Wyss Institute and John A. Paulson Harvard School of Engineering and Applied Sciences

下载 (1MB)

索引源数据

11. Fig. 10. Microfluidic drug testing devices

下载 (1MB)

索引源数据

12. Fig. 11. The Man-on-Chip Model

下载 (1MB)

索引源数据

13. Fig. 12. Modeling of cystic fibrosis. Left - light-on-a-chip system; on the right is a cystic fibrosis-on-a-chip model. Source: Wyss Institute at Harvard University

下载 (1MB)

索引源数据

14. Fig. 13. Diagram of the intestine-on-a-chip construction. Source: Wyss Institute at Harvard University

下载 (1MB)

索引源数据

15. Fig. 14. Micro device for monitoring hemostasis. Source: Wyss Institute at Harvard University

下载 (1MB)

索引源数据

用户名
密码
记住我

忘记您的密码?	注册

用户名
密码
记住我

忘记您的密码?	注册