药动学和药效学评价生物制品:挑战与局限性

摘要/Abstract

摘要： 近年来, 重组蛋白多肽和蛋白质已发展成为主流药物。多肽和蛋白类药物在临床前和临床研究以及治疗用药中均占有相当大的比重。理解药物动力学和药效动力学, 包括剂量-浓度-效应之间的关系,对于包括多肽和蛋白类在内的任何药物都是至关重要的, 因为它奠定了优化给药方案和临床合理用药的基础。比起传统的基于小分子的疗法, 多肽和蛋白类药物的药物暴露/效应评价往往由于下列因素而变得复杂:(1) 与内源性多肽、蛋白及营养物质的相似性;(2) 能在分子水平直接参与体内生理过程;(3) 具有高分子特性及免疫原性;(4) 由于存在着很多相似的分子, 目标物的分析和量化具有一定的挑战性。不像传统的小分子药物, 多肽和蛋白质口服后往往没有治疗活性。为选择最适当的给药途径, 需要全面了解多肽和蛋白质理化性质以外的吸收特性, 包括化学和代谢稳定性、吸收部位、免疫反应性、跨膜过程以及主动摄取和外排过程。肽和蛋白质的各种分布特性决定了其在靶器官能否达到适宜浓度从而发挥预期疗效, 而结合现象和受体介导的细胞摄取有可能使这个问题更加复杂化。消除过程作为药物全身暴露的一个关键因素, 可以是众多通路的综合, 包括肾脏及肝脏代谢通路以及广义的蛋白水解作用与受体介导的内吞作用。多肽和蛋白质为基础药物的药代动力学药效学结合研究常因其与内源性物质密切的相互作用以及生理调节反馈机制而错综复杂。本文重点阐述了与大多数生物制品相关的一些主要动力学特性及过程, 为具有药效特性的多肽和蛋白质疗法提供范例。理解了生物疗法和传统小分子药物之间药动学与药效学的差异, 将有助于从事药物研发的科学家以及医疗保健人员在药物开发和应用药物治疗过程中用最适宜的方法去处理、评价和用药。

Abstract: In recent years, biotechnologically-derived peptides and proteins have developed into mainstream therapeutic agents.Peptide and protein drugs now constitute a substantial portion of the compounds under preclinical and clinical development as well as in clinical practice.The understanding of the pharmacokinetics and pharmacodynamics, including the dose-concentration-effect relationship, is crucial to any drug-including peptides and proteins-as it lays the foundation for optimal dosing regimen design and rational clinical application.Compared to traditional small molecule-based therapeutics, pharmacokinetic and exposure/response evaluations for peptide and protein therapeutics are frequently complicated by their similarity to endogenous peptides and proteins as well as nutrients, by their intimate involvement in physiologic processes on the molecular level, by their macromolecule character and immunogenicity, and by analytical challenges to identify and quantify them in the presence of a myriad of similar molecules.Peptides and proteins, unlike conventional small molecule drugs, are generally not therapeutically active upon oral administration, and selection of the most appropriate route of administration requires comprehensive knowledge of their absorption characteristics beyond physicochemical properties, including chemical and metabolic stability at the absorption site, immunoreactivity, passage through biomembranes, and active uptake and exsorption processes.Various distribution properties dictate whether peptide and protein therapeutics can reach optimum target site exposure in order to exert the intended pharmacological response.Binding phenomena and receptor-mediated cellular uptake may further complicate this issue.Elimination processes-a critical determinant for the drug' s systemic exposure-may follow a combination of numerous pathways, including renal and hepatic metabolism routes as well as generalized proteolysis and receptor-mediated endocytosis. Pharmacokinetic/pharmacodynamic (PK/PD) correlations for peptide and protein-based drugs are frequently convoluted by their close interaction with endogenous substances and physiologic regulatory feedback mechanisms.
The manuscript highlights some of the major pharmacokinetic properties and processes relevant for the majority of biologics and will provide examples of well characterized pharmacodynamic relationships for peptide and protein therapeutics.Appreciation of the pharmacokinetic and pharmacodynamic differences between therapeutic biologics and traditional small molecule drugs will empower the drug development scientist as well as the healthcare provider to handle, evaluate and apply these compounds in an optimal fashion during the drug development process as well as in applied pharmacotherapy

Key words: Pharmacokinetics, pharmacodynamics, biologics, drug development, peptides, proteins

. 药动学和药效学评价生物制品:挑战与局限性[J]. 中国临床药理学与治疗学, 2007, 12(10): 1089-1098.

Bernd Meibohm. Pharmacokinetic and pharmacodynamic evaluation of biologics:challenges and pitfalls[J]. Chinese Journal of Clinical Pharmacology and Therapeutics, 2007, 12(10): 1089-1098.

参考文献

1 Meibohm B, Derendorf H.Basic concepts of pharmacokinetic/pharmacodynamic (PK/PD) modelling[J].Int J Clin Pharmacol Ther, 1997;35:401-413.
2 Levy G.Kinetics of drug action:an overview[J].J Allergy Clin Immunol, 1986;78:754-761.
3 Meibohm B, Derendorf H.Pharmacokinetic/pharmacodynamic studies in drug product development[J].J Pharm Sci, 2002; 91:18-31.
4 Holford NH, Sheiner LB.Kinetics of pharmacologic response [J].Pharmacol Ther, 1982;16:143-166.
5 CDER/FDA.Exposure Response Relationships:Guidance for Industry[S].US Department of Health and Human Services, Food and Drug Administration, Center for Drug Evaluation and Research:Rockville.2003.
6 International Conferenceon Harmonization, ICH E4.Dose-response information to support drug registration[S].1994, London:European Agency for the Evaluation of Medicinal Products.
7 Ferraiolo BL, Mohler MA, Gloff CA.Protein pharmacokinetics and metabolism[M].New York:Plenum Press.1992.
8 Meibohm B.Pharmacokinetics and pharmacodynamics of biotech drugs[M].Weinheim:Wiley.2006.
9 Meibohm B, Braeckman RA.Pharmacokinetics and pharmacodynamics of peptide and protein drugs, in pharmaceutical biotechnology[A].In:D.J.A.Crommelin, R.D.Sindelar, B. Meibohm, eds.3rd edition.New York:Informa Healthcare. 2007:95-123.
10 Tabrizi M, Roskos LK.Exposure-reponse relationships for therapeutic biologics, in pharmacokinetics and pharmacodynamics of biotech drugs[A].In:B.Meibohm, ed.Wiley:Weinheim, 2006:295-330.
11 Tang L, Persky AM, Hochhaus G, et al. Pharmacokinetic aspects of biotechnology products[J].J Pharm Sci, 2004;93: 2184-2204.
12 Meibohm B, Derendorf H.Pharmacokinetics and pharmacodynamics of biotech drugs[A].In:O Kayser, R Muller, eds.Pharmaceutical biotechnology:Drug discovery and clinical applications[M].Weinheim:Wiley, 2004:141-166.
13 Herbst RS, Langer CJ.Epidermal growth factor receptors as a target for cancer treatment:the emerging role of IMC-C225 in the treatment of lung and head and neck cancers[J].Semin Oncol, 2002;29:27-36.
14 Shen WC.Oral peptide and protein delivery:unfulfilled promises[J] ? Drug Discov Today, 2003;8:607-608.
15 Fasano A.Novel approaches for oral delivery of macromolecules [J].J Pharm Sci, 1998;87:1351-1356.
16 Porter CJ, Charman SA.Lymphatic transport of proteins after subcutaneous administration[J].J Pharm Sci, 2000;89:297-310.
17 Supersaxo A, Hein WR, Steffen H.Effect of molecular weight on the lymphatic absorption of water-soluble compounds following subcutaneous administration[J].Pharm Res, 1990;7:167-169.
18 Zito SW.Pharmaceutical biotechnology:a programmed text [M].Lancaster, PA:Technomic Pub.Co.1997.
19 Flessner MF, Lofthouse J, Zakaria el R.In vivo diffusion of immunoglobulin G in muscle:effects of binding, solute exclusion, and lymphatic removal[J].Am J Physiol, 1997;273: H2783-H2793.
20 Reddy ST, Berk DA, Jain RK, et al. A sensitive in vivo model for quantifying interstitial convective transport of injected macromolecules and nanoparticles[J].J Appl Physiol, 2006; 101:1162-1169.
21 Colburn W.Peptide, peptoid, and protein pharmacokinetics pharmacodynamics[A].In:P.Garzone, W.Colburn, M. Mokotoff, eds.Petides, peptoids, and proteins[M].Cincinnati, OH:Harvey Whitney Books 1991:94-115.
22 Kageyama S, Yamamoto H, Nakazawa H, et al. Pharmacokinetics and pharmacodynamics of AJW200, a humanized monoclonal antibody to von Willebrand factor, in monkeys[J].Arterioscler Thromb Vasc Biol, 2002;22:187-192.
23 Straughn AB.Limitations of noncompartmental pharmacokinetic analysis of biotech drugs[A].In:B.Meibohm, ed.Pharmacokinetics and pharmacodynamics of biotech drugs[M].Weinheim: Wiley, 2006:181-188.
24 Straughn AB.Model-independent steady-state volume of distribution[J].J Pharm Sci, 1982;71:597-598.
25 Perrier D, Mayersohn M.Noncompartmental determination of the steady-state volume of distribution for any mode of administration[J].J Pharm Sci, 1982;71:372-373.
26 Toon S.The relevance of pharmacokinetics in the development of biotechnology products[J].Eur J Drug Metab Pharmacokinet, 1996;21:93-103.
27 Maack T, Park C, Camargo M.Renal filtration, transport and metabolism of proteins[A].In:D.Seldin, G Giebisch, eds. The kidney[M].New York:Raven Press, 1985:1773-1803.
28 Wills RJ, Ferraiolo BL.The role of pharmacokinetics in the development of biotechnologically derived agents[J].Clin Pharmacokinet, 1992;23:406-414.
29 Meibohm B.Pharmacokinetics of Protein-and Nucleotide-Based Drugs[A].In:R.I.Mahato, ed.Biomaterials for delivery and targeting of proteins and nucleic acids[M].Boca Raton:CRC Press, 2004:275-294.
30 Levy G.Pharmacologic target-mediated drug disposition[J]. Clin Pharmacol Ther, 1994;56:248-252.
31 Mager DE.Target-mediated drug disposition and dynamics[J]. Biochem Pharmacol, 2006;72:1-10.
32 Bartocci A, Mastrogiannis DS, Migliorati G, et al. Macrophages specifically regulate the concentration of their own growth factor in the circulation[J].Proc Natl Acad Sci USA, 1987; 84:6179-6183.
33 Bauer RJ, Gibbons JA, Bell DP, et al. Nonlinear pharmacokinetics of recombinant human macrophage colony-stimulating factor (M-CSF) in rats[J].J Pharmacol Exp Ther, 1994;268: 152-158.
34 Schellekens H, Jiskoot W.Immunogenicity of therapeutic proteins[A].In:D.J.A.Crommelin, R.D.Sindelar, B.Meibohm, eds.Pharmaceutical biotechnology [M].3rd edition. New York:Informa Healthcare, 2007:125-132.
35 Batra SK, Jain M, Wittel UA, et al Pharmacokinetics and biodistribution of genetically engineered antibodies[J].Curr Opin Biotechnol, 2002;13:603-608.
36 Derendorf H, Meibohm B.Modeling of pharmacokinetic pharmacodynamic (PK/PD) relationships:concepts and perspectives [J].Pharm Res, 1999;16:176-185.
37 Mager DE, Wyska E, Jusko WJ.Diversity of mechanism-based pharmacodynamic models[J].Drug Metab Dispos, 2003;31: 510-518.
38 Lesko LJ.Paving the critical path:how can clinical pharmacology help achieve the vision[J] ? Clin Pharmacol Ther, 2007; 81:170-177.
39 Levy G.Mechanism-based pharmacodynamic modeling [J]. Clin Pharmacol Ther, 1994;56:356-358.
40 Racine-Poon A, Botta L, Chang TW, et al. Efficacy, pharmacodynamics, and pharmacokinetics of CGP 51901, an anti-immunoglobulin E chimeric monoclonal antibody, in patients with seasonal allergic rhinitis[J].Clin Pharmacol Ther, 1997;62: 675-690.
41 Radwanski E, Chakraborty A, Van Wart S, et al. Pharmacokinetics and leukocyte responses of recombinant human interleukin-10[J].Pharm Res, 1998;15:1895-1901.
42 Perez-Ruixo JJ, Kimko HC, Chow AT, et al. Population cell life span models for effects of drugs following indirect mechanisms of action[J].J Pharmacokinet Pharmacodyn, 2005;32: 767-793.
43 Agoram B, Heatherington AC, Gastonguay MR.Development and evaluation of a population pharmacokinetic-pharmacodynamic model of darbepoetin alfa in patients with nonmyeloid malignancies undergoing multicycle chemotherapy[J].Aaps J, 2006;8:E552-E563.
44 Ramakrishnan R, Cheung WK, Wacholtz MC, et al. Pharmacokinetic and pharmacodynamic modeling of recombinant human erythropoietin after single and multiple doses in healthy volunteers[J].J Clin Pharmacol, 2004;44:991-1002.
45 Mahmood I.Interspecies scaling of protein drugs:Prediction of clearance from animals to humans[J].J Pharm Sci, 2004;93: 177-185.
46 Breimer DD, Danhof M.Relevance of the application of pharmacokinetic-pharmacodynamic modelling concepts in drug development. The “wooden shoe” paradigm[J].Clin Pharmacokinet, 1997;32:259-267.
47 Machado SG, Miller R, Hu C.A regulatory perspective on pharmacokinetic/pharmacodynamic modelling[J].Stat Methods Med Res, 1999;8:217-245.
48 Lesko LJ, RowlandM, Peck CC, et al. Optimizing the science of drug development:opportunities for better candidate selection and accelerated evaluation in humans[J].J Clin Pharmacol, 2000;40:803-814.
49 Sheiner LB, Steimer JL.Pharmacokinetic/pharmacodynamic modeling in drug development[J].Annu Rev Pharmacol Toxicol, 2000;40:67-95.