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单克隆抗体的技术进展。

Technological Advancements in Monoclonal Antibodies.

机构信息

University Center SENAI/CIMATEC, National Service of Industrial Learning-SENAI, Salvador, Bahia, Brazil.

SENAI Institute of Innovation (ISI) in Advanced Health Systems (CIMATEC ISI SAS), University Center SENAI/CIMATEC, National Service of Industrial Learning-SENAI, Salvador, Bahia, Brazil.

出版信息

ScientificWorldJournal. 2021 Feb 10;2021:6663708. doi: 10.1155/2021/6663708. eCollection 2021.

DOI:10.1155/2021/6663708
PMID:33628140
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7892242/
Abstract

Biopharmaceuticals are innovative solutions that have revolutionized the treatment of important chronic diseases and malignancies. The approval of biosimilar products has become a complex and balanced process, and there are versions of drugs with established biosimilarity that can offer a more accessible treatment option to patients. The objective of this work was to identify the advancement of these technologies by means of patent and article analysis based on technological and scientific prospection. In patent document recovery, Derwent Innovation Index (DWPI) and PatentInspiration databases were used. The research was based on the search of the selected terms in the title, summary, and claims of the documents through a search strategy containing IPC code and keywords. In articles recovery, the Web of Science tool was used in the search of scientific publications dated from the last 5 years. The search resulted in a total of 2295 individual patent documents and 467 families using DWPI database, 769 individual patents and 205 families using PatentInspiration, and 2602 articles using Web of Science database. Additionally, this work describes the number of organizations that contribute to this area, where they are, how much development they have undergone, and the inventors/authors involved. Based on the number of publications registered, there is an important prominence for scientific research in mAbs. In terms of innovation, it is expected that several therapeutic drugs are already under regulatory review, which will allow drugs to be approved over the next few years and will thus generate a continuous flow of new products based on immunotherapies, mAbs, and biosimilar drugs. These drugs have become essential weapons for the treatment of significant diseases, and the increasing trend in the number of related scientific and technological publications contributes to making these therapies available to the greatest number of people.

摘要

生物制药是创新解决方案,彻底改变了重要慢性病和恶性肿瘤的治疗方式。生物类似药的批准已成为一个复杂而平衡的过程,已有具有明确生物类似性的药物版本,可以为患者提供更可及的治疗选择。本工作的目的是通过基于技术和科学展望的专利和文章分析来确定这些技术的进展。在专利文献检索中,使用了德温特创新索引(DWPI)和 PatentInspiration 数据库。研究基于通过包含 IPC 代码和关键词的搜索策略,在标题、摘要和权利要求中搜索选定术语,从专利文献中检索。在文章检索中,使用 Web of Science 工具在过去 5 年中检索科学出版物。检索结果为 DWPI 数据库共检索到 2295 份专利文献和 467 个专利家族,PatentInspiration 检索到 769 份专利和 205 个专利家族,Web of Science 数据库检索到 2602 篇文章。此外,本文还描述了对此领域做出贡献的组织数量、它们的位置、发展程度以及涉及的发明人/作者。根据登记的出版物数量,单克隆抗体(mAbs)的科学研究具有重要的突出地位。在创新方面,预计已有若干治疗药物正在接受监管审查,这将允许在未来几年内批准这些药物,从而基于免疫疗法、mAbs 和生物类似药产生源源不断的新产品。这些药物已成为治疗重大疾病的重要武器,相关科学和技术出版物数量的增加有助于使这些疗法为更多人所用。

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