市场调查报告书
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1262031
液体处理市场 - 全球行业规模、份额、趋势、竞争、机会、预测,2018-2028 年,按类型、产品、应用、最终用户、地区划分Liquid Handling Market- Global Industry Size, Share, Trends, Competition, Opportunities and Forecast, 2018-2028F Segmented by Type, Product, Application, End-User, By Region |
由于液体处理系统的进步,液体处理市场预计在预测期内将会增长。 液体处理设计主要用于临床分析、高通量筛选和敏感取样。 液体处理系统改进和设计的重大进步极大地扩展了以更快的速度、更高的可靠性和效率筛选大量化学品的能力。 这些发展趋势是小型化,主要是为了降低成本和提高产量。 在这种现代化趋势中,正在创建液体处理系统,根据药物开发每个步骤的目的,充分利用各种技术。
液体处理系统的下一步是部署人工智能来管理流程的各个阶段,并充分利用互联网连接与用户进行远程通信。 在多功能液体处理自动化工作站的帮助下,可以自动完成液体样品的大部分取样、组合和混合。 嵌入在自动液体处理系统中的软件能够进行高级错误管理,并且可以依靠机器学习使仪器活动适应样品处理过程中可能出现的新条件(例如,对堵塞喷嘴的补偿和对一次性吸头缺陷的反应等。 ). 这些工作站是自我管理的,可以实时向远程操作员报告问题并概述对问题的响应,使其成为实验室资源优化的有效解决方案。 液体处理系统常用的软件包括 Biomek 自动化工作站上的 Biomek 软件和 Echo 软件应用程序,它允许为特定应用程序创建液体处理协议,只需最少的培训。
自主学习软件的开发还促进了各种组件的集成,使实验室能够从自动化工作流程中添加或删除特定功能的组件。 模块化增加了整个系统的通用性,扩大了生物医学实验室自动化液体处理设备的应用范围。
液体处理机用于对药理物质进行 ADMET 分析,这些分析有助于表征吸收、分布、代谢、排洩和毒性。 ADMET 试验提供了关于药物如何与人体相互作用的深入知识,该数据概况对于是否进行或停止未来药物研究的决策过程非常重要。
Tecan Group AG 等公司自 1980 年代以来一直从事液体处理系统的製造业务,如今,为了方便他们的工作并提高准确性,他们製造了带有多个点胶头的移动液体处理系统。我们还致力于通过提供带有液体处理臂的新型改进液体处理系统来改进我们的技术。 为了在药物发现的早期阶段加强 ADME(吸收、分布、代谢和排洩)筛选,Tecan 开发了多种自动化筛选方法。 这些平台自动化细胞渗透性、药物溶解度、体外药物代谢、蛋白质结合研究和化合物表征任务,并基于高度适应性和可扩展的液体处理平台。 这允许集成 Tecan 多模式读取器,以实现具有完整样本跟踪的无人值守处理。
如果液体处理设备变得更受欢迎,实验可能会变得更容易。 这种方法最初被公司和工业实验室采用,但后来传播到可以进行各种非常规实验的学术环境。 在当前的实验中,研究人员移动液体用于稀释、混合和接种等目的,以进行进一步的实验。 液体处理系统的远程控制使它们能够以更稳健和更有弹性的方式运行,以应对阻碍工作或增加污染可能性的外部影响。
根据市场数据,TechSci Research 根据公司的具体需求提供定制服务。 该报告可以定制为:
Liquid Handling Market is estimated to grow during the forecast year owing to the advancement in liquid handling systems. Liquid handling designs are mostly used in clinical analysis, high-throughput screening, and delicate sampling. The capacity to screen large collections of chemicals at a faster rate with better reliability and efficiency has been greatly expanded due to the significant advancements in the modification and designing of liquid handling systems. These developments tend toward miniaturization, largely in an effort to lower costs and boost throughput. With the approaching modernization, a variety of fluid handlers that use various technologies for specific purposes have been created for each step of the drug development process.
Many different types of liquid handlers can be used as stand-alone parts by operating separately from any other machinery. These liquid handling devices are typically built into bigger stations, which simplify regular activities, minimize human involvement, and enable multitasking in a single run. These liquid handling systems can be small workstations with specialized functions or completely automated robotic decks with the ability to carry out an endless variety of operations. In recent years, academic research in the United States has become significantly more interested in high-throughput screening technology. The Society for Biomolecular Sciences in the US maintains an extensive listing of academic screening facilities. It not only gives the academic community high-throughput screening (HTS) materials but also aids in the search for probes and leads for drug discovery.
In the pharmaceutical sector, high-throughput screening techniques are widely employed to quickly examine the biological or biochemical activity of many compounds, typically pharmaceuticals. The liquid handling techniques make use of robotics and automation because they speed up target analysis since vast compound libraries can be swiftly and affordably screened. High-throughput screening (HTS) is a helpful tool for evaluating things like pharmacological targets, agonists, antagonists' receptors (such as GPCRs), and enzymes.
Liquid Handling in Clinical Research and Drug Development will Support the Global Liquid Handling Market.
Basically, the use of liquid handling technology is done to precisely dispense small volumes for miniaturized drug screens. A simple pipet to a sophisticated workstation is an example of liquid handling equipment used in the development of pharmaceuticals. Micropipettes, pipettes, dispensers, and burettes are among the more suitable and efficient liquid-handling tools for drug research. These are essential because instruments used for handling liquids are very flexible. They can help in the movement of cells, proteins, oligonucleotides, or other biological components and are utilized for a range of purposes, including pipetting, transferring, diluting, dosing, and dispensing. The equipment's high throughput, capacity, and dynamic volume range enable this tremendous flexibility.
Earlier, liquid handling equipment was proven inefficient at lowering the cost of quality control procedures due to the lack of appropriate technology. But now, the high precision capabilities of liquid handling instruments are helping to ensure the reliability of clinical research results' accuracy.
The implementation of artificial intelligence to manage various phases of the procedure and to fully utilize internet connectivity to communicate with users remotely are the next steps for liquid handling systems. The majority of the sampling, combining, and mixing of liquid samples can be done automatically with the help of multipurpose liquid handling automated workstations. The in-built software in the automated liquid handling system is able to provide high degrees of error management and adapt the instrument's activity to novel conditions that may arise during sample processing by relying on machine learning (e.g., compensating for nozzle clogging or reacting to a defect in a disposable tip). These workstations are self-managed and represent efficient walk-away solutions for the optimization of laboratory resources by reporting problems in real-time to remote operators and outlining their reaction to the issue. Some of the widely used software u in liquid handling systems include Biomek Software in Biomek Automated Workstations and Echo Software Applications which can create liquid handling protocols for specific applications with a minimum requirement of training.
The creation of self-learning software will also make it easier to integrate various components, enabling labs to add or delete particularly functional components from an automated workflow. Modularity will, thus, boost the system's overall versatility and enable a wider range of applications for automated liquid handling equipment in biomedical laboratories.
Liquid handlers are used to put pharmacological substances through ADMET assays, which are useful for determining features of absorption, distribution, metabolism, excretion, and toxicity. In-depth knowledge about how drugs interact with the human body is provided by ADMET testing, and this data profile is crucial in the decision-making process to carry out or halt any future medication research.
Companies like Tecan Group AG have been in the business of manufacturing liquid handling systems since the 1980s, which is now also enhancing its technology by providing a new modified liquid handling system that has a movable liquid handler arm with multiple dispense tips to ease the work and enhance accuracy. To enhance ADME (Absorption, Distribution, Metabolism, and Excretion) screening in the early stages of drug discovery, Tecan has developed a variety of automated screening methods. These platforms, for automated cell permeability, drug solubility, in vitro drug metabolism, protein binding tests, and compound characterization operations, are based on adaptable and scalable liquid handling platforms. By this, the Tecan multimode readers can be integrated to enable walkaway processing with complete sample tracking.
It may be easier to conduct experiments if liquid handling devices are more widely used. The method was initially embraced by companies and industry-based laboratories, but it has since spread to academic settings where a wide range of unconventional/unusual experiments can be conducted. According to current procedures or laboratory tests, researchers transfer liquids for the purpose of dilution, mixing, or inoculation to carry out the experimentation further. By operating the liquid handling systems remotely, operations can be performed more robustly and in a resilient way against outside influences which can hamper the work or can increase the chances of contamination; it can also help in carrying out more tests at a time which was seen during the time of COVID-19 pandemic for rapid antigen testing thus, liquid handling system can make laboratories more efficient.
The Global Liquid Handling Market is segmented based on Type, Product, Application, End User, Region, and Company. Based on Type, the market is trifurcated into Manual Liquid Handling, Automated Liquid Handling, and Semi-Automated Liquid Handling. Based on the Product, the market is segmented among Automated Workstations, Pipettes, Dispensers, Burettes, and Others. Based on the Application, the market is divided among Drug Discovery, Cancer and Genomics Research, Clinical Diagnostics, and Others. Based on the End User, the market is divided into the Pharmaceutical and Biotechnology Industry, Contract Research Organizations, Academic Institutes, and Others.
Agilent Technologies, Aurora Biomed, Inc., AUTOGEN, INC., Danaher Corporation, BioTek Instruments, Inc., Analytik Jena AG, Corning Incorporated, Eppendorf AG, Formulatrix, Inc., Gilson, Inc. are among the major market players operating in the Global Liquid Handling market.
In this report, Global Liquid Handling Market has been segmented into the following categories, in addition to the industry trends, which have also been detailed below:
Company Profiles: Detailed analysis of the major companies present in Global Liquid Handling.
With the given market data, TechSci Research offers customizations according to a company's specific needs. The following customization options are available for the report: