The Global Robotic Arms in Laboratories market is valued at USD XX. XX billion in 2016 and is expected to reach a value of USD XX. XX billion by the end of 2022, growing at a projected CAGR of XX. XX % during the forecast period of 2017 – 2022. In research laboratories, applications that require flexibility, efficient use of space and seamless integration of lab peripherals are increasing adopting the use of robotic arms. The adoption has grown over the years with increased ease in programming the arms. Typical tasks performed by these robots are preparing samples, operating analytical equipment and handling sample material.
Automation of routine laboratory procedures, by the use of dedicated work stations and software to program instruments, allows associate scientists and technicians to think creatively about the implications of their experiments and to design effective follow-up projects or develop alternative approaches to their work instead of spending their days repeating tedious tasks.
Apart from reducing mundane tasks, the market for laboratory automation is also driven by the need for consistency in quality. Because the cost of an error is very high in a scientific paper or developing a drug, even fairly low error rates can have a profound impact on the conclusions you make downstream.
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It is believed that taking out the human element helps in achieving more consistency. Great advances have been made in the molding of plastics that has reduced the volumes of reagents used and enabled handling of smaller liquid volumes easy. These advancements have worked in favor of the development of micro and nano-litre plates to fit in with the automated liquid handling equipment.
Validation and data quality play a major role in modern life science. Legal validation, patents, and clinical testing have become crucial issues. Automation enables a much higher reproducibility and better documentation of data. This allows the production of more data points with great ease. It also ensures the safety of personnel in the presence of infectious or potentially hazardous material.
Automation is used in a wide variety of life science applications ranging from proteomics to systems biology. Automation is a dominant feature in the diagnostics market followed by the discovery and research labs. In clinical diagnostics, where profits are based on the number of
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