Automated liquid handling systems are designed to perform multiple tasks in laboratories, such as sampling, mixing, and combining liquid samples automatically. The system helps eliminate sample contamination, as well as reduce manual work of laboratory personnel by performing various laboratory tasks. Moreover, automated liquid handling systems are able to add reagents, measure samples, and ensures uniform liquid addition to bioassays. The system helps minimize processing time by eliminating laboratory errors. These workspaces vary in the amount of samples that can be handled and a variety of integrated software are available to maintain the footprint of work performed by automated fluid handling systems.
Pipettes & Consumables; automated liquid handling systems are being widely used around the world in laboratories across the different scientific disciplines. Liquid handling systems enable the handling of chemical compounds with high precision. They help in the efficient transport and storage of substances. Pipettes are usually used for the transportation and storage of small amounts of chemicals like liquids and solvents. Pipettes and other related equipment are also used for the transportation and storage of large volumes of chemicals like gases, which requires high-pressure refrigeration. The piping of liquid handling systems are generally available as integral part of an automated system and are operated by remote control.
Automated liquid handling systems are also being essential to speed up the production of many complicated, multi-parameter experiments in a robust, reproducible, and repeatable way, while freeing highly skilled scientists from lab-work to concentrate on more specialized tasks, such as the analysis of experimental data and drafting of experimental plans. There are a wide range of applications of automated liquid handling systems in various research domains. They are used for the preparation of reagents, for the transportation and storage of reagents, and for the transfer of reagents from one container to another, while assuring the controlled exposure of reagents to hazardous conditions. Some of the well-known popular applications include the development of reagents in the wide-ranging biological sciences, manufacture of solid dose vaccines, and assays for the evaluation of samples from dangerous diseases such as anthrax.
Another prominent area where automated liquid handling systems are extensively used is the drug discovery and drug delivery field. Pharmaceutical companies engaged in the discovery of important new agents for the treatment of crucial diseases are now leveraging these systems to automate the processes involved in the discovery process and to speed up the process of drug delivery to the clinics. This has made possible the design of improved and more efficient drug manufacturing processes, with the help of throughput capacity.
The throughput capacity refers to the number of samples that can be processed per hour. Higher throughput means faster processing and greater cost effectiveness. It also helps in speeding up the process of drug discovery. Another important application of automated liquid handling technology is in the field of therapeutic drug delivery. By leveraging these high-throughput automated systems, manufacturers and suppliers can process a much higher volume of pharmaceuticals at lower costs and improve their service quality, while achieving greater organizational flexibility and productivity.
Pharmaceutical companies are constantly striving to accelerate the rate of growth of their business. To achieve this, they often depend on highly skilled employees who possess both knowledge and skill sets. However, due to the tremendous workload and the time constraints of such tasks, it often leads to organizational dysfunction, increased stress levels, as well as a reduction in efficiency. To overcome these obstacles, pharmaceutical companies require automated liquid handling systems that will not only speed up the process of workflow, but also make the workflow more robust and more effective.
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