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In the last ten years, computer science and technology have advanced significantly, impacting every part of our lives. Since the late 1990s, computational biology has grown to play a significant role in the area of biology's new technologies. Scientists are now able to obtain structural information with greater detail thanks to advances in computer hardware development, such as the introduction of supercomputers and the programming language for computational biology. This information is crucial for understanding the various functions and mechanisms of biological molecules, but it also holds the key to the development of molecules with new or improved functions.
B lymphocytes create the binding proteins known as antibodies to protect an organism from infections and foreign macromolecules. They are frequently utilized as medicinal medicines, diagnostic tools, and research tools. Antibody molecules are distinguished by their extreme diversity and recognition specificity. The development of phage display technology has made it possible to choose antibodies to any antigen with a suitable binding affinity, but antibody characteristics still need to be further improved for their application, particularly for therapy. When accessible, finely tuned antibody structures, including the structure of the antibody-antigen complex, are particularly helpful for designing and engineering antibodies. Key phases of antibody creation are detailed in our PreciAb™ Platform.
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