As scientists discover new levels of understanding in the physical world, these innovators develop new and exciting ways to push the boundaries of scientific advancement. Advancements arrive in the form of new medications, alternative manufacturing processes, or a better understanding of sustainability and the use of renewable resources. While each method is unique in scope and execution, they all share the need for precise control over production processes.

In bioscience fields, there are two primary distinctions. Intracellular processes and extracellular processes form the defining line between cellular and molecular processing. Intracellular processes break cells apart through cell disruption. Filters with microscopic pore openings remove cellular debris and purify the samples for testing.

The extracellular processes help to lead research into new biofuels, biodegradable plastics, industrial enzymes, and more. Filtration methods for extraction, precipitation, crystallization, and centrifugation allow scientists to isolate ethanol, antibiotics, and oils. For example, microalgae were grown through extracellular processes to serve as a viable target for biofuels and other bioactive compounds.

Filtration products allow for precise control over research and testing processes. By understanding that target elements have size constraints, scientists use filters with corresponding pore sizes to purify samples or isolate targeted molecules. For example, white blood cells are 25 microns while red blood cells are 7-8 microns. Using a filter with 20-micron pores on a blood test would filter out anything larger than 20 microns in size, including white blood cells.

The requirements for different bioprocessing methods will also determine the type of filtration needed. Centrifugal filter tubes, vacuum-aided filtration, tangental filtration, and chromatography filter papers provide options to obtain specific results.

The evolution of scientific methods using bioprocessing is crucial for unlocking new potentials in biosciences. The delicate interplay between intracellular and extracellular processes, including precise filtration techniques, enables researchers to enhance their findings. Additionally, by tailoring filtration solutions to specific bioprocessing needs, scientists drive innovations that promote sustainability, new therapies, and advanced materials. The dedication of professionals in the bioscience industry, and their unrelenting research, will continue to drive transformative advancements to address our most pressing global challenges.