Flow cytometry in the field of oncology is utilized for the quantitative detection and measurement of the physical and chemical characteristics of cancerous cells in a given sample. Flow cytometry is majorly used for hematological malignancies to identify malignant cell types by detecting cell surface antigens, which offer critical information regarding the stage of maturation and phenotypical heterogeneity. Although flow cytometry has been an established cornerstone for the diagnosis and screening of hematological malignancies, the clinical applicability of the same is not well understood in the field of solid tumors. However, extensive research is being conducted to decipher insights pertaining to the utility of flow cytometry in the quantification of nuclear DNA content present in solid tumor samples.

Gel documentation systems are used to visualize and document the gel experiments. Further, the characterization of protein and nucleic acid is also done by gel documentation systems. For deoxyribonucleic acid (DNA), gels can be used for separation, sequencing, preparation, and imaging, and documentation are essential to all these applications. With modern imaging and documentation systems, the quantification of nucleic acid and proteins can be highly accurate and quantitative. Gel documentation systems include all-in-one systems, which are instruments, accessories, and software. The systems are used for academic and research institutions. The current study aims to assess the global gel documentation systems market by focusing on evaluating products catering to the aforementioned definition. The current scenario of gel documentation systems is majorly dominated by biotechnology majors such as Analytik Jena GmbH, Azure Biosystems, Inc., Bio-Rad Laboratories, Cleaver Scientific, Danaher Corporation, and Thermo Fisher Scientific Inc.

Industrial microbiology is the branch of applied microbiology that involves the utilization of microorganisms in industrial processes such as pharmaceutical drugs development, vaccines production, industrial fermentation, wastewater treatment, and industrial chemical treatment. Industrial microbiological quality control includes the use of products and services for the identification and control of microbial species in the manufacturing of food items, beverages, drugs, cosmetics, biologics, and other industrial products in large quantities. Microbial contamination of the products is a significant concern for many industrial verticals. Excessive microbial growth can cause deteriorations of the machines and equipment used in the production process. It also decreases the process efficiency in manufacturing, thereby negatively impacting the quality of the end product and endangering the health and safety of consumers and workers.

Technology in terms of solar cell efficiency, battery density, advanced materials, and control (stability) has progressed significantly to make HAPS a technically and economically viable product. The HAPS technology advancement will also benefit from the current developments in electric mobility, electric aircraft, and unmanned aerial mobility (cargo airships).