Biological/biomedical properties

Keywords Benzophenothiazines Biological and biomedical properties Phenothiazines Photophysical, photochemical and analytical studies Spectroscopic properties... 

Biological and Biomedical Properties of Phenothiazines and Benzo[a]phenothiazines... 

The biological and biomedical properties of benzo[a]phenothiazine derivatives were widely investigated in the last two decades. However, the precise interpretation of the biomedical properties and applications of these large molecules remains the matter of future research. 

In this chapter, we have reviewed recent progress in spectroscopic, pho-tophysical, photochemical and analytical studies as well as the biological and biomedical properties of a number of bioactive phenothiazines and benzo[a]phenothiazines. 

The last chapter, Bioactive Phenothiazines and Benzo[ a] phenothiazines Spectroscopic Studies, Biological and Biomedical Properties and Applications by Jean-Jacques Aaron, Mame Diabou Gaye-Seye, Snezana Trajkovska, and Noboru Motohashi, presents recent advances in the spectroscopic, photophysical, photochemical, and analytical studies of bioactive phenothiazines and benzophenothiazines, including also their biological and biomedical properties, as well as recent results from the authors of this review Chapter. The... 

Spectroscopic Studies, and Biological and Biomedical Properties and Applications... 

Long-range transport (LRT) of particles from wildfires greatly inerease in small fine particles (PM 1 to 0.2 particles) or ultrafine particles. LRT is the second of four criteria of hazardous (organic) particles. Other properties of partiele hazard are persistence (previously discussed), bioaccumulation (particles suffieiently small to avoid phagocytosis), and adverse biological (biomedical) effects. PM 1 to 0.2 particles are the smallest portion of fine particles, which we call the aceumulation mode (1,2). They are the closest to ultrafine (nano) particles in size (structure) and funetion. 

Plieva FM, Galaev lY, Mattiasson B (2010) Production and properties of cryogels by radical polymerization. In Mattiasson B, Kumar A, Galaev I (eds) Macroporous polymers production, properties and biological/biomedical applications. CRC, Boca Raton, p 23... 

Macroporous polymers production, properties and biological/biomedical applications. CRC, Boca Raton, p 83... 

This chapter presents a literature survey of the applications of porous silicon in BioMEMS (biological/biomedical microelectromechanical systems). This material possesses properties particularly suitable for biomedical purposes biocompatibility, biodegradability, photoluminescence, ability to precisely control the pore size and shape, and possibility to easily modify the surface chemistry. Many applications can, for instance, be found in the fields of sensing and delivery of therapeutics. It is expected that the number of BioMEMS using porous silicon will continue to increase in the future with the development of lab-on-a-chip/microfluidic devices. 

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