Akademik Veri Yönetim Sistemi
INTERNATIONAL CONGRESS OF MULTIDISCIPLINARY STUDIES IN HEALTH SCIENCES, Erzurum, Türkiye, 14 Ocak 2022, ss.89-90
Biofluid dynamics is considered valid as a subject that studies fluid flow, fluid-structure
interaction, and heat and mass transfer in living things and their therapeutic medical devices [1].
Biofluid has had an even weirder use lately - it’s become part of the art. In the most basic terms, a
biofluid is a biological fluid, a fluid produced by the body itself. Biofluids can be excreted through
sweat, secreted through bile, obtained through a needle when blood is drawn, or develop from a
blister or cyst. Body water is also a biofluid such as earwax, amniotic fluid, cerebrospinal fluid,
pus, and saliva, among others. Biofluid is a term often used by researchers and those in the medical profession. Most other people call them bodily fluids. Biofluid is also a common term used
by crime practitioners when working at crime scenes. DNA is found in many bodily fluids, and its
proper, safe handling is something that all crime scene personnel should be trained in. Analysis of
biofluids could be the key to solving rape and murder cases [2].
Ritual purification is even used in some religions. Medical hygiene workers, hospitals,
and doctor’s offices are increasingly treating biofluids as dangerous because they can potentially
carry blood-borne diseases [4,3]. Since the onset of AIDS and other diseases, biofluids have been
treated with increasing attention. There are strict rules about how nurses and doctors are acquired,
handled and disposed of. Strict biofluid management provides important infection and disease
control.
A non-Newtonian fluid is a different fluid from a Newtonian fluid as the viscosity of the
non-Newtonian fluid is similar to that of subsedation. In a non-Newtonian fluid, the relationship
between shear stress and shear rating is different and may even depend on the time of the blades.
Thesis time may be on the ground. Therefore, a viscosity product cannot be proven. Non-Newtonian fluids change their viscosity or flow behavior under stress. If force is applied to such fluids, compression can cause them to thicken, behave like solids, or in some cases behave in the opposite direction and leak more than before. Deletion causes them to revert to their previous state.
Not all non-Newtonian fluids behave the same way when stress is applied - some are more solid,
some are more fluid.