In many years, a lot of science researchers have tried to explain and unravel the broad diversity of multifaceted forms that oftentimes surface in live blood as observed by means of darkfield microscopy using a darkfield compound microscope. These compositions are not the usual developed elements of the blood, which are the erythrocytes or red corpuscles, leukocytes or white blood cells, and thrombocytes or the platelets, but the actual bestiary of elements that are either not apparent with most standard imaging methods, or are habitually discharged as accidental artifacts of zero importance.
Among these forms that are simply observed with a science research grade darkfield compound microscope are the tubular, spherical and branched membrane-bound components ranging from a fraction of a micron in length to fifty microns or more, as observed via microscopy under the microscope such as darkfield compound microscope. As observed through microscopy using a microscope such as darkfield compound microscope, the radial, linear, branched, articulated and networked webs of filamentous and flexible strands also appear. The broad array of crystalline forms ranging from simple reflective masses to greatly structured, fern like fields with a noticeably fractal look can also be viewed via microscopy under the microscope such as darkfield compound microscope. The massive accumulations of diverse property forms, textures and colors are also apparent under the darkfield compound microscope.
These elements can be observed via microscopy using a microscope such as darkfield compound microscope while being formed and consequently create morphological conversions in particularly unfailing manners either suddenly or in response to particular types of in vitro disputes. In an instance, there is a firm, butterfly formed crystalline plate that can oftentimes be observed collapsing into a cluster of flexible strands anchored to a common midpoint, which can be viewed by means of microscopy using a microscope such as darkfield compound microscope. If for a time being the question of what these shapes actually are will be placed aside, it is nevertheless probable to relate their existence and revolutionary patterns with certain clinical conditions, making them helpful as signs for particular therapeutic selections. This is the turf of classical darkfield blood analysis using a darkfield compound microscope, and it is also the onset of a more sophisticated and accurate analytical method known as DIAD Microscopy. DIAD means Differential Isopathic Assessment in Darkfield.
At certain point, nonetheless, the temptation to discover the origin of the objects themselves becomes convincing. Dr. Günther Enderlein created a wide-ranging theory of bacterial and fungal pleomorphism and taken into consideration some of the types he observed in the blood using a microscope like a darkfield compound microscope, to be living bacteria and mold fungi. Nevertheless, Enderlein’s theories are not easy to resolve with modern biological information, and parts of his opus seem frankly naïve and obsolete.
In reaction to it, another science researcher has suggested a theory hypothesizing that bacterial and fungal pleomorphism may be the consequence of a set of progressive ecological dynamics, and have theorized a new enlightenment for the phenomena that he called provolution. The Theory of Ambimorphic Provolution proposes that certain autonomously grown microorganisms endure an intense procedure of devolution inside a lineage of host organisms like the mammalian line where humans developed. At certain later time, acting in response to triggers inside the host’s internal ecological system, numerous devolved elements can recombine to generate active biological arrangement. The science researcher utilized the term provolution to explain this procedure of undevolving. It is not important that the provolved entities precisely match the devolved organisms wherein they came from. They merely need to have the morphological comparison to operate as markers of a clinically important procedure.