V.I. Nesterov
The Non-linear Diagnosis Systems (NLS) have been extensively used lately and are
gaining ever growing popularity. Even in the few cases, where the clinical symptoms
look very typical, NLS diagnosis provides extra information about the extent of
dysfunction and enables a better opportunity for a more comprehensive prognosis. In
most cases it is of vital importance for diagnosis and consequently for the right choice of
treatment.
In 2000 Theodore Van Hoven theory of quantum entropy logic (that underlies this
method) had been in existence for 20 years. Non-linear diagnosis appears to be the most
up-to-date of all methods of the hardware-based diagnosis. His discovery can be viewed as a
significant landmark in diagnostic medicine.
Non-linear analysis was originally employed in organic chemistry to determine the
composition of complex compounds.
Sviatoslav Pavlovich Nesterov, who introduced a trigger sensor in 1988 and thus framed the
concept, is considered as the originator of the NLS-diagnosis device (metatron).
Active work was immediately started to develop and improve the NLS-diagnostic
systems. Clinical testing of the early equipment took the period from 1990 through 1995. The
late 90s saw a fast growth of commercial production of the device and a sudden
surge in the quality of the results produced.
The non-linear diagnosis method is still in its development stage. The diagnostic
techniques are improving so fast that the system versions have to be updated every six
months. Due to the introduction of some new devices, equipped with digital trigger
sensors, the NLS-diagnosis has become not only far more time-efficient but also quite
different in terms of quality. It is obvious that some routine techniques, for instance
three-dimensional visualization of investigation results will soon become a daily practice.
The vegetative testing aspect (testing of specific item signatures against the client) is just
one example of the developments. NLS analysis is now becoming so widely employed
that we should rather speak about a definite range of indications for its use than just about
its popularization.
Research centers continue their quest for some new investigation methods based on the
non-linear analysis systems. So far the results appear to be quite promising.
Unlike NMR and computer tomography, the NLS-analysis does not need strong fields.
The method seems to have good prospects for metabolism studies, particular on a cellular
level.
The NLS-method is advancing not only in technical innovation but also in new
applications. Some minor surgical operations (e.g. biopsy) have long been monitored
using ultrasound, fluoroscopy or computer tomography. Today we have an opportunity to
have biopsy monitored by NLS. Many surgeons now focus on using this method to assist
major surgeries.
The cost of equipment for NLS-diagnosis is still very low as compared to some other
hardware-based methods. This should help promote more extensive use of the method in
countries with low living standards. Of all methods of hardware-based diagnosis the
NLS provides representations most proximate to the pathologic-anatomic picture. The
feature of the method along with its harmlessness, promotes rapid development of the
NLS-diagnosis.