The systems of nonlinear diagnostics (NLS) have acquired wide reputation recently. Even in those few cases where the clinical symptomatology is very typical the method of NLS-diagnostics brings some extra information about the size of damage and allows judging about the prognosis. In overwhelming majority of cases it has principal significance for diagnosing and consequently for the correct choice of cure.
In 2000 the Theory of quantum entropic logic created by academician Svyatoslav Pavlovitch Nesterov, which underlies the method itself, celebrated its 20th anniversary. So the nonlinear diagnostics is the youngest method among other hardware-based methods of diagnostics. However its discovery became a very important landmark in diagnostic medicine.
The apparatus for NLS-diagnostics (metatron) was created by Vladimir Igorevitch Nesterov, who offered in 1988 a trigger gauge and thus founded the idea of the apparatus.
Then Mr. Nesterov founded an Institute of Practical Psychophysics (IPP) and at once began active work on creating and improving NLS-diagnostics systems. The period from 1990 to 1995 was characterized by clinical tests of the first apparatuses. Late 90’s were marked by a rapid growth in commercial manufacture of apparatuses and a break-through in quality of the results obtained.
The NLS-method is still at its stage of development. The diagnostics methodologies are being improved so fast that the system versions are updated every six months. Due to introduction of new apparatuses with digital trigger gauges the NLS-diagnostics became not only faster but different in terms of quality. Obviously the dynamic methodologies such as the three-dimensional visualization of the examination results very soon will become routine practice. The methodology of vegetative testing is a striking example of their fast introduction. It is used so widely that one should speak sooner of a more strict specter of indications for it than of its popularization.
The Institute of Practical Psychophysics keeps searching for new methods of investigation based on NLS-systems. The results are very promising.
The NLS-analysis in contrast to NMR (Nuclear Magnetic Resonance) and computer tomography does not require high-density fields. The method looks prospective for research of metabolism in particular on cellular level.
The improvement of NLS-method follows not only the way of technical novelties but also the way of new applications. The simplest surgical manipulations such as biopsy for a long time are carried out under control of ultrasound, fluoroscopy and computer tomography. Now we have such an opportunity, and the biopsy became possible under control of NLS. However the attention of surgeons is attracted by more complicated operations carried out using this methodology.
The cost of equipment for NLS-diagnostics remains extremely low as compared to other hardware methods. This must promote wide spreading of this method in the countries with low level of income of their population. Among all methods of hardware diagnostics the NLS gives the picture, which is to the greatest extent close to the pathologoanatomic one. This condition along with its harmlessness stimulates rapid development of NLS-diagnostics method.

Principles of functioning of NLS-diagnostics apparatuses

In compliance with the Theory of quantum entropic logic, the informational exchange between systems is realized thanks to quanta of electromagnetic emanation, which have energy adequate to that of destruction of connections in elementary structure of a system.
The intensity of informational exchange between two systems A and B, which exchange information, increases with destruction of order in any one of those systems.
The degree of order of any system is equivalent to the quantity of information it contains. That is why the destruction of order in one of the systems (A) with parallel transmission of information to the second one (B) expresses the Law of conservation of information, postulated by the Theory of quantum entropic logic.
The Theory of entropic logic postulates that the abovementioned positions are physically rightful only in case where the systems A and B are quantum systems and the unity consisting of parts A and B can be described as one quantum state. This anticipates presence of initially existing informational exchange preceding the destruction of structures of one of the systems, what connects within the limits of entropic logic both parts in a whole quantum system, as long as it complies with the Einstein-Rozen-Podolsky effect.
The Theory of quantum entropic logic allows explaining many details of fundamental psychophysical mechanisms acting in a long-distance transmission of information between two spatially remote objects. The theory reveals the mechanisms, which form associativity, informational selectivity and other characteristics of a similar channel of transmission of information.
From the physical point of view the apparatus is a system of electronic oscillators (cadistor), which resonate at such electromagnetic wavelengths, whose energy is adequate to that of destruction of dominant connections maintaining the structural organization of a biological object. The information about a concrete state of a biological object is taken using a noncontact method with the help of a “trigger gauge”, developed with the implementation of new informational technologies and chip-making techniques. The “trigger gauge” picks up the smallest fluctuations of signals sorted out from the average statistical noise characteristics of fields and then transforms them into a digital sequence. Then a microprocessor processes this sequence to transmit it through an interface cable into a computer.
Every type of cells has its own energy of destruction, which is characteristic for certain intracellular molecular connections.
Changing accordingly the cadistor emanation characteristics one can cause the destruction of connections of intracellular structures (and the spine orientations of bio-molecular combinations connected with them) within the cells of any tissues of an organism.
It is natural that the more unstable and accordingly already defective state the studied tissues have, the higher response in compliance with the Theory of quantum entropic logic we get.
At the same time the scanning frequencies will coordinate the position of response, what together with the value of response will picture the general geometry of damage accumulated in the organism.
The energy emanation destructing characteristic molecular connections, which is used while locating always matches with the resonance of corresponding electron transitions in the structure of the cadistor. And based on this resonance and the released (because of the destruction of the spine organization) energy due to appearance of metastable nonlinear processes in the structure of the cadistor a quantum pump is realized. And the quantum pump amplifies the response signal emitted by the organism.

Future trends in development of NLS-technologies

The development of a new generation of nonlinear computer scanners (metatrons) by the Institute of Practical Psychophysics, where a many-dimensional virtual visualization of the studied object is applied, allowed improving essentially the effectiveness of the NLS-method even broadening its area of application despite the competition of MRT.
The peculiarity of many-dimensional visualization of NLS is the initially three-dimensional nature of scanning. The received data represent a unified array, what eases reconstruction of many-dimensional virtual images of anatomic structures of a studied object.
In this connection the virtual NLS is widely used in particular for the angiographic researches with three-dimensional reconstruction of vascular formations.
Other promising field of application of three-dimensional reconstruction of images based on data received with the many-dimensional NLS is the study of hollow organs on the principle of “virtual NLS-scopy”. Such system is developed by the Institute of Practical Psychophysics jointly with a firm “ClinicTech Inc.” (USA) for Z-series high-speed many-dimensional nonlinear scanners. This system was named “Hunter”. Preservation of high resolution during fractal scanning and implementation of LAAP system (a system of parallel processors with super high computational capability and processing speed) allows realizing in this development a principle of “virtual NLS-scopy” on a multimodal DICOM-compatible workstation Voxel Z, which is the basic system of visualization and further processing of data on ClinicTech Inc. scanners. Preparation of NLS-images for visual analysis is made with the help of a developed original method “4-D Tissue”, which enables not only to get virtual many-dimensional images of anatomic structures but also to focus on some particular biological tissue – “additional dimension” and visualize bones, soft tissues and vessels simultaneously.
The characteristic feature of presentation of virtual data in the Hunter system is the simultaneous visualization of surfaces of hollow formations and extramural formations, which are located outside the opening of the cavity under study (lymph nodes, vessels). The resulting images form a natural sequence of virtual NLS-pictures. At the same time special navigating programs automatically detect the trajectory of “virtual scanner” movement in the center of the cavity under study. The choice of movement trajectory may also be made using other parameters set by the operator, what enables him/her to determine details of an NLS-image changing the angle of view. The relief image of the surface of a cavity with artificial shadow sections is also possible. The formed sequences of NLS-images may easily be transformed into a standard VHS format with the help of epi-Client program and thus be used on common video-systems, in particular for the purpose of teleradiology.
The Hunter system is intended first of all to detect patients with obstructive processes in upper air passages, volumetric formations of oesophagus, stomach and large intestine, atherosclerotic damages of major vessels, diseases of paranasal sinus, urinary bladder and vertebral canal. Data obtained with the help of “virtual NLS-scopy” allow choosing beforehand an optimal place for biopsy and define the size of surgical interven-tion. The given methodology may be used independently as well as represent a good connecting-link between tomographic, endoscopic and NLS examinations.
The latest development is an integrated with a computer scanner stereotaxic manipulator – The Pincers – a handy instrument to plan surgical interventions under control of NLS.
The Pincers consist of an operated stereotaxic manipulator (“hand”) and a flat monitor both mounted on a mechanical arm, and also a system of cables and software. The system provides a doctor with facilities for modeling and executing surgical interventions with the help of interactive communication between the virtual NLS and the real operative field.