The secret of the LEC-03 lies in the design and the manufacturing process of its disposable probes. They could be called the heart of the device. The quality of the probes, with perfectly identical parameters, is ensured by the standard manufacturing conditions and the constantly monitored ISO 9001 quality control process. This production technology has been patented in 20 countries around the world and we have the exclusive rights to promote and distribute it.
The electrochemical sensor is built into the tip end of a slender plastic tube 2 mm in diameter. This feature makes it easy to locate malignant alterations with high accuracy. Its plastic tube is manufactured in different lengths, from 20 cm to 160 cm. These features make the LEC-03 an ideal tool for laparoscopic surgeries and it is easily utilized in the field of laryngology, otology, rhinology, dental surgery, dermatology, urology, or gastroenterology, to mention only a few of the numerous possibilities.

The sensor of this device is a miniature electrochemical cell (primary battery). The chemical interaction between one of the sensor's electrodes and the alkali ions of tissue-electrolyte, generates electric power.

The generated electrical power (measured in microwatt, and showed in microampere on the display) stems from the alkali ion concentration alone. The current alkali ion level - due to the cell division rate - will produce a proportionate rise in electrical power.

The next direction for further improvement is the development of a syringe-like probe line that makes the detection of cancerous tissues possible in deeper areas of the body, reaching it by placing the probe into the target area.

The diagram below illustrates the characteristics of the Cancer Detector's probes. According to this, the critical (malignant) speed of cell division is 30 microampere = 800 mM/kg dry weight (Na+, K+ ion) = 7 days/1 cell-division.

The biochemical foundations leading to this unique invention (LEC-03) were laid down by such world famous American scientist-researchers as Cone, Cameron, Smith and Rosengurt. They independently came to the very same conclusions regarding Na+ ion concentration in cancerous tissues.

Ivan Cameron (University of Texas Health Science Center at San Antonio, Texas USA) and his biochemist colleague, Philip Skehan (Department of Pharmacology and the Oncology Research Group, University of Calgary, Alberta, Canada), have found that the normal cells contain the dry weight amount of approximately 500 mM/kg monovalent Na+, K+ cations. This corresponds with the same parameters of the slowly dividing cells, while fast dividing healthy cells and tumorous cells, as can be seen on the diagram, accumulate the dry weight amount of approx. 800 mM/kg cations.