The stethoscope (from Greekστηθοσκόπιο, of στήθος, stéthos - chest and σκοπή, skopé - examination) is an acoustic medical device for auscultation, or listening to the internal sounds of an animal body. It is often used to listen to lung and heart sounds. It is also used to listen to intestines and blood flow in arteries and veins. In combination with a sphygmomanometer, it is commonly used for measurements of blood pressure.
Less commonly, "mechanic's stethoscopes" are used to listen to internal
sounds made by machines, such as diagnosing a malfunctioning automobile
engine by listening to the sounds of its internal parts. Stethoscopes
can also be used to check scientific vacuum chambers for leaks, and for
various other small-scale acoustic monitoring tasks
Diagnostic tool 2: The FSCAN (Invented 2001)
A valuable device to scan one's body for the presence of pathogens.
- It detects the presence of pathogens
- It determines anomalies in the body through EAV
- It treats a wide range of ailments by
The dilemma with which health and medical practitioners are being continuously
confronted is to determine with which pathogens their patients are infected
The problem with blood tests is that one must specify beforehand which
pathogens the laboratory must look for. For each pathogen that needs to be
identified, a separate blood sample is needed. This is not only painful and
time-consuming but the problem is that certain pathogens that also may be
present in the patient and were not specified for the test will remain
unidentified in the patient. A good example is for instance where the patient
complains about chronic fatigue. There are numerous pathogens that may cause
chronic fatigue symptoms, such as the Epstein Bahr virus, the whole range of
Coxsacci bacteria as well as a wide spectrum of parasites, including worms and
The solution to this dilemma is to scan the body in a short period of time for
all pathogens present.
This can be done by the Fscan.
Every substance in the body (hormone, toxin, vitamin and pathogen) has a unique
energy signature comprised of 55 different electrical measurements, including
frequency, voltage, amperage, inductance and capacitance. Using bio-resonance,
the Fscan sends pulsed electro-magnetic signals at different frequencies into
the body and by detecting the responses to each signal, it can identify the
pathogen by comparing it with the data stored in the Fscan’s memory base.
The Fscan is a frequency scanner that is able to detect the presence of
pathogens by transmitting a burst of frequencies through the body, and by
applying the principle of sympathetic resonance, it reports back on
corresponding resonance activities.
The principle of sympathetic resonance involves that if there are two similar
objects close to each other and one of them is vibrating, the other will begin
to vibrate as well, even if they are not touching.
As it is a scientific fact that everything resonates, it is thus understandable
that if the resonant frequency of each pathogen is known, one can determine
which pathogens are present in the body. Thanks to medical research
pioneers such as Dr Royal Raymond Rife and Dr Hulda Clark, most of the known
pathogens have been connected with a specific frequency at which they each
vibrate. When new pathogens such as SARS became known, their frequencies could
be determined as soon as their DNA signatures had been identified.
In the same way that a sound wave can induce resonance in a crystal glass and
ultra-sound can be used to destroy gallstones, the Fscan can transmit a series
of frequencies through the body and detect when a similar frequency is returned
to the Fscan.
When a patient complains about an infection the practitioner needs several
blood tests to be done to determine which pathogen is causing the infection.
The results of the blood test itself may take a minimum of a few hours
before they are known. It may even take days, depending on how busy the
laboratory is and the type of pathogen involved. The Fscan can therefore be
applied in a health or medical practice that necessitates the quick
identification of pathogens. With the pathogens identified, the practitioner
can now verify the Fscan's results with a blood test as the Fscan dramatically
narrows down the wide range of pathogens that may cause the symptoms. Instead
of requiring maybe 10 or even more blood tests, one now drastically reduce the
number of tests required. With the Fscan’s results at hand, the practitioner
can apply the information straight away to assist him or her in making a proper
The advantages of the Fscan
Scanning an individual takes little time.
An Fscan procedure does not have to take more than 10 minutes. One sees
the results instantly, not like in the case of many other tests that may even
take days. Accurate monitoring of patient’s infection status can be done in