by Tim Bolen  

Everybody has seen "Bones," on Star Trek, pass what looks like a TV remote control device over a reclining patient in sick bay of the Starship Enterprise.  In his best bedside manner, the good doctor "hmmm'd, and uh-huh'd," and within seconds proclaimed a diagnosis.

Whether it was cancer, heart disease, or bad breath, it didn't matter - for after 20 seconds of "concerned looks," "Bones" could proclaim "I'll have you back to work in the morning!"

Gene Rodenberry, the Producer of the series, and his team, just didn't know about Hulda Clark.  For if they did, I'm sure they would have written in a new line for the doctor, "Nurse, hand me the Clark 421 please..."

Can an electronic device, like the Syncrometer, really analyze the human body quickly, and provide information for a health professional to diagnose? 

Now there's a good argument to bandy around the peer reviewed journals...

So, let's start that argument.

"Nurse, hand me the Clark 001 please..."

Clark's Syncrometer (Clark 001) is an electronic device that has one purpose - and only one.  It detects electrical frequencies (waves), and announces them by making a specific sound change.

In the hands of someone properly trained in its use, the Syncrometer can detect any foreign substance in the human body, and tell us exactly where that substance is concentrated.

Clark has found that every living thing has its own specific sound.  In other words, every living thing electrically resonates at its own specific frequency.  

Imagine having a finely tuned microphone where you could listen to the specific sound emitted by a flu virus, look at your digital meter, and see that that flu virus resonated at 33.4562 khz.  Then you could listen to a sample of e-coli bacteria, and hear it resonate at 27.6743 khz on your digital meter. (I made up those frequencies.)

So what?

Well, suppose you had a list of every living thing in the world's emitted frequency?  Then, if you have an unidentified sample in a lab dish in front of you, wouldn't it make sense to do a test to see at what frequency it resonated?

If the sample in front of you showed a read-out on your digital meter of  33.4562 khz, could we be looking at flu virus?

Simple, huh?

Ok, so the Syncrometer can be a useful lab tool.  But, Clark uses it to detect things INSIDE a human body.  How does she do that?

Actually, it is quite simple.  She merely puts the human body into the circuit.

Every electrical circuit is a circle.  In other words, in order for a table lamp to work there has to be two wires - one for the electricity to go IN, the other OUT, and back to the starting point.  Disconnect one of those wires and the light bulb goes off.

Electricity, and the science of it, is well developed.  I am not going to try to explain all of it's parts to you here - but I will give you some of its applications. 

Besides the electrical plug in which you plugged in the computer you are using to read this, there are thousands of things we normally use in our daily lives which make use of the electrical phenomena.  Radio, television, communications systems, tapes, CDs, etc., are all functions of electricity and its components.

The Syncrometer is much easier to explain than, for instance, that radio on the table over there.  Care to tell me how that works?  If you can do that, can you tell me how my television hooked up to my satellite dish works?  Or how about explaining how I get that crystal clear sound of Arthur Rubenstein playing Chopin's Nocturnes in my car, off a little tiny thing that looks like an under-age Frisbee?

Please, don't call me an tell me how my television works.  I just want to push the buttons and have it work.  I don't care HOW it works.

Simply put, the Syncrometer is in that genre. 

Let's do a (virtual) Syncrometer test on YOU, as an example...

Sit down, right here in front of Dr. Clark.  Hold that copper tube attached to the red wire in your right hand.  Put your left hand in front of Dr. Clark.

The electrical circuit we are going to make has three parts:  (1) the audio oscillator (Syncrometer), (2) the Test Plate apparatus, and (3) YOU.

In the Syncrometer test layout, Clark has two, what she calls "test plates."  These are little platforms on which you can place things.  If you place a little bottle of flu virus on the plate, that bottle is resonating at a certain frequency.  Let's say Dr. Clark wants to find out if you have the flu virus in your body.  All she has to do is put a glass bottle, from a laboratory supply house, containing the flu virus on the test plate.  Since the sample is emitting its own resonance frequency - that frequency now becomes part of the circuit.

All Dr. Clark, or any Syncrometer operator, has to do is listen to see if their is a resonance sound generated by the audio oscillator.  If there is one, than the virus is present.  If there is no resonance than it most likely is not - or exists in a very small quantity.

So what if you wanted to know EXACTLY where that foreign substance is in your body.  The Syncrometer operator can locate the exact place it resides, and/or determine if it is present in any organ, tissue, etc.

How can they do that?  By putting samples (in glass containers) of various organs, tissues, etc. on the test plates one at a time.  This action adjusts the resonance wave.  If it now gives off an audio oscillation, it IS in that location.  If not...

By determining what foreign substances are present, in what locations, trained health professionals can pre-stage weeks of laboratory workups, and make many more tests, quicker, and at less cost, deriving a lot more diagnostic information.

So, is this the diagnostic tool of the future?

Yes, and No.  Actually, it is the diagnostic tool for right now.

Every health professional in the world needs to have a trained Syncrometer operator in their place of business, just to do an "intake" examination.  The medical profession likes the expression "early detection" - here is the device that can deliver early information like no other.

The Clark 421?

Of course...  Hulda Clark is a research scientist.  Research scientists never sit still.  There is always another door to open, another question to ask - and answer, another path to go down.

Clark is just at the beginning...