Cindy, Dr Hicks Autism One presentation, was: The Science Behind LW patches

[Guest guest]

Hi , was there anything of importance or interest in his

presentation that was not shown on slides? what was his take-home

message in terms of treatments?

tia

Natasa

> >>>>

> >>>>

> >>>>> yes but people are wanting reports NOT from lifewave, that is

the

> >>>>>

> >>>>>

> >>>> problem. there are reports form the CDC that vaccinations are

all

> >>>> safe and don't cause autism but they are all funded from the cdc

> >>>>

> > WITH

> >

> >>>> a vested interest, people are wanting to see outside source info

> >>>>

> >>>>

> >>>>> Recovering from Autism is a marathon

> >>>>> NOT a sprint, but FULLY possible!

> >>>>> Read more about it on my BLOGs at

> >>>>> http://www.myspace.com/christelking

> >>>>> http://foggyrock.com/MyPage/recoveringwishes

> >>>>> http://www.facebook.com/profile.php?id=677063169

> >>>>>

> >>>>> The Science Behind LW patches

> >>>>>

> >>>>>

> >>>>>

> >>>>> PS From Sue I hope the report below will help your

> >>>>>

> >>>>>

> >>>> understanding of how the LW patches work.

> >>>>

> >>>>

> >>>>> This is part of a 23 page report.... pages 14-23

> >>>>> The Science Behind LifeWave Technology Patches

> >>>>> BY Steve Haltiwanger, M.D., C.C.N.

> >>>>>

> >>>>> LIFEWAVE patches are like organic radio stations

> >>>>> ·

> >>>>> One analogy that may help you understand how LifeWave patches

> >>>>>

> >>>>>

> >>>> work is to think of them as being like organic radio stations.

Lets

> >>>> say you own a radio station. Your radio station will have to be

> >>>> licensed by the federal government to send out a specific

frequency

> >>>> called a carrier wave across the airwaves. The carrier wave that

> >>>>

> > your

> >

> >>>> radio station transmits is used to carry or piggyback other

> >>>> frequencies that contain information signals. If you are licensed

> >>>>

> > to

> >

> >>>> run an FM radio station your equipment will use frequency

> >>>>

> > modulation

> >

> >>>> to encode information on the carrier wave that your station

> >>>> transmits. In order for the radios in people's homes to receive

> >>>>

> > your

> >

> >>>> radio transmission their radios have to be tuned to carrier wave

of

> >>>> your radio station so that they can demodulate the information

> >>>> signals.

> >>>>

> >>>>

> >>>>> ·

> >>>>> Your radio station will use an active transmitter that derives

> >>>>>

> >>>>>

> >>>> energy from electricity to send out electromagnetic frequencies

> >>>>

> > that

> >

> >>>> lie in a particular portion of the electromagnetic spectra we

call

> >>>> radio waves. Before you begin operation of your radio station you

> >>>>

> > are

> >

> >>>> first going to have to decide what information you want your

radio

> >>>> station to transmit. If you choose to send information that

nobody

> >>>> wants to listen to you will soon be out of business. Therefore,

you

> >>>> have to be very selective in the information that you transmit.

If

> >>>>

> > a

> >

> >>>> signal is sent from one place and received at another place then

> >>>> information has been successfully transmitted and received.

> >>>>

> >>>>

> >>>>> ·

> >>>>> Just as the mayor of a city can get on your radio station and

> >>>>>

> >>>>>

> >>>> tell the citizens that the community has a blood shortage. Those

> >>>> people who respond to the information they received on their

radios

> >>>> can then go to the Red Cross and donate blood. What we have is

the

> >>>> phenomenon where information has been transmitted from one place

to

> >>>> another and a response occurs.

> >>>>

> >>>>

> >>>>> ·

> >>>>> LifeWave patch technology was invented with the recognition

that

> >>>>>

> >>>>>

> >>>> the body is composed of molecules and that each chemical reaction

> >>>>

> > in

> >

> >>>> the body uses very specific combinations of molecules and that

> >>>> frequencythese molecules will respond to specific signals or

> >>>>

> > codes.

> >

> >>>> In general molecules in the body are not isolated substances

> >>>> dissolved in the fluid of cells instead molecules link to other

> >>>> molecules to form more complex structures.

> >>>>

> >>>>

> >>>>> ·

> >>>>> Every molecule and molecular complex of the body is like the

> >>>>>

> >>>>>

> >>>> glass in the Memorex commercial. Each molecule and molecular

> >>>>

> > complex

> >

> >>>> has its own specific frequency at which it can resonantly absorb

> >>>> information or energy. In a sense these molecular structures are

> >>>>

> > like

> >

> >>>> a miniature radio receivers. When information is sent at the

> >>>> frequency code that these molecular radios are pretuned to

receive,

> >>>> information or energy can be directly transmitted to those

> >>>>

> > molecules

> >

> >>>> in the body. This process of energy transfer to specific

molecular

> >>>> complexes can assist in the activation of the chemical reactions

> >>>> these molecules are involved in.

> >>>>

> >>>>

> >>>>> ·

> >>>>> LifeWave patches were designed to function as passive

> >>>>>

> > transmitter

> >

> >>>> systems. When the patches are placed on the skin the materials in

> >>>> magnetic field the patches interact with and modulate body's to

> >>>> produce certain specific electrical signals. In addition the

body's

> >>>> natural magnetic field is the carrier that takes these signals

into

> >>>> the body.

> >>>>

> >>>>

> >>>>> ·

> >>>>> LifeWave patch technology does not create chemical reactions

in

> >>>>>

> >>>>>

> >>>> the body it only assists biological reactions that are already

> >>>>

> > taking

> >

> >>>> place to work more efficiently. Schmidt has basically

> >>>> investigated what signals are needed to turn on certain

biological

> >>>> reactions and invented a patch technology that can effectively

> >>>> deliver these signals into the body.

> >>>>

> >>>>

> >>>>> ·

> >>>>> In summary, LIFEWAVE patches contain organic molecules that

are

> >>>>>

> >>>>>

> >>>> naturally present in the human body. These substances have

already

> >>>> been determined to be safe by the FDA. However instead of

actually

> >>>> putting the molecules themselves into the body LIFEWAVE patches

> >>>> produce specific electrical signals, which will be resonantly

> >>>> absorbed by molecules that are able to receive these particular

> >>>> signals.

> >>>>

> >>>>

> >>>>> PART 2

> >>>>> Data supporting the concept that cell components can respond

to

> >>>>>

> >>>>>

> >>>> external frequencies with metabolic changes

> >>>>

> >>>>

> >>>>> ·

> >>>>> In order for an electromagnetic field to activate a metabolic

> >>>>>

> >>>>>

> >>>> process in the body a field induced molecular change must occur.

> >>>>

> > This

> >

> >>>> section will discuss the physical, chemical and electrical

> >>>>

> > properties

> >

> >>>> of proteins and how electrical fields can affect the molecular

> >>>> structures and functions of proteins. " It is at the atomic level

> >>>>

> > that

> >

> >>>> physical processes, rather than chemical reactions in the fabric

of

> >>>> molecules, appear to shape the transfer of energy and the flow of

> >>>> signals in living systems (Adey, 1993a). "

> >>>>

> >>>>

> >>>>> · Proteins are sophisticated molecules that play critical

> >>>>>

> >>>>>

> >>>> structural and functional roles in the cells. Proteins help

provide

> >>>> cell structure, strength and flexibility. Proteins also have

> >>>> functional roles as signaling molecules in the processes of cell

> >>>> communication and as enzymes in the chemical reactions of cells.

> >>>>

> > The

> >

> >>>> functional properties of proteins in turn are dependent upon

their

> >>>> three-dimensional structure (Grattarola et al., 1998).

> >>>>

> >>>>

> >>>>> ·

> >>>>> Proteins that catalyze chemical reactions are called enzymes

> >>>>>

> >>>>>

> >>>> (Holyzclaw et al., 1991). The body's enzymes are natural

catalytic

> >>>> molecules that promote chemical reactions without themselves

being

> >>>> used up. Enzymes are specific for certain chemical substances

> >>>>

> > because

> >

> >>>> they recognize specific chemical structures both by their three-

> >>>> dimensional shape as well as by their chemical properties

> >>>>

> > (Jespersen,

> >

> >>>> 1997).

> >>>>

> >>>>

> >>>>> ·

> >>>>> Proteins embedded in cell membranes that act as signal devices

> >>>>>

> >>>>>

> >>>> are called receptors. Receptors respond to chemical signals from

> >>>>

> > the

> >

> >>>> blood stream to initiate chemical pathways within the cells and

to

> >>>> assist in the transport of materials into and out of cells

(

> >>>> and , 2000). The scientific data also shows that receptors

also

> >>>> respond to electric fields (Adey, 1993a).

> >>>>

> >>>>

> >>>>> ·

> >>>>> Enzymes and membrane receptors, like all proteins, are folded

> >>>>>

> >>>>>

> >>>> into 3-dimensional structures. The primary three-dimensional

> >>>> structure of a protein arises because each protein is composed of

a

> >>>> unique ordered sequence of amino acids. The proteins of human

cells

> >>>> are all made of chiral molecules called L-amino acids ( and

> >>>> , 2000).

> >>>>

> >>>>

> >>>>> ·

> >>>>> The location and sequence of amino acids, the location and

> >>>>>

> >>>>>

> >>>> sequence of negative and positive charges, and the interaction of

> >>>>

> > the

> >

> >>>> protein with water and other biological molecules determines the

> >>>> primary three-dimensional structure of a protein at body pH

> >>>> (Grattarola et al., 1998; and , 2000).

> >>>>

> >>>>

> >>>>> ·

> >>>>> Linus ing was the first scientist to discover that

specific

> >>>>>

> >>>>>

> >>>> sequences of amino acids in a protein can coil or wind itself and

> >>>> then transition into a helical shape called an alpha-helix

> >>>>

> > (ing,

> >

> >>>> 1988). This structure is particularly prominent in proteins that

> >>>>

> > are

> >

> >>>> embedded in cell membranes ( and , 2000).

> >>>>

> >>>>

> >>>>> ·

> >>>>> In electrical terms coils and helices are inductors,

transducers

> >>>>>

> >>>>>

> >>>> and antennas.

> >>>>

> >>>>

> >>>>> ·

> >>>>> The coil-to helix transition is a nonlinear phenomenon

> >>>>>

> >>>>>

> >>>> (Grattarola et al., 1998), which means that it can be triggered

by

> >>>> absolutely miniscule amounts of energy.

> >>>>

> >>>>

> >>>>> ·

> >>>>> The coil-to helix transition is a cooperative phenomenon

called

> >>>>>

> > a

> >

> >>>> two-state function, which is characteristic of any type of

> >>>>

> > electronic

> >

> >>>> or biological device appropriate for information processing

> >>>> (Grattarola et al., 1998).

> >>>>

> >>>>

> >>>>> ·

> >>>>> Enzymes and receptors are types of proteins that possess the

> >>>>>

> >>>>>

> >>>> ability to fluctuate back and forth between active and inactive

> >>>> states much like electrical switches that can either be set to an

> >>>>

> > on

> >

> >>>> or off position. This cyclical movement between the active

position

> >>>> and the rest position of these types of proteins involves a

> >>>> reversible shift in the distribution of electrical charges, which

> >>>> subsequently alters the 3-dimensional folding and chemical

binding

> >>>> sites of these proteins. This alteration in protein folding,

called

> >>>>

> > a

> >

> >>>> configurational or conformational change is accompanied by

changes

> >>>>

> > in

> >

> >>>> both the chemical reactivity and the electrical properties of

these

> >>>> proteins (Wuddel and Apell, 1995).

> >>>>

> >>>>

> >>>>> ·

> >>>>> For many years biologists have recognized that the triggering

> >>>>>

> >>>>>

> >>>> mechanism that turns on enzymes and receptors causing them to

> >>>> transition between their active and rest states involves chemical

> >>>> interactions where chemical compounds transfer electrical charges

> >>>> between one another. However new research has now proven that the

> >>>> transfer of electric charges does not always require a chemical

> >>>> carrier. In fact enzymes and receptors can also be activated by

> >>>> electric charges directly transferred from resonantly coupled

> >>>> electric fields (Derényi and Astumian, 1998) .This is because

> >>>>

> > the

> >

> >>>> intramolecular charge transfer that occurs in enzymes and

receptors

> >>>> undergoing conformational transitions within their cycle conveys

to

> >>>> these molecules the ability to transduce energy directly from

> >>>> oscillating electric fields (Astumian et al., 1989).

> >>>>

> >>>>

> >>>>> ·

> >>>>> A number of researchers, especially Ross Adey, have shown that

> >>>>>

> >>>>>

> >>>> weak electromagnetic fields may resonantly interact with the

> >>>> glycoproteins of the cell membrane acting like first messenger

> >>>> signals that activate intracellular enzymes (Adey, 1993b). These

> >>>> electromagnetic signals can create conformational changes in cell

> >>>> membrane proteins when these membrane proteins transductively

> >>>>

> > couple

> >

> >>>> with electromagnetic frequencies provided the frequencies are

> >>>>

> > within

> >

> >>>> certain amplitude and frequency windows (Adey, 1993b). This means

> >>>>

> > the

> >

> >>>> cell membrane proteins can act like electrical transducers that

> >>>> behave as on off electrical switches that activate chemical

> >>>>

> > processes

> >

> >>>> inside of the cell (Adey, 1980, 1981, 1988, 1993b; Adey et al.,

> >>>> 1982).

> >>>>

> >>>>

> >>>>> ·

> >>>>> " The essential molecular functions appear in fact to be

> >>>>>

> >>>>>

> >>>> determined by electromagnetic mechanisms. A possible role of

> >>>> molecular structures would be the carrying of electric charges,

> >>>>

> > which

> >

> >>>> generate, in the aqueous environment, a field specific to each

> >>>> molecule. Those exhibiting such coresonating or opposed fields

> >>>> ( " electroconformational coupling " ) could thus communicate, even

at

> >>>>

> > a

> >

> >>>> distance (Benveniste, 1993). "

> >>>>

> >>>>

> >>>>> ·

> >>>>> For example, it is well recognized by biologists that cell

> >>>>>

> >>>>>

> >>>> enzymes such as Na,KATPases require energy to pump ions such as

> >>>> sodium and potassium across cell membranes. However new data

shows

> >>>> that these enzymes can either be activated by chemical energy

> >>>>

> > derived

> >

> >>>> from ATP or by energy directly absorbed from electric fields (Xie

> >>>>

> > et

> >

> >>>> al., 1997). In this case energy from the electric field

substitutes

> >>>> for the energy normally provided chemically by ATP (Derényi

and

> >>>> Astumian, 1998). Any electromagnetic effect on a chemically based

> >>>> biological reaction in the body is dependent upon the electric or

> >>>> magnetic frequency sensitivity of the rate constant of the enzyme

> >>>> involved in the chemical reaction (Weaver et al., 2000). Membrane

> >>>> receptor proteins can also be activated by resonantly coupling to

> >>>> electric fields (Astumian and on, 1989).

> >>>>

> >>>>

> >>>>> ·

> >>>>> " If fields can affect enzymes and cells, [one should expect]

to

> >>>>>

> >>>>>

> >>>> be able to tailor a waveform as a therapeutic agent in much the

> >>>>

> > same

> >

> >>>> way as one now modulates chemical structures to obtain

> >>>> pharmacological selectivity and perhaps withhold many of the

side-

> >>>> effects common to pharmaceutical substances (Davey and Kell,

> >>>>

> > 1990). "

> >

> >>>>> ·

> >>>>> The key step necessary for this mechanism to work is to

produce

> >>>>>

> >>>>>

> >>>> an electric field in the body, which exactly matches the resonant

> >>>> frequency of the enzymatic process or membrane receptor that you

> >>>>

> > wish

> >

> >>>> to stimulate so that the enzyme or receptor is able to resonantly

> >>>> couple to the field. This is exactly how LifeWave patches work.

> >>>>

> >>>>

> >>>>> Biological Antennas

> >>>>> ·

> >>>>> Their shapes can classify antennas, and their shape determines

> >>>>>

> >>>>>

> >>>> their radiation pattern. Antennas emit power that is different at

> >>>> different angles (Carr, 2001).

> >>>>

> >>>>

> >>>>> ·

> >>>>> The cells of the body communicate with each other by chemical

> >>>>>

> >>>>>

> >>>> signal molecules that are either carried by the bloodstream to

> >>>>

> > cells

> >

> >>>> in distant locations or are released directly on the cell

surfaces

> >>>> from nerve fibers and local tissue cells (Nicholls et al., 2001).

> >>>>

> >>>>

> >>>>> ·

> >>>>> The binding of a signaling chemical to a cell membrane

receptor

> >>>>>

> >>>>>

> >>>> triggers an amplified biological response such as the opening of

a

> >>>> cell membrane ion channel, which allows the entry of minerals

like

> >>>> calcium into the cell. Other amplified responses include the

> >>>> activation of enzymes and secondary messenger signals (Mehrvar et

> >>>> al., 2000).

> >>>>

> >>>>

> >>>>> ·

> >>>>> It is not widely known, but cell membrane receptors can also

act

> >>>>>

> >>>>>

> >>>> like electrical antennas and transducers responding to signals of

> >>>> electrical fields of the right frequency and amplitude (Adey,

> >>>>

> > 1993a,

> >

> >>>> 1993b).

> >>>>

> >>>>

> >>>>> ·

> >>>>> Cell membrane receptors composed of proteins that have coil

and

> >>>>>

> >>>>>

> >>>> helical configurations can act as receiving antennas for

electrical

> >>>> fields as well as electrical transducers and electrical

inductors.

> >>>> These components are organized into complex cooperative arrays

that

> >>>> facilitate communication (signaling and information transfer)

> >>>>

> > between

> >

> >>>> cells in the body as well as between cells and the external

> >>>> environment (Gilman, 1987). The transducing element in cell

> >>>>

> > membrane

> >

> >>>> biosensor complexes couples a chemical or electrical signal to a

> >>>> biological response that might include the movement of minerals

> >>>>

> > into

> >

> >>>> the cell or a cascade of enzyme reactions (Mehrvar et al., 2000).

> >>>>

> >>>>

> >>>>> ·

> >>>>> Helical antennas produce directed beams when their diameter

and

> >>>>>

> >>>>>

> >>>> coil spacing are large fractions of the wavelength. They provide

> >>>> moderately wide bandwidth and circular polarized beams (Carr,

> >>>>

> > 2001).

> >

> >>>> When helical antennas are used the receiving helical antenna has

to

> >>>> be wound in the same direction as the sender's. Helical antennas,

> >>>> like DNA, can be stacked, which allows a way for a ell

> >>>> receptor/antenna to obtain high gain with only a few turns on

each

> >>>> helix.

> >>>>

> >>>>

> >>>>> ·

> >>>>> In summary it is my opinion that the structures of cells have

> >>>>>

> >>>>>

> >>>> components that have electronic features allowing cells to detect

> >>>>

> > and

> >

> >>>> respond to electrical frequencies that act as information signals

> >>>> triggering biological responses through the process of signal

> >>>> amplification.

> >>>>

> >>>>

> >>>>> The mechanism of resonant electrical frequency interactions

with

> >>>>>

> >>>>>

> >>>> cells

> >>>>

> >>>>

> >>>>> ·

> >>>>> The mechanism of resonant electrical frequency interactions

with

> >>>>>

> >>>>>

> >>>> cells includes the reception of the electrical signal/charge

> >>>>

> > transfer

> >

> >>>> by receptor antenna/transducers that are coupled to membrane

bound

> >>>>

> > G-

> >

> >>>> proteins that are also coupled to intracellular enzymes like

> >>>> adenylate cyclase.

> >>>>

> >>>>

> >>>>> ·

> >>>>> Membrane bound G-proteins and the intracellular enzymes that

> >>>>>

> > they

> >

> >>>> are coupled to form a complex of proteins that operate as an

> >>>> amplifier for the signal they receive. For example certain

> >>>>

> > G-proteins

> >

> >>>> are coupled to and activate specific intracellular enzymes that

in

> >>>> turn increase the cell concentrations of second messenger systems

> >>>> like cAMP. Increasing cell levels of cAMP in turn activates an

> >>>>

> > enzyme

> >

> >>>> called protein kinase A, which in turn activates other enzymes

such

> >>>> as hormone sensitive lipase ( and , 2000; Nicholls et

al.,

> >>>> 2001).

> >>>>

> >>>>

> >>>>> ·

> >>>>> Different electrical frequencies will activate different

> >>>>>

> >>>>>

> >>>> receptors, different Gproteins, different intracellular enzymes

and

> >>>> different second messenger systems thus producing different

> >>>> biological reactions and cascades.

> >>>>

> >>>>

> >>>>> ·

> >>>>> Certain steps must be taken in order for a clinician to be

able

> >>>>>

> >>>>>

> >>>> to electrically modulate the biological reactions he or she wants

> >>>>

> > to

> >

> >>>> influence. He or she must first identify, choose, and apply the

> >>>> correct electrical frequencies that activate the signaling

> >>>>

> > mechanism

> >

> >>>> involved in turning on that biological process. In addition an

> >>>> individual who makes an effort to improve the health of their

cell

> >>>> membranes by proper modification of the diet with food and or

> >>>> supplements may receive even greater benefits from this

technology.

> >>>>

> >>>>

> >>>>> The principle of magnetic induction

> >>>>> ·

> >>>>> In 1831 Faraday, one of the first electrical pioneers,

> >>>>>

> >>>>>

> >>>> first described the phenomenon of electromagnetic induction. He

> >>>> discovered that he could produce a measurable electrical current

in

> >>>>

> > a

> >

> >>>> wire conductor simply by moving a magnet near the wire. This

> >>>> discovery became the basis for Faraday's Law of Induction, which

is

> >>>>

> > a

> >

> >>>> basic law of electromagnetism ( and Childers, 1990).

> >>>>

> >>>>

> >>>>> ·

> >>>>> The LifeWave patch system has been designed to utilize the

> >>>>>

> >>>>>

> >>>> principle of induction. The natural substances in these patches

are

> >>>> in a sense function as small electronic conductors and antennas.

> >>>>

> > When

> >

> >>>> the body's oscillating magnetic field interacts with these

> >>>> electrically active molecules in the patches, the magnetic field

> >>>> induces the creation of electric fields through the Faraday

effect.

> >>>> The electrical field produced contains the specific resonant

> >>>> frequencies of the materials contained within the patches. The

> >>>> electromagnetic field that is naturally present in addition acts

> >>>>

> > like

> >

> >>>> a transmitter of a carrier wave so that these frequencies can be

> >>>> carried into the body.

> >>>>

> >>>>

> >>>>> ·

> >>>>> The interaction of the body's magnetic field with LifeWave

> >>>>>

> >>>>>

> >>>> patches induces electrical current flows of specific frequencies

in

> >>>> the body's tissues. The specific sets of frequencies produced by

> >>>>

> > the

> >

> >>>> patches have been selected to activate certain chemical reactions

> >>>>

> > and

> >

> >>>> biological processes. This technology can support: the use of fat

> >>>>

> > as

> >

> >>>> an energy source, the activation of muscle contraction by

calcium,

> >>>> which increases the recruitment of muscle fibers. This translates

> >>>> into more energy and greater endurance.

> >>>>

> >>>>

> >>>>> How LIFEWAVE patches interface with the body's thermomagnetic

> >>>>>

> >>>>>

> >>>> field, the transformer analogy

> >>>>

> >>>>

> >>>>> ·

> >>>>> A transformer is a device that transfers electrical energy

from

> >>>>>

> >>>>>

> >>>> one electric circuit to another, by the principle of magnetic

> >>>> induction without changing the frequency.

> >>>>

> >>>>

> >>>>> ·

> >>>>> A transformer has two windings or coils the first called the

> >>>>>

> >>>>>

> >>>> primary winding is the coil that draws power/ or frequency from

the

> >>>> source. The secondary winding is the coil that delivers the

energy

> >>>>

> > to

> >

> >>>> the load. Magnetic transfer of voltage or frequencies only occurs

> >>>>

> > if

> >

> >>>> the magnetic field is oscillating/changing strength (Van

> >>>>

> > Valkenburgh,

> >

> >>>> Nooger and Neville, Inc., 1992).

> >>>>

> >>>>

> >>>>> ·

> >>>>> An isolation transformer is a special transformer that is

> >>>>>

> >>>>>

> >>>> designed so that the signal going out equals the signal going in.

> >>>>

> > In

> >

> >>>> LifeWave technology the signal going out is produced by the

> >>>> interaction of the body's fluctuating thermomagnetic field with

the

> >>>> antenna/conductor created by the organic matrix of the patch.

> >>>>

> >>>>

> >>>>> ·

> >>>>> The unique proprietary mixture of Life Wave technology

LIFEWAVE

> >>>>>

> >>>>>

> >>>> patches forms a matrix antenna/conductor system that acts like a

> >>>> primary coil of a transformer when it interacts with the body's

> >>>> magnetic field.

> >>>>

> >>>>

> >>>>> ·

> >>>>> The oscillating thermomagnetic field of the body creates

> >>>>>

> > magnetic

> >

> >>>> induction where the electrical frequencies generated from the

> >>>> materials in the patch frequency modulate the body's oscillating

> >>>> magnetic field.

> >>>>

> >>>>

> >>>>> ·

> >>>>> The interaction of the patches with the body's oscillating

> >>>>>

> >>>>>

> >>>> magnetic field creates local vortexes in the magnetic field over

> >>>>

> > the

> >

> >>>> area where the patches are located. The magnetic field is thus

> >>>> modulated by this interaction with the patches and it acts as an

> >>>> information carrier of a harmonic electrical energy field.

> >>>>

> >>>>

> >>>>> ·

> >>>>> The resonant interaction of the electrical signals with

> >>>>>

> > molecules

> >

> >>>> that are already pretuned to the exact frequencies allows

> >>>>

> > information

> >

> >>>> to be passed to the receiving molecules.

> >>>>

> >>>>

> >>>>> ·

> >>>>> Receiving molecules in cell membranes and the cell function

like

> >>>>>

> >>>>>

> >>>> the secondary windings of a transformer. These cellular

components

> >>>> function as antennas, electrical transducers and electrical

> >>>>

> > inductors

> >

> >>>> so that the cell demodulates and receives the signal information

by

> >>>> resonant energy transfer. Resonant absorption of electrical

> >>>> frequencies by biological molecules results in the induction of

> >>>> electron flows in the conductive liquid crystal molecules of the

> >>>> body.

> >>>>

> >>>>

> >>>>> ·

> >>>>> The resonant transfer of specific frequency information to the

> >>>>>

> >>>>>

> >>>> cells is amplified by cellular mechanisms and this information

can

> >>>> activate or enhance certain specific biological processes that

can

> >>>>

> > be

> >

> >>>> selected for activation by the choice of materials placed in the

> >>>> patches to provide a specific set of electrical frequencies.

> >>>>

> >>>>

> >>>>> ·

> >>>>> For example, use of natural organic materials such as chiral

L-

> >>>>>

> >>>>>

> >>>> amino acids in the patches permits the production of electrical

> >>>> fields whose frequencies exactly match the resonant frequencies

of

> >>>> certain specific natural biological molecules.

> >>>>

> >>>>

> >>>>> LIFEWAVE patch references:

> >>>>> 1.

> >>>>> Adey WR. Frequency and power windowing in tissue interactions

> >>>>>

> >>>>>

> >>>> with weak electromagnetic fields. Proc IEEE 1980;68 (1):119-125.

> >>>>

> >>>>

> >>>>> 2. Adey WR. Tissue interactions with nonionizing

electromagnetic

> >>>>>

> >>>>>

> >>>> fields. Physiol Rev 1981; 61:435-514.

> >>>>

> >>>>

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1997;72:2496-2502.</xbody><!--

> >>>> toctype = X-unknown --><!-- toctype = text --><!-- text --><!--

END

> >>>> TOC -->

> >>>>

> >>>>

> >>>>>

> >>>>>

> >>>>>

> >>>>>

> >>>>>

> >>>>>

> >>>>>

> >>>>>

> > --------------------------------------------------------------------

> >

> >>>> ----------

> >>>>

> >>>>

> >>>>> No virus found in this incoming message.

> >>>>> Checked by AVG - http://www.avg.com

> >>>>> Version: 8.0.169 / Virus Database: 270.6.21/1671 - Release

Date:

> >>>>>

> >>>>>

> >>>> 9/14/2008 7:16 AM

> >>>>

> >>>>

> >>>

> >>> ------------------------------------

> >>>

> >>>

[Guest guest]

What I got out of it was that everything has energy and we can

determine our own with positive thinking. Positive thinking about our

children, treatments, the people around us, events, will have an

positive impact on our children's healing. McCarthy also made

this one of her main points in her keynote address. Of all the messages

I heard at the conference, this has had the most possitive impact on

our course of autism. No matter what, find a positive.

natasa778 wrote:

Hi , was there anything of importance or interest in his

presentation that was not shown on slides? what was his take-home

message in terms of treatments?

tia

Natasa

yes but people are wanting reports NOT from lifewave, that is

the

problem. there are reports form the CDC that vaccinations are

all

safe and don't cause autism but they are all funded from the cdc

WITH

a vested interest, people are wanting to see outside source info

Recovering from Autism is a marathon

NOT a sprint, but FULLY possible!

Read more about it on my BLOGs at

http://www.myspace.com/christelking

http://foggyrock.com/MyPage/recoveringwishes

http://www.facebook.com/profile.php?id=677063169

The Science Behind LW patches

PS From Sue I hope the report below will help your

understanding of how the LW patches work.

This is part of a 23 page report.... pages 14-23

The Science Behind LifeWave Technology Patches

BY Steve Haltiwanger, M.D., C.C.N.

LIFEWAVE patches are like organic radio stations

·

One analogy that may help you understand how LifeWave patches

work is to think of them as being like organic radio stations.

Lets

say you own a radio station. Your radio station will have to be

licensed by the federal government to send out a specific

frequency

called a carrier wave across the airwaves. The carrier wave that

your

radio station transmits is used to carry or piggyback other

frequencies that contain information signals. If you are licensed

to

run an FM radio station your equipment will use frequency

modulation

to encode information on the carrier wave that your station

transmits. In order for the radios in people's homes to receive

your

radio transmission their radios have to be tuned to carrier wave

of

your radio station so that they can demodulate the information

signals.

·

Your radio station will use an active transmitter that derives

energy from electricity to send out electromagnetic frequencies

that

lie in a particular portion of the electromagnetic spectra we

call

radio waves. Before you begin operation of your radio station you

are

first going to have to decide what information you want your

radio

station to transmit. If you choose to send information that

nobody

wants to listen to you will soon be out of business. Therefore,

you

have to be very selective in the information that you transmit.

If

a

signal is sent from one place and received at another place then

information has been successfully transmitted and received.

·

Just as the mayor of a city can get on your radio station and

tell the citizens that the community has a blood shortage. Those

people who respond to the information they received on their

radios

can then go to the Red Cross and donate blood. What we have is

the

phenomenon where information has been transmitted from one place

to

another and a response occurs.

·

LifeWave patch technology was invented with the recognition

that

the body is composed of molecules and that each chemical reaction

in

the body uses very specific combinations of molecules and that

frequencythese molecules will respond to specific signals or

codes.

In general molecules in the body are not isolated substances

dissolved in the fluid of cells instead molecules link to other

molecules to form more complex structures.

·

Every molecule and molecular complex of the body is like the

glass in the Memorex commercial. Each molecule and molecular

complex

has its own specific frequency at which it can resonantly absorb

information or energy. In a sense these molecular structures are

like

a miniature radio receivers. When information is sent at the

frequency code that these molecular radios are pretuned to

receive,

information or energy can be directly transmitted to those

molecules

in the body. This process of energy transfer to specific

molecular

complexes can assist in the activation of the chemical reactions

these molecules are involved in.

·

LifeWave patches were designed to function as passive

transmitter

systems. When the patches are placed on the skin the materials in

magnetic field the patches interact with and modulate body's to

produce certain specific electrical signals. In addition the

body's

natural magnetic field is the carrier that takes these signals

into

the body.

·

LifeWave patch technology does not create chemical reactions

in

the body it only assists biological reactions that are already

taking

place to work more efficiently. Schmidt has basically

investigated what signals are needed to turn on certain

biological

reactions and invented a patch technology that can effectively

deliver these signals into the body.

·

In summary, LIFEWAVE patches contain organic molecules that

are

naturally present in the human body. These substances have

already

been determined to be safe by the FDA. However instead of

actually

putting the molecules themselves into the body LIFEWAVE patches

produce specific electrical signals, which will be resonantly

absorbed by molecules that are able to receive these particular

signals.

PART 2

Data supporting the concept that cell components can respond

to

external frequencies with metabolic changes

·

In order for an electromagnetic field to activate a metabolic

process in the body a field induced molecular change must occur.

This

section will discuss the physical, chemical and electrical

properties

of proteins and how electrical fields can affect the molecular

structures and functions of proteins. "It is at the atomic level

that

physical processes, rather than chemical reactions in the fabric

of

molecules, appear to shape the transfer of energy and the flow of

signals in living systems (Adey, 1993a)."

· Proteins are sophisticated molecules that play critical

structural and functional roles in the cells. Proteins help

provide

cell structure, strength and flexibility. Proteins also have

functional roles as signaling molecules in the processes of cell

communication and as enzymes in the chemical reactions of cells.

The

functional properties of proteins in turn are dependent upon

their

three-dimensional structure (Grattarola et al., 1998).

·

Proteins that catalyze chemical reactions are called enzymes

(Holyzclaw et al., 1991). The body's enzymes are natural

catalytic

molecules that promote chemical reactions without themselves

being

used up. Enzymes are specific for certain chemical substances

because

they recognize specific chemical structures both by their three-

dimensional shape as well as by their chemical properties

(Jespersen,

1997).

·

Proteins embedded in cell membranes that act as signal devices

are called receptors. Receptors respond to chemical signals from

the

blood stream to initiate chemical pathways within the cells and

to

assist in the transport of materials into and out of cells

(

and , 2000). The scientific data also shows that receptors

also

respond to electric fields (Adey, 1993a).

·

Enzymes and membrane receptors, like all proteins, are folded

into 3-dimensional structures. The primary three-dimensional

structure of a protein arises because each protein is composed of

a

unique ordered sequence of amino acids. The proteins of human

cells

are all made of chiral molecules called L-amino acids ( and

, 2000).

·

The location and sequence of amino acids, the location and

sequence of negative and positive charges, and the interaction of

the

protein with water and other biological molecules determines the

primary three-dimensional structure of a protein at body pH

(Grattarola et al., 1998; and , 2000).

·

Linus ing was the first scientist to discover that

specific

sequences of amino acids in a protein can coil or wind itself and

then transition into a helical shape called an alpha-helix

(ing,

1988). This structure is particularly prominent in proteins that

are

embedded in cell membranes ( and , 2000).

·

In electrical terms coils and helices are inductors,

transducers

and antennas.

·

The coil-to helix transition is a nonlinear phenomenon

(Grattarola et al., 1998), which means that it can be triggered

by

absolutely miniscule amounts of energy.

·

The coil-to helix transition is a cooperative phenomenon

called

a

two-state function, which is characteristic of any type of

electronic

or biological device appropriate for information processing

(Grattarola et al., 1998).

·

Enzymes and receptors are types of proteins that possess the

ability to fluctuate back and forth between active and inactive

states much like electrical switches that can either be set to an

on

or off position. This cyclical movement between the active

position

and the rest position of these types of proteins involves a

reversible shift in the distribution of electrical charges, which

subsequently alters the 3-dimensional folding and chemical

binding

sites of these proteins. This alteration in protein folding,

called

a

configurational or conformational change is accompanied by

changes

in

both the chemical reactivity and the electrical properties of

these

proteins (Wuddel and Apell, 1995).

·

For many years biologists have recognized that the triggering

mechanism that turns on enzymes and receptors causing them to

transition between their active and rest states involves chemical

interactions where chemical compounds transfer electrical charges

between one another. However new research has now proven that the

transfer of electric charges does not always require a chemical

carrier. In fact enzymes and receptors can also be activated by

electric charges directly transferred from resonantly coupled

electric fields (Derényi and Astumian, 1998) .This is because

the

intramolecular charge transfer that occurs in enzymes and

receptors

undergoing conformational transitions within their cycle conveys

to

these molecules the ability to transduce energy directly from

oscillating electric fields (Astumian et al., 1989).

·

A number of researchers, especially Ross Adey, have shown that

weak electromagnetic fields may resonantly interact with the

glycoproteins of the cell membrane acting like first messenger

signals that activate intracellular enzymes (Adey, 1993b). These

electromagnetic signals can create conformational changes in cell

membrane proteins when these membrane proteins transductively

couple

with electromagnetic frequencies provided the frequencies are

within

certain amplitude and frequency windows (Adey, 1993b). This means

the

cell membrane proteins can act like electrical transducers that

behave as on off electrical switches that activate chemical

processes

inside of the cell (Adey, 1980, 1981, 1988, 1993b; Adey et al.,

1982).

·

"The essential molecular functions appear in fact to be

determined by electromagnetic mechanisms. A possible role of

molecular structures would be the carrying of electric charges,

which

generate, in the aqueous environment, a field specific to each

molecule. Those exhibiting such coresonating or opposed fields

("electroconformational coupling") could thus communicate, even

at

a

distance (Benveniste, 1993)."

·

For example, it is well recognized by biologists that cell

enzymes such as Na,KATPases require energy to pump ions such as

sodium and potassium across cell membranes. However new data

shows

that these enzymes can either be activated by chemical energy

derived

from ATP or by energy directly absorbed from electric fields (Xie

et

al., 1997). In this case energy from the electric field

substitutes

for the energy normally provided chemically by ATP (Derényi

and

Astumian, 1998). Any electromagnetic effect on a chemically based

biological reaction in the body is dependent upon the electric or

magnetic frequency sensitivity of the rate constant of the enzyme

involved in the chemical reaction (Weaver et al., 2000). Membrane

receptor proteins can also be activated by resonantly coupling to

electric fields (Astumian and on, 1989).

·

"If fields can affect enzymes and cells, [one should expect]

to

be able to tailor a waveform as a therapeutic agent in much the

same

way as one now modulates chemical structures to obtain

pharmacological selectivity and perhaps withhold many of the

side-

effects common to pharmaceutical substances (Davey and Kell,

1990)."

·

The key step necessary for this mechanism to work is to

produce

an electric field in the body, which exactly matches the resonant

frequency of the enzymatic process or membrane receptor that you

wish

to stimulate so that the enzyme or receptor is able to resonantly

couple to the field. This is exactly how LifeWave patches work.

Biological Antennas

·

Their shapes can classify antennas, and their shape determines

their radiation pattern. Antennas emit power that is different at

different angles (Carr, 2001).

·

The cells of the body communicate with each other by chemical

signal molecules that are either carried by the bloodstream to

cells

in distant locations or are released directly on the cell

surfaces

from nerve fibers and local tissue cells (Nicholls et al., 2001).

·

The binding of a signaling chemical to a cell membrane

receptor

triggers an amplified biological response such as the opening of

a

cell membrane ion channel, which allows the entry of minerals

like

calcium into the cell. Other amplified responses include the

activation of enzymes and secondary messenger signals (Mehrvar et

al., 2000).

·

It is not widely known, but cell membrane receptors can also

act

like electrical antennas and transducers responding to signals of

electrical fields of the right frequency and amplitude (Adey,

1993a,

1993b).

·

Cell membrane receptors composed of proteins that have coil

and

helical configurations can act as receiving antennas for

electrical

fields as well as electrical transducers and electrical

inductors.

These components are organized into complex cooperative arrays

that

facilitate communication (signaling and information transfer)

between

cells in the body as well as between cells and the external

environment (Gilman, 1987). The transducing element in cell

membrane

biosensor complexes couples a chemical or electrical signal to a

biological response that might include the movement of minerals

into

the cell or a cascade of enzyme reactions (Mehrvar et al., 2000).

·

Helical antennas produce directed beams when their diameter

and

coil spacing are large fractions of the wavelength. They provide

moderately wide bandwidth and circular polarized beams (Carr,

2001).

When helical antennas are used the receiving helical antenna has

to

be wound in the same direction as the sender's. Helical antennas,

like DNA, can be stacked, which allows a way for a ell

receptor/antenna to obtain high gain with only a few turns on

each

helix.

·

In summary it is my opinion that the structures of cells have

components that have electronic features allowing cells to detect

and

respond to electrical frequencies that act as information signals

triggering biological responses through the process of signal

amplification.

The mechanism of resonant electrical frequency interactions

with

cells

·

The mechanism of resonant electrical frequency interactions

with

cells includes the reception of the electrical signal/charge

transfer

by receptor antenna/transducers that are coupled to membrane

bound

G-

proteins that are also coupled to intracellular enzymes like

adenylate cyclase.

·

Membrane bound G-proteins and the intracellular enzymes that

they

are coupled to form a complex of proteins that operate as an

amplifier for the signal they receive. For example certain

G-proteins

are coupled to and activate specific intracellular enzymes that

in

turn increase the cell concentrations of second messenger systems

like cAMP. Increasing cell levels of cAMP in turn activates an

enzyme

called protein kinase A, which in turn activates other enzymes

such

as hormone sensitive lipase ( and , 2000; Nicholls et

al.,

2001).

·

Different electrical frequencies will activate different

receptors, different Gproteins, different intracellular enzymes

and

different second messenger systems thus producing different

biological reactions and cascades.

·

Certain steps must be taken in order for a clinician to be

able

to electrically modulate the biological reactions he or she wants

to

influence. He or she must first identify, choose, and apply the

correct electrical frequencies that activate the signaling

mechanism

involved in turning on that biological process. In addition an

individual who makes an effort to improve the health of their

cell

membranes by proper modification of the diet with food and or

supplements may receive even greater benefits from this

technology.

The principle of magnetic induction

·

In 1831 Faraday, one of the first electrical pioneers,

first described the phenomenon of electromagnetic induction. He

discovered that he could produce a measurable electrical current

in

a

wire conductor simply by moving a magnet near the wire. This

discovery became the basis for Faraday's Law of Induction, which

is

a

basic law of electromagnetism ( and Childers, 1990).

·

The LifeWave patch system has been designed to utilize the

principle of induction. The natural substances in these patches

are

in a sense function as small electronic conductors and antennas.

When

the body's oscillating magnetic field interacts with these

electrically active molecules in the patches, the magnetic field

induces the creation of electric fields through the Faraday

effect.

The electrical field produced contains the specific resonant

frequencies of the materials contained within the patches. The

electromagnetic field that is naturally present in addition acts

like

a transmitter of a carrier wave so that these frequencies can be

carried into the body.

·

The interaction of the body's magnetic field with LifeWave

patches induces electrical current flows of specific frequencies

in

the body's tissues. The specific sets of frequencies produced by

the

patches have been selected to activate certain chemical reactions

and

biological processes. This technology can support: the use of fat

as

an energy source, the activation of muscle contraction by

calcium,

which increases the recruitment of muscle fibers. This translates

into more energy and greater endurance.

How LIFEWAVE patches interface with the body's thermomagnetic

field, the transformer analogy

·

A transformer is a device that transfers electrical energy

from

one electric circuit to another, by the principle of magnetic

induction without changing the frequency.

·

A transformer has two windings or coils the first called the

primary winding is the coil that draws power/ or frequency from

the

source. The secondary winding is the coil that delivers the

energy

to

the load. Magnetic transfer of voltage or frequencies only occurs

if

the magnetic field is oscillating/changing strength (Van

Valkenburgh,

Nooger and Neville, Inc., 1992).

·

An isolation transformer is a special transformer that is

designed so that the signal going out equals the signal going in.

In

LifeWave technology the signal going out is produced by the

interaction of the body's fluctuating thermomagnetic field with

the

antenna/conductor created by the organic matrix of the patch.

·

The unique proprietary mixture of Life Wave technology

LIFEWAVE

patches forms a matrix antenna/conductor system that acts like a

primary coil of a transformer when it interacts with the body's

magnetic field.

·

The oscillating thermomagnetic field of the body creates

magnetic

induction where the electrical frequencies generated from the

materials in the patch frequency modulate the body's oscillating

magnetic field.

·

The interaction of the patches with the body's oscillating

magnetic field creates local vortexes in the magnetic field over

the

area where the patches are located. The magnetic field is thus

modulated by this interaction with the patches and it acts as an

information carrier of a harmonic electrical energy field.

·

The resonant interaction of the electrical signals with

molecules

that are already pretuned to the exact frequencies allows

information

to be passed to the receiving molecules.

·

Receiving molecules in cell membranes and the cell function

like

the secondary windings of a transformer. These cellular

components

function as antennas, electrical transducers and electrical

inductors

so that the cell demodulates and receives the signal information

by

resonant energy transfer. Resonant absorption of electrical

frequencies by biological molecules results in the induction of

electron flows in the conductive liquid crystal molecules of the

body.

·

The resonant transfer of specific frequency information to the

cells is amplified by cellular mechanisms and this information

can

activate or enhance certain specific biological processes that

can

be

selected for activation by the choice of materials placed in the

patches to provide a specific set of electrical frequencies.

·

For example, use of natural organic materials such as chiral

L-

amino acids in the patches permits the production of electrical

fields whose frequencies exactly match the resonant frequencies

of

certain specific natural biological molecules.

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