Arasys Science:

1. Uses advanced MENS technology to resonate the biological signal that the brain sends to the nerve in control of the muscle.
2. Arasys signal is built with up to 1,000 waveforms composed on the basis of empirical and clinical research (a total of 17 years) by the co-inventor of the first pacemaker.
3. Arasys signal targets the nerve in control of the muscle and not the muscle as do muscle stimulators.
4. Arasys resonance of the neuron signal results in a full muscle contraction that has the rhythm and potency of strenuous exercise without the effort.
5. Arasys effortless workout gets you straight to the fat burning stage without the gym burnout. The Arasys procedure utilizes fat as an energy source. It bypasses aerobic (requiring oxygen) glucose burning as well as the anaerobic (without oxygen) energy supply process that converts pyruvic acid molecules to lactic acid.

HOW IS ARASYS DIFFERENT FROM MUSCLE STIMULATORS

Arasys uses microcurrent to signal the nerve in charge of the muscle contraction by resonating the brain signal at the nerve synapse.

MILIAMP MUSCLE STIMULATION VS. MENS SIGNAL TO THE NERVE:

Although the glucose molecule holds plenty of chemical energy, it cannot be used directly for muscle contraction. Instead muscle cells must transfer their incoming glucose supplies into the more readily utilizable form of ATP.

1. MUSCLE STIMULATION: During muscle stimulation, the outside of the muscle cell membrane is more positive than the inside. An electrical stimulus causes a reversal of this polarity, causing the muscle to twitch. The energy that powers this process comes through ATP that acts as a molecular motor powering movement. Maintaining the availability of ATP for muscle contraction is the limiting factor, since ATP is not stored in large amounts in the skeletal muscle. Research has consistently shown that Miliamp (one over a thousand of an amp) depletes ATP. Muscle stimulators work with miliamps, quickly depleting the limited ATP supply in the skeletal muscle.
2. SIGNAL TO THE NERVE: Nerve tissue (neurons and glia cells) has the ability to generate and conduct electrical signals in the body; it can communicate. These electrical messages are managed by nerve tissue in the brain and transmitted down the spinal cord to the body. During exercise, an electrical signal travels from the brain to the neuromuscular junctions, where a motor neuron attaches to the muscle. Calcium is released from its storage area bringing about a muscle contraction. As the nerve impulse reaches the junction, Acetycholine & ATP are co-released from the electromotor nerve terminals. ATP involved in the neuronal process does not have the limitations it does during muscle stimulation that draws on the limited supply of ATP stored in the skeletal muscle. A number of research studies indicate that an important advantage of microcurrent stimulation is that it increases ATP up to 500%.

NEURO-RESONANCE VS STIMULATION:

Neuro-resonance occurs when a signal harmonizes with another signal or a process. Neurons are prone to oscillate at certain frequencies. Research has shown that inter-neuronal feedback is the basis for neuronal oscillations rather than intrinsic autonomous oscillations of single cells (Victor et al 1988). Targeting the motor nerve rather than the muscle requires a complex signal that resonates with the biological signal transmitted to the nerve membrane during movement – e.g., a signal that involves an equivalent composition of an analogous number of frequencies. Neuro-resonance signifies harmony with a biological activity.

Stimulation reflects an increase of a non-specific activity that may or may not be beneficial or in harmony with the body.

WHAT DOES ARASYS DO?

1. Clinical studies report that Arasys burns fat to build muscle.
2. Muscle contraction enhances lymphatic drainage and blood circulation.
3. Increased circulation and lymphatic drainage helps reduction of cellulite.
4. Clinical studies on the Arasys report significant inch loss and increased metabolic rate.
5. Inch loss after Arasys treatments is reportedly significant with individuals suspected to have visceral fat.
6. Arasys clients report enhanced health and an overall sense of well-being.

ARASYS SQUARE WAVEFORM:

1. Arasys square waveform is consistent with the square micro-signals of neurons reported by Erwin Neher (Nobel Prize, 1991).
2. It is constructed with up to 1,000 frequencies researched at London University and BIS for 17 years.
3. Frequencies are combined like symbols programmed in a specific sequence to form a computer command.
4. Frequencies intertwine into the square waveform that resonates the brain signal used to communicate with neuron cells during regular exercise.

How and why Arasys was invented

Arasys was invented and built in 1994 in London University by Gerry Pollock, the co-inventor of the first pacemaker and Donald Gilbert, a renown Cellular Biochemist. It was originally intended for the treatment of Multiple Sclerosis and Muscle Atrophy. It gained popularity in the field of cosmetics as a result of its high speed muscle building, inch loss, visceral fat reduction, and its dramatic effects in tightening abdominal muscles after pregnancy.

It was redesigned in 2004 to include modern electronics at Bi Centre Innova Science (BIS), a European Community Funded Science Park in the UK. After 17 years of empirical electronic research it was upgraded in 2005 for fine tuning of its complex square waveform that signals the nerve in charge of the muscle. The most recent 2006 upgrade empowered the Arasys with additional effectiveness and comfort.

Gerry Pollock, the co-inventor of the first pacemaker raised the standards of MENS (Micro-current Electrical Neuromuscular Stimulation) with Arasys exclusive square waveform that resonates the brain's biological signal to neuronal cells.

In studying neuronal cells Dr. Erwin Neher reported: "The square-wave nature of the signals was proof of the hypothesis that channels in biological membranes open and close stochastically in an all-or-none manner. The fact that similar records could be obtained both in our Göttingen laboratory and in the laboratory of Charles F. Stevens at Yale gave us confidence that they were not the result of some local demon, but rather signals of biological significance."
--Erwin Neher, 1991 Nobel Prize in Medicine and Physiology.

Gerry Pollock's proprietary waveform is built with up to 1,000 frequencies that form the fine tuned Arasys signal. Arasys frequencies have been combined to resonate the biological signal that the brain sends to the nerve in charge of the muscle prior to movement. Seventeen years of research on the Arasys have been dedicated in discovering and combining the specific frequencies that would intertwine to deliver a signal that can closely resonate the specific brain signal that the nerve understands.

The Arasys signal has the clarity and accuracy that makes it similar to the biological signal which singles out Arasys as a unique technology, despite several attempts to duplicate it. Pollocks' ingenuity and meticulous empirical experimentation has established Arasys as a superior technology. Pollock continues research and development at the Innova Science Park, a European community funded research center.

Arasys is unlike most Electrical Muscle Stimulators (EMS) which merely stimulate the muscle. Muscle cells do not receive or understand brain signals. Only muscle neurons understand the brain signal that Arasys has been designed to resonate. The muscle contraction caused by signaling the nerve that controls the muscle is a far more complicated process than mere muscle stimulation. Muscle stimulation is the result of a change occurring at the electrical gradient across the muscle cell membrane. The outside is more positive than the inside. Stimulus causes an instantaneous reversal of this polarity, causing the muscle to contract. On the other hand, the Arasys signal targets the neuromuscular junctions which are the point where a motor neuron attaches to a muscle. Acetycholine is released from the axon end of the nerve cell when a nerve impulse reaches the junction. A wave of electrical changes is produced in the muscle cell when the acetylcholine binds to receptors on its surface. Calcium is released from its storage area in the cell's endoplasmic reticulum, which is a network of membranous tubules in the cytoplasm of a cell, involved in the production of phospholipids (building blocks of cellular membrane) proteins, and other functions. Each impulse from a nerve cell causes calcium release to bring about a muscle contraction. In conclusion, Arasys works through a much more sophisticated and complex manner when compared to EMS devices that merely stimulate the muscle. Unlike most EMS devices that more or less twich the muscle, Arasys results in a full muscle contraction that is analogous to the movement that occurs during regular exercise.

Bioenergetics and Biocommunication
Computation in Cellular and Molecular Biological Systems (R. Cuthbertson, M. Holcombe and R. Paton, eds.), pp.251-264, World Scientific, Singapore, 1996.
Abstract: Lord Kelvin was impressed with how organisms seem to have energy at will, whenever and wherever required, and in a perfectly coordinated way. That is at once the problem of bioenergetics -- how organisms can have energy so readily -- and of biocommunication -- how the energy mobilizing activities are organized as a whole. Similarly, Schrödinger alluded to the ability of organisms to use the energy they feed on to build up and maintain their dynamic organization. The intuition of both physicists is that energy and organization are intimately linked.
Full document

The Past, Present, and Future of the ElectroDermal Screening System (EDSS)
Professor Julia J. Tsuei, M.D., F.A.C.O.G., National Yang-Ming University School of Medicine
(Journal of Advancement in Medicine, Volume 8, Number 4, Winter 1995)
Abstract: The author presents the past, present, and possible future of the Electrodermal Screening System (EDSS), EDS Test (EDST), and EDS Device (EDSD) and relates them to procedures that preceded them: traditional acupuncture based on meridian theory and electro-acupuncture according to Voll.
The author and others have produced a body of scientific data and literature that demonstrate efficacy of the EDSS and offers plausible mechanisms of action. Use of the EDSS and EDSD for diagnostic screening and their possible integration into a modern health care system are reported.
Full document

Electromedicine in NeuroRehabilitation
Daniel L. Kirsch, Ph.D.
NeuroRehabilitation 17 (2002), IOS Press.
Abstract: Electromedicine is therapeutic intervention via electricity or magnetism, rather than through chemicals. As with all medical disciplines, it is also an attempt at understanding observable phenomenon. While the use of electromedicine in clinical practice is achieving an impressive reemergence based on the superior efficacy of modern technologies, there is still much to be learned about how various modalities work. To explain the observable phenomenon, we must look beyond our current understanding of physiology. This issue contributes to that mission while also providing the results of original research and practical information useful to the clinician.
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Functional Electrical Stimulation Enhancement of Upper Extremity Functional Recovery During Stroke Rehabilitation: A Pilot Study.
Gad Alon, PhD, PT, Alan F. Levitt, MD, and Patricia A.McCarthy, OTR
Neurorehabil Neural Repair 2007; 21; 207 originally published online Mar 16, 2007
DOI: 10.1177/1545968306297871
Abstract: Objective. To test if functional electrical stimulation (FES) can enhance the recovery of upper extremity function during early stroke rehabilitation. Methods. Open-label block-randomized trial, begun during inpatient rehabilitation and continued at the patients’ home. Patients were assigned to either FES combined with task-specific upper extremity rehabilitation (n = 7) or a control group that received task-specific therapy alone (n = 8) over 12 weeks.
Full document

Bloacking Out The Pain
James Woessner, MD, PhD
Practical PAIN MANAGEMENT, Mar/Apr 2002
Abstract: Electric nerve blocks (ENBs) represent a long tradition of the use of electricity in medicine5 along with electrocardiography (EKG), elec-troencephalography (EEG), electromyography (EMG), transcutaneous electrical nerve stimulation (TENS) for low back pain, electroconversion therapy (ECT) for depression, dorsal column stimulators (DCS) for chronic pain control, bone growth stimulators after orthopedic surgery, and neuromuscular stimulation for disuse atrophy — all capitalizing on the electrical properties of the human body.
Full document

Chronic Motor Dysfunction After Stroke: Recovering Wrist and Finger Extension by Electromyography-Triggered Neuromuscular Stimulation
James Cauraugh, PhD; Kathye Light, PhD, PT; Sangbum Kim, MS; Mary Thigpen, PT, MHS Andrea Behrman, PhD, PT
(Stroke. 2000;31:1360.)
Abstract: Background and Purpose—After stroke, many individuals have chronic unilateral motor dysfunction in the upper extremity that severely limits their functional movement control. The purpose of this study was to determine the effect of electromyography-triggered neuromuscular electrical stimulation on the wrist and finger extension muscles in individuals who had a stroke >=1 year earlier.
Conclusion--Two lines of evidence clearly support the use of the electromyography-triggered neuromuscular electrical stimulation treatment to rehabilitate wrist and finger extension movements of hemiparetic individuals >=1 year after stroke. The treatment program decreased motor dysfunction and improved the motor capabilities in this group of poststroke individuals.
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Neuromuscular Stimulation for Upper Extremity Motor and Functional Recovery in Acute Hemiplegia
John Chae, Francois Bethoux, Theresa Bohinc, Loreen Dobos, Tina Davis and Amy Friedl
(Stroke 1998;29;975-979)
Abstract: Background and Purpose--The purpose of this study was to assess the efficacy of neuromuscular stimulation in enhancing the upper extremity motor and functional recovery of acute stroke survivors.
Conclusions--Data suggest that neuromuscular stimulation enhances the upper extremity motor recovery of acute stroke survivors. However, the sample size in this study was too small to detect any significant effect of neuromuscular stimulation on self-care function. (Stroke. 1998;29:975-979.)
Full document

Why Electromedicine?
Daniel L. Kirsch, PhD, DAAPM, FAIS, (Electromedicine)
Abstract: Afresh look at physiology is needed to better understand and intervene in the primary medical complaint of pain. Western universities are still teaching that life is based on a chemical model. Given the explosive growth in electrical technologies and our ever increasing understanding of physics, it is more realistic in the 21st century to view biological processes on an electrochemical basis rather than on a chemical basis alone. Modern thinking on the subject far transcends the use of force in electromedical interventions. Scientific electromedicine has only evolved recently,over the past 50 years. This is due, in part, to advances in electrical technology and our understanding of biophysics as a distinct discipline from biochemistry. The most recent advancements involve only microcurrent levels of stimulation, often sufficiently minute as to not even be felt by the patient being treated.
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ARASYS CLINICAL & EXPERIMENTAL RESEARCH

2006:	Clinical Study: Data collected from a number of doctors and physical trainers. Data collection focused on the effectiveness of Arasys III on Inch Loss and Muscle Building after tailoring different frequency and pulse combinations for individuals with variable needs. Results indicated that inch loss is slightly higher when the pulse is set on a lower setting (faster pulse) and muscle building is higher when pulse is set on a higher setting (slower pulse). The 200 frequency is slightly better for muscle building.
2006:	Clinical Study: Data collected from a number of doctors and physical trainers. Data collection focused on the effectiveness of Arasys III on Inch Loss and Muscle Building when compared to physical exercise or other inch loss procedures. Results revealed that inch loss and muscle building occurs significantly faster with the Arasys when compared to both physical exercise and other inch loss procedures.
2006:	Experimental Research: Experimental study comparing the effects of Arasys on Inch Loss with two patient samples: Arasys Experimental Group and Physical Exercise Control Group.

Abstract
March 2004
Subjects: 20 subjects were randomly assigned to the Arasys group (experimental group four men and six women) and the gym group (control group four men and six women). The age of the subjects ranged from 35 to 49 years old. The mean waist circumference of the men was 52 inches, legs 37 inches, arms 21 inches. The mean waist circumference of the women was 37 inches, legs 26 inches, arms 15 inches

Method:
The subjects in the Arasys group received ten Arasys procedures for 60 minutes on their abdomen, legs and arms. Procedures were offered every other day. Overall treatment was completed within 20 days. The subjects in the gym group went ten times to the gym, every other day, working out for two hours at a time. All subjects were instructed to follow a low fat low carb diet provided by the experimenter and drink at least eight glasses or water daily. All subjects reported compliance with the above instructions.
Measure: Inch Loss.
Results: Statistical analysis (t test) revealed significantly more inch loss (an average of 11.8 inches lost) in the Arasys group when compared to the gym group (an average of 3.1 inches lost) p< 0.001

2004:

Experimental Research: Experimental study comparing the effects of Arasys on Visceral Fat with two patient samples: Arasys Experimental Group and Physical Exercise Control Group.

Abstract
December 2004
Subjects: eight subjects were randomly selected and assigned to the Arasys group (experimental group four women) and the gym group (control group four women). The age of the subjects ranged from 49 to 62 years old. All women were menopausal and had a waist circumference of greater than 35 inches ( 37- 43 inches) suggesting the presence of visceral fat (fat that surrounds vital organs and is metabolized by the liver, which turns it into blood cholesterol)
Method: The subjects in the Arasys group received ten Arasys procedures for 60 minutes on their abdomen. Procedures were offered every other day. Overall treatment was completed within 20 days. The subjects in the gym group went ten times to the gym, every other day, working out for two hours at a time. All subjects were instructed to follow a low fat low carb diet provided by the experimenter and drink at least eight glasses of water daily. All subjects reported compliance with the above instructions.
Measure: Inch Loss.
Results: Statistical analysis (t test) revealed significantly more inch loss (an average of 9.9 inches lost) in the Arasys group when compared to the gym group (an average of 2.4 inches lost) p<0.001

2004:

Experimental Research: Experimental study comparing the effects of Arasys on Muscle Building with two patient samples: Arasys Experimental Group and Physical Exercise Control Group.

Abstract
September 2004
Subjects: nine subjects were randomly assigned to the Arasys group (four men) and the gym group (five men). The age of the subjects ranged from 29 to 38 years old. All men were athletic and had previously followed a gym regime.
Method: The subjects in the Arasys group received ten Arasys procedures for 60 minutes on their legs and arms. Procedures were offered every other day. Overall treatment was completed within 20 days. The subjects in the gym group went ten times to the gym, every other day, lifting weights for four hours on each day and working primarily on their legs and arms. All subjects were instructed to follow a low fat, high protein diet provided by the experimenter. None of the subjects were on steroids. All subjects reported compliance with the above instructions.
Measure: Muscle building measured in inches.
Results: Statistical analysis (t test) revealed significantly more muscle building (an average of 3.6 inches of muscle increase) in the Arasys group when compared to the gym group (an average of 2.1 inches of muscle increase) p<0.01

2004:

Experimental Research: Experimental study comparing the effects of Arasys on Inch Loss with two patient samples: Arasys Experimental Group and Body Wraps, Control Group.

ARASYS PERFECTOR EMPIRICAL ELECTRONIC RESEARCH

1989 – 2006:

Gerry Pollock, co-inventor of the first pacemaker, continues his 17 years empirical electronic research focusing on the complex waveforms delivering the signal to the nerve that controls the muscle. New Arasys upgrades are expected in the near future. Research is conducted at the Bi Centre Innova Science in the UK, the most prestigious research center in Europe, funded by the European Community, where most European universities are doing their research.

ARASYS PERFECTOR CLINICAL ELECTRONIC RESEARCH

1994 – 2006:

Gerry Pollock, co-inventor of the first pacemaker, continues his 17 years clinical electronic research focusing on the complex waveforms delivering the signal to the nerve that controls the muscle with human subjects. New Arasys upgrades are expected in the near future. Research is conducted at the Innova Science Park in the UK, the most prestigious research center in Europe, funded by the European Community, where most European universities are doing their research.