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Rewiring The Body

First came pacemakers. Now exotic implants are bringing new hope to victims

of epilepsy, paralysis, depression, and other diseases

S. Kohn has donated his brain to science. An epileptic since he was 8

years old, Kohn has tried everything from experimental drugs to harrowing

surgery to control his seizures. Time and again, neurosurgeons have taken out

bits of his brain that spark his hallucinations, or auras, and have severed

nerves that enable aberrant electrical impulses to arc from lobe to lobe and

generate a full-blown seizure. They have also run filaments to a nerve in his

neck and to the core of his brain to microshock the disease into submission.

Inevitably, though, the illness reemerges, corrupting a new clump of brain

cells, and he is disabled once again. A college grad and certified computer

programmer, Kohn lives with his parents at age 34 and has never had a job.

Since

his first seizure in 1978, he figures he has had 10,000 more.

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His life may get better. Last fall, Kohn underwent his 12th operation.

First, doctors scrutinized images of his brain as it malfunctioned. Then,

guided

by these scans, they wired electrodes to eight " hot spots " deep in his brain,

and implanted under his skull a pacemaker-like device from NeuroPace Inc. in

Mountain View, Calif. About the size of a microcassette tape and only a bit

heavier, it houses a microprocessor programmed to detect the brain-wave

pattern that precedes a seizure. Whenever this pattern arises, it immediately

zaps

the trigger sites with tiny jolts of electricity. The goal is to override his

abnormal synapses and restore normal brain activity before Kohn is even

aware that a seizure is brewing.

Since the operation on Oct. 14, Kohn has been averaging 10 to 15 seizures a

month, down from 50 to 70. As a veteran guinea pig, Kohn knows that it takes

at least six months before anyone can truly gauge how well a treatment works,

so he doesn't want to rush to judgment. " I'm feeling pretty good, " he says.

His doctors, who believe they can lower that rate by tinkering with the

device's settings, are less guarded. " We've been looking for solutions for a

long

time, " says Dr. W. Byrne, a neurosurgeon at Rush University Medical

Center in Chicago who installed the device. " This could be it. "

Forty-five years ago, doctors successfully implanted a cardiac pacemaker for

the first time in the U.S., providing long-term hope for millions of people

with heart disease and creating what has become a hugely profitable -- and

still fast-growing -- $10 billion-a-year business. Now, electrical therapy may

be approaching an historic transition. Using advances in pacemaker

technology, researchers and doctors are finding that rapid-fire bursts of

low-voltage

electricity can alleviate symptoms in an astonishing number of illnesses in

many other parts of the human body. Scourges such as depression, post-stroke

paralysis, migraines, sleep apnea, angina, obesity, tinnitus, and digestive

tract disorders all may be treated with neurostimulators by the end of the

decade. If early-stage experiments pan out, Alzheimer's disease,

obsessive-compulsive disorder, Tourette's syndrome, bulimia, and other brain

ailments could be

next.

Mysterious Ways

Many doctors are thrilled by this emerging vision of the body electric

because it provides fixes beyond the ken of the medical mainstream. Life

sciences

today are heavily swayed by recent advances in molecular biology. The Human

Genome Project and other well-funded efforts have cracked some of the inner

workings of genes and the biochemical pathways of disease. In contrast, science

has paid less attention to the role of electricity, which governs everything

from the ethereal transmission of thought to the rhythmic music of the

heart. The race to design and test new implantable devices could help correct

this

imbalance.

The high-tech implants are neither cheap nor risk-free. For one thing, they

must be replaced every 5 to 10 years. Why they work is also still something

of a mystery. What's more, neurostimulation won't cure most diseases, even

though it eliminates or alleviates some symptoms. Doctors note that much of the

research is in an early stage. It could be 10 years before they can say for

sure if some devices are a fix -- or a flop.

But the potential upside is great. Unlike most drugs, these implants produce

few side effects. And while they might be a burden on insurers initially,

studies show that they should save big bucks on hospitalization over time. The

devices also are aimed at prevalent diseases that can't always be treated

with drugs. As a result, medical-products executives and their surgeon partners

predict that such implants could one day become as common as cardiac devices,

which are currently helping 2 million Americans.

Little wonder, then, that some of the biggest names in health care are in a

scramble to get into the market. Most recently, in December, &

(_JNJ_ (javascript: void showTicker('JNJ')) ) bought implant-maker

Guidant

Corp. (_GDT_ (javascript: void showTicker('GDT')) ) for $23.9 billion. " Any

organ that a nerve can influence -- and that's every organ in the body -- can

be affected using this technology, " says Dr. Ali R. Rezai, who is director

of functional neurosurgery at the Cleveland Clinic. " It's a new era in

neurology. "

The use of implantable mini-generators is more widespread than you probably

think. Already, 190,000 patients are wearing electrodes in their heads to

control Parkinson's disease tremors or spinal-cord stimulators to relieve pain

or prevent urinary incontinence. Some 30,000 have wires threaded to the vagus

nerve in the neck to treat epilepsy, while 60,000 have microtransmitters in

the inner ear enabling them to hear. These numbers are likely to grow -- and

quickly. One of the most promising devices is a $15,000 neurostimulator for

chronic depression from Cyberonics Inc., which the Food & Drug Administration

conditionally approved on Feb. 2.

Candy Bradshaw can testify to the power of neurostimulation. She had a

gastric pacemaker implanted in her abdomen in 1999 at Tufts-New England Medical

Center in Boston as part of an early-stage trial sponsored by Transneuronix

Inc. Today, Bradshaw, 47, weighs 200 pounds, down from 280 before surgery. She

still has to watch her diet and exercise regularly. But the device makes her

feel full sooner than before, so she eats less. " What it has done is

fantastic, " says Bradshaw, an office manager in Worcester, Mass. Executives of

Transneuronix in Mt. Arlington, N.J., say the implant, now in a pivotal trial,

could

be available as a less-invasive alternative to stomach stapling within three

years.

At Indiana University Medical Center in Indianapolis, researchers hope

neurostimulators might enable paraplegics to walk again. Their device beams

microvolts of electricity through six surgically installed electrodes to the

site

of a spinal cord injury. The electric field reverses direction, or

oscillates, every 15 minutes. In a just-completed experiment on 10 volunteers,

oscillating stimulation helped nerves regenerate after 14 weeks of treatment,

say

doctors in the study, a joint venture between Indiana University and Purdue

University. Two patients even recovered some movement in their legs, and one man

who had been impotent regained sexual functions. Doctors, fully aware that

earlier efforts in this area failed to achieve results, now are screening

paraplegics for a second round of trials.

Infection Risk

As neurostimulators get even smaller and their microchips more powerful,

researchers foresee new uses for these implants. Advanced Bionics Corp., a

startup that Boston Scientific Corp (_BSX_ (javascript: void showTicker('BSX'))

). acquired in 2004, is testing a rechargeable device so tiny that it can be

injected almost anywhere in the body to treat pain or muscle dysfunction.

Implants also could act as sensors, telling a miniature pump when to deliver a

drug or customized protein to a precise location in the body. " The body is on

fire with electricity, " says Dr. N. Oesterle, chief medical officer at

Medtronic Inc (_MDT_ (javascript: void showTicker('MDT')) )., the No. 1

maker of implantable electrical devices. " If you start with that concept, then

all you need is imagination. "

As with any invasive procedure, there are dangers in implant surgery. When a

cardiac device is implanted, for example, the rate of infection is 3% to 4%,

which is twice the average rate for surgery in general. Batteries in these

devices last only 5 to 10 years, which means patients may need a second

implant. (The second operation is generally easier and less costly, since the

electrical leads can be left in place.) Some device experts have expressed

concerns about airport scanners interfering with implants. And the devices can

fail.

Last year, Medtronic had to recall thousands of defibrillators after

discovering that their batteries were running low too quickly. At least four

people

died as a result of the product defect. On the other hand, sick people die

after undergoing other therapies, or doing nothing. All in all, " these are

low-risk products, " says Dr. Stuart M. Portnoy, a former cardiac-device

specialist at the FDA and now an industry adviser with PharmaNet, a Princeton

(N.J.)

consultant.

The neuromodulation market is potentially enormous. There are up to 3

million Americans with chronic migraines and 4 million with depression who do

not

respond to drugs. The number of morbidly obese American adults is also

estimated at 4 million. An additional 5 million Americans have been crippled to

some

degree by stroke, and the number grows by about 750,000 each year. Most of

these people won't rush out and have surgery. But if only a fraction get an

implant, executives at medical-device companies project that overall sales of

noncardiac pulse generators should balloon from $1.6 billion today to $10

billion in 10 to 15 years, depending on how quickly the FDA approves new uses.

" Ultimately, " says Todd K. Whitehurst, vice-president for emerging indications

at Advanced Bionics in Valencia, Calif., " this is going to be as big as

cardiac-rhythm management. "

The returns for investors may also be substantial. Today, most

neurostimulators don't make money because years of research and development and

marketing

outlays overwhelm what are, in the beginning, only trickling revenue streams.

Still, Advanced Neuromodulation Systems Inc. (_ANSI_ (javascript: void

showTicker('ANSI')) ), of Plano, Tex., averages gross margins of 70% on its

spinal-cord device for chronic pain. Houston's Cyberonics, Medtronic, and

Boston

Scientific -- the other companies with FDA- approved neuromodulators -- all

boast even fatter margins.

As sales grow, device makers will be able to spread their expenses over a

wider base and become more efficient manufacturers. If the FDA approves their

new treatments, says Jan D. Wald, a medical-device analyst at A.G. &

Sons Inc. (_AGE_ (javascript: void showTicker('AGE')) ) in Boston, pretax

earnings at the smaller companies should rise to 20% to 30% of revenue,

equaling

the return on more established products such as pacemakers. " The market is

close to an inflection point, " he says. Mark Landy, an analyst at Susquehanna

Financial Group in Bala Cynwyd, Pa., also sees the market growing by 20% for

the next several years. For now, though, he cautions against buying these

stocks, saying the share prices are already based on outsize returns.

Nevertheless, as more patients request implants for conditions that drugs

can't treat, the creaky health-care system will have to brace itself for yet

more financial strain. Today, a patient with migraines might get by on $10 a

day for drugs. A neurostimulator, by comparison, typically costs $15,000, or

about as much as a heart pacemaker or defibrillator. The total bill can hit

$50,000 with doctors' and hospital charges. Equipping just 10% of the estimated

500,000 Americans with epilepsy that drugs can't help could cost $2.5

billion. Even amortized over the average 7 1/2-year life of a device, that

$50,000

would cost about $17 a day.

Too Much of a Good Thing?

Beyond the sticker shock, officials at the government's Centers for Medicare

& Medicaid Services (CMS) also worry that, as with other glitzy treatments,

too many of these devices might end up in patients who don't really need

them. Tunis, the agency's chief medical officer, points out that the

nation

might get more bang for the buck if physicians did less expensive things

first -- for instance, routinely screening people for depression and putting

them

on medications before their conditions become untreatable. " There's no end

to the numbers of new devices that are being developed, but there is a limit

to how much employee-benefit plans can absorb, " warns Ignagni, chief

executive of America's Health Insurance Plans, a trade group representing the

major health insurers.

Over time, however, these devices may restore more than lives; they could

save money, too. In a comprehensive review of spinal-cord stimulation, a doctor

and an economist at Maastricht University Hospital in the Netherlands

reported in 2002 that the cost of implanting the device was offset by savings

on

physical therapy and other expenses in 2 1/2 years. The study's authors, who

tracked 54 patients over five years, also extrapolated that over a lifetime,

each patient would save $60,000. CMS and most major private health plans such

as Blue Cross Blue Shield Assn. cover implants for FDA-allowed devices,

although reimbursement rates and prerequisites for surgery vary.

Neurostimulation has another selling point: Because the implants alter

tissue only at their points of contact, side effects are generally negligible.

In

epilepsy patients with electrodes implanted to pulse the vagus nerve, the

most dire side effect is hoarseness, sometimes accompanied by the desire to

clear the throat. Only 3% of such patients report this minor complication. Most

say they can't sense the stimulation at all. Contrast that with the most

common drug treatment, Dilantin, which can cause dizziness and nausea and can

lead

to liver damage. " Think of the device as a smart bomb, " says Advanced

Neuromodulation (_ANSI_ (javascript: void showTicker('ANSI')) ) CEO

G.

Chavez.

Medical-device executives and surgeons point out that today's implants are

not generally intended to be a first-line treatment. Someone with heart

trouble, for instance, would start off on a cholesterol-reducing drug and a

stricter diet before getting outfitted with an implantable defibrillator. The

same

goes for neurostimulators, which are meant for patients with illnesses or

disabilities for which there are no other treatments. People like Judith Walsh

of

Elmwood Park, Ill. In 1999, when Walsh was just 54, she suffered a stroke

that paralyzed her entire left side. Thanks to aggressive physical therapy, she

recovered the ability to speak -- and also learned how to walk again. But

her left arm remained atrophied, with her left hand permanently clenched in an

almost-useless fist.

Last February, Walsh began electrical-stimulation therapy. In a clinical

study sponsored by Northstar Neuroscience Inc., doctors at Northwestern

Memorial

Hospital in Chicago implanted a pacemaker in her chest and tunneled wires up

her neck to her head. They drilled through her skull to place an electrode

patch about the size of a postage stamp on the protective membrane surrounding

her brain, close to the swatch that had been killed by the stroke. The

surgery took 90 minutes. For the next six weeks, even though she couldn't feel

it,

the device bathed the target site with electricity as she willed her left

arm and hand to move during 3 1/2 hours of supervised rehab every day. Then the

implant and electrodes were surgically removed.

Today, Walsh can make a peanut-butter and jelly sandwich and grip the

steering wheel of her car with her left hand. More gratifying, she says, she

can

feed and dress her five-month-old granddaughter, Emma, things she couldn't do

with her three older grandchildren when they were babies. " It's hard, as a

grandmother, not to be able to hold the grandchildren -- and now I'm able to do

that, " she says. " It's the thrill of my life. " Executives at Northstar, a

Seattle startup financed by J&J and Boston Scientific, among others, are now

negotiating the parameters of a final-stage clinical trial with the FDA.

The question remains: How do these devices alleviate symptoms? In the case

of rehabilitating stroke victims, doctors aren't sure whether the stimulation

enables brain cells in proximity to the stroke site to learn new functions or

whether the pulses instead are helping cells in stroke-damaged tissue

regenerate. Similarly, doctors are baffled as they test pacemakers to treat

obesity. They know the device stimulates nerves in the stomach to tell the

patients

they are no longer hungry. But they're not sure which organ is being tricked:

the stomach itself or the brain. " There must be a central mechanism, " says

Dr. Jay B. Prystowsky, chief of gastrointestinal and endocrine surgery at

Northwestern Memorial, " but the bottom line is we really don't know exactly how

this works. "

Burst of Uses

For such basics still to be a mystery is odd, considering how long science

has been studying electrical stimulation of the body. As far back as the late

1700s, experimenters showed they could make muscles twitch with shocks from

static-electricity generators. By the 1930s, as engineers perfected how to

control the frequency and flow of electricity, scientists were dabbling with

battery-powered pacemakers to pulse the heart. These early devices were bulky,

requiring patients to be anchored to an external contraption. Then in 1960,

electrical engineer Greatbatch patented the first successful implantable

pacemaker. Finally, in the mid-1990s, the FDA began approving pacemakers for

uses outside the heart.

Now, after that initial burst of approvals, a raft of new treatments may be

around the corner. On Feb. 2, the FDA cleared Cyberonics' vagus-nerve

stimulator for chronic depression, pending some clarification on the labeling

of the

device. Chairman and CEO P. " Skip " Cummins says Cyberonics analyzed

results from 240 people with long-term depression after two years of

neurostimulation. All of the subjects had failed to respond to drugs. The

analysis

found that half the patients were markedly better, with 18% reporting they were

no longer depressed. With the FDA's go-ahead, Cummins says, Cyberonics will

begin pilot studies on Alzheimer's disease, headache, anxiety disorders, and

bulimia. Medtronic also may be closing in on a number of new therapies. Its

products are in clinical tests to pulse the thalamus to treat epilepsy; another

region of the deep brain to treat migraines, depression, and

obsessive-compulsive disorder; the hypoglossal nerve in the neck to treat sleep

apnea; the

sacral nerve to treat bowel disorders; and the stomach to treat obesity.

Medtronic may have a deep-brain treatment for epilepsy in two or three years.

New treatments may become feasible as device sizes shrink and rechargeable

batteries evolve. Advanced Bionics, for example, has developed a rechargeable

implant that is about the size of an ink tube from a ballpoint pen cut to a

one-inch length. Its first use, already permitted in Europe, is to prevent

bladder incontinence by stimulating the organ directly, rather than through the

sacral nerve. The Boston Scientific subsidiary also has begun a stage-one

trial to see whether the device can alleviate chronic headaches by injecting it

into the base of the skull to stimulate the brain's occipital lobe. And soon,

company executives say, they hope to start testing the device in the leg and

arm as a therapy for pain or carpal-tunnel syndrome.

The leading cardiac-device makers are packing their newest implants with

enough computing power to sense the environment around them and alter a

patient's treatment as needed. A next step would be to link sensor-laden

neurostimulators to miniature drug pumps. In this way, a patient could be dosed

exactly

when needed and at the precise site where the medication is most effective.

Researchers say this could reduce dosages by a thousandfold and avert side

effects. Such systems would also enable a patient to be treated with

bioengineered drugs and proteins too large to be absorbed by swallowing a pill.

The

combined therapy seems most promising in the brain, where many disorders might

be

tackled with protein drugs complemented by electrical pulses.

As these new therapies move closer to reality, the medical-products

companies are putting down their markers. Last June, Boston Scientific paid

$740

million in cash to acquire Advanced Bionics. Boston Scientific also holds a 14%

stake in Cyberonics. Then in December came J&J's megadeal with Guidant.

Although Guidant does not have any neurostimulators in clinical trials, the

Indianapolis company has been earmarking an increasing share of its R&D budget

for

these devices. Some medical-products executives predict J&J or Boston

Scientific could buy Cyberonics or Advanced Neuromodulation next.

Implants won't cure everything that ails us. The Parkinson's treatment, for

one, stops tremors but can't halt the deadly disease. Yet the list of

therapies is growing. And they all benefit from advances in microelectronics

and our

deepening understanding of the brain and nervous system. " These de- vices

were science-fiction dreams 20 years ago, " marvels Dr. Levy, a

Northwestern Memorial neurosurgeon who has seen neurostimulation give stroke

victims

like Judy Walsh use of their hands and arms again. The body, as medicine is

learning, truly is electric.

By Arndt