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North by Northwest

The planet's wandering magnetic poles help reveal history of Earth and humans

Hikers in the wilderness often place their faith in a trusty compass. But any navigator worth his salt knows that compasses can't truly be trusted: Only along certain longitudes in the Northern Hemisphere does a compass needle point due north.

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MOVED BY MAGNETISM. Explorers first found the north magnetic pole at Canada's Cape Adelaide in 1831. Blue dots (direct surface observations) and red dots (models using satellite data) denote the pole's movement since then. Green dots indicate the pole's future location if its current rate and direction of motion continue.
Olsen and Mandea

In other locales, a compass needle slews either to the left or the right of true north by a certain angle, a process commonly known as declination. That's because a compass isn't attracted to the north geographic pole, the point at which Earth's rotational axis pierces the Arctic ice. Instead, the needle is attracted to the north magnetic pole, the spot where the planet's invisible magnetic field lines burst from the surface and point directly upward.

Astronomers have long known that a compass doesn't always point true north, a bearing in the night sky that lies within 0.5° of Polaris, the North Star. Their measurements of declination, along with those made by seafaring explorers, enabled 16th-century sailors to better navigate along their trade routes, especially those linking the New World to the Old. What many scientists didn't appreciate until the 1600s, after they had compiled a few decades' worth of precise measurements at astronomical observatories, was that declination varied through time. Suddenly, they realized: The magnetic pole moves!

What difference does this make in today's world, where pilots, navigators, and even backcountry campers increasingly depend on satellite-based technology such as Global Positioning System equipment to find their way? In practice, not much: Earth's magnetic poles are located in remote regions and in recent times they've moved, at most, only a few dozen kilometers a year.

However, a slowly wandering magnetic pole is a boon for archaeologists and other researchers who study the past. Often magnetic substances in rock, paint, and other materials become aligned with Earth's magnetic field under certain conditions, enabling researchers to, say, determine when a mural was painted, when a town was built, or when a fireplace was used for the last time.

 

Wandering poles

Draw a line between the north and south geographic poles, and it runs smack through the center of the planet. Earth's rotation around this axis once each 24 hours produces the familiar cycle of day and night. Unlike the geographic poles, however, our planet's north and south magnetic poles aren't located directly opposite one another, says Nils Olsen, a geophysicist at University of Copenhagen.

Earth's geographic poles are fairly stable, wobbling back and forth across the landscape only a few meters every year or so (SN: 8/12/00, p. 111). The north and south magnetic poles are far more mobile, and they move independently of one another, says Olsen. Now located in the Arctic Ocean just north of Canada, the north magnetic pole is moving northwest toward Siberia by about 50 km each year. The south magnetic pole, just off the Antarctic coast south of Australia, is also—for now—heading northwest, but only at around 5 km/yr, Olsen and Mioara Mandea, a geophysicist at the National Research Center for Geosciences in Potsdam, Germany, report in the July 17 Eos.

Such wanderings stem from irregularities in the process that generates the magnetic field, says Olsen. Although Earth's inner core is solid and primarily composed of iron, its outer core is a molten mix of iron and lighter metals that is constantly on the move. The flow of that material, which carries charged particles and conducts electricity, produces the magnetic field, says Olsen. Long-lived eddies and swirling currents in the fluid, which moves at an average speed of about 20 km/yr and is no more viscous than water, make the magnetic field deep within Earth much more complex than it is at the planet's surface. "It's a highly chaotic system," says Olsen.

In particular, he notes, that turbulence can create "reversed-flux patches," regions on the surface of the outer core where magnetic field lines point opposite to those predominant at the Earth's surface. Variations in the size and strength of these patches significantly affect the location and the motion of the magnetic poles. For instance, the growth and movement of a reversed-flux patch beneath northern Canada is causing the north magnetic pole to surge toward Siberia.

At its current rate, the north magnetic pole will pass within 400 km of the north geographic pole in 2018, Olsen and Mandea report. Because of the chaotic nature of the field-generating processes in the outer core, predicting the pole's location more than a decade into the future is tricky, says Olsen. Nevertheless, the pole has been moving toward the northwest, although with varying speed, for more than a century.

In the past few decades, the strengthening of reversed-flux patches—especially ones beneath Canada and the South Atlantic Ocean—has weakened Earth's magnetic field, says Olsen. If the field's overall strength keeps dropping at today's rate, it will reach zero in a few hundred years. However, he notes, it's not clear whether recent fluctuations in field strength are routine variations or the prelude to a full-blown reversal of Earth's magnetic field—something that happens, on average, every quarter-million years or so.

Although the strength of the Earth's magnetic field is now dropping, it is 50 percent stronger than the estimated average for the past 60 million years, says Lisa Tauxe, a paleomagnetist at the Scripps Institution of Oceanography in La Jolla, Calif. At its most recent peak, about 2,000 years ago, the magnetic field was about twice as strong as it is now. "Data is spotty, but we have a crude idea of what's going on [with the magnetic field]," she notes. The data also suggest that "the field can change rapidly over a shorter time than [scientists] had thought."

Around the world

Only in the past couple of centuries have scientists visited the Earth's magnetic poles. The first explorers to find the north magnetic pole did so at Cape Adelaide, on the west coast of Canada's Boothia Peninsula, in 1831. An expedition 73 years later discovered that the pole had moved about 50 km to the northeast. In the following century, the pole moved more than 1,300 km toward the northwest, along the same path it is taking today.

 

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DIGGING THE SCENE. Paleomagnetic data from a series of hearths unearthed in central Winchester, England, yield information about the city's early history.
Oxford Archaeology Ltd.

 

Despite this limited history of direct observations, researchers can use various clues to estimate the size, strength, and polarity of Earth's magnetic field at many times in the past. For instance, some minerals that crystallize as lava cools can record the direction of the planet's magnetic field at the time the eruption occurred, says Steven T. Johnston, a geologist at the University of Victoria in British Columbia. In many cases, such information enables scientists to establish the latitude where pieces of Earth's crust originated and thereby infer their long-term tectonic motion, he notes.

As long as magnetized minerals aren't heated above a characteristic temperature known as a Curie temperature, the alignment of the magnetic materials contained therein remains intact. If the rocks are heated beyond the Curie temperature, which typically lies between 500°C and 600°C, the stored magnetic information gets scrambled, says Cathy Batt, a paleoarchaeologist at the University of Bradford in England. Then, when the rocks cool, their magnetic materials realign themselves with the planet's magnetic field (SN: 3/13/04, p. 174). Because fires usually are hotter than a mineral's Curie temperature, magnetic materials lining a hearth record the strength and direction of magnetic field lines at the last time a fire had been lit there—a finding of great interest to an archaeologist, for example.

By combining data gathered by geologists and archaeologists, researchers have tracked the motions of the magnetic poles for the past 7,000 years or so, says Mandea. During that time, the magnetic poles have wandered through all longitudes, roughly circling the geographic poles, she notes. While the north magnetic pole has remained well within the Arctic Circle, the south magnetic pole has recently roamed farther away from the south geographic pole and is now around 64°S.

Using information collected in Britain, mostly from England and Wales, Batt and her colleagues have compiled a record of how magnetic declination has varied in that region during the past 4,000 years. To provide a more useful comparison among sites, the researchers adjusted each measurement to replicate what the magnetic field would have been like at Meriden, England, a town about 150 km northwest of London. The model should be valid for any site within 500 km of that town, which is roughly the center of the England-Wales region, Batt and her colleagues note in the Feb. 16 Physics of the Earth and Planetary Interiors.

The team's data also include information about magnetic dip, the angle between the Earth's magnetic field lines and a horizontal plane. Only a few of the 858 sets of measurements, most notably the 238 data points taken at observatories since the 1600s, include data about paleointensity, or how strong the planet's magnetic field was at the time data were gathered. The combination of two or more of these parameters enables researchers to better estimate the age of an artifact when other clues don't provide a clear answer, says Batt.

Most centuries during the past 4 millennia are represented by at least 10 data points. However, few archaeological sites have been dated to the centuries between A.D. 600 and 800, which historians often refer to as the Dark Ages. Data for the centuries before 1000 B.C. are similarly sparse.

During the past 4 millennia, magnetic declinations in Britain have varied through an angle of 70° and their magnetic dips have ranged about 25°, the researchers report.

To test their model, Batt and her colleagues analyzed an archaeological site that was exposed during construction in downtown Exeter, England. The city has been continuously populated since the Roman period, so sites there often include a jumble of artifacts from different periods. One sample the team analyzed probably came from a fireplace in a home or other structure. Another sample was, most likely, just a spot of burned soil.

The combination of declination and dip found in the fireplace sample suggest the material could have been last heated during any of three intervals during the past 4 millennia, says Batt. However, because two of those intervals long predate known occupation in the area, the researchers dismiss those possibilities. Therefore, the fireplace probably last hosted a fire in the 11th century, during Europe's early-medieval period. The burnt spot of soil is a century or so older than that, the magnetic data suggest.

Using paleomagnetic data offers archaeologists "a good tool to figure out who occupied a particular area at a particular time, and what they were doing," says Batt.

Probing the past

One debate among English historians regards what stimulated urban development in the fledgling nation. King Alfred, who with his brother unified the nobility in the mid-800s, commissioned earthwork defenses in many areas of southern England after Viking attacks in the 860s. One big question: Were the cities encircled by those earthworks well developed before construction of the defenses, or did those fortifications provide the protection needed for small villages to grow into thriving cities?

a9134_3499.jpg

HALF-BAKED DATA. The strength and direction of the magnetic field trapped in minerals forged by fire in ancient hearths (reddish materials at arrows) can help archaeologists estimate the date when those fires last burned.
Oxford Archaeology Ltd.

 

Information unearthed during a construction project in downtown Winchester, about 90 km southwest of London, could help settle the debate, says Ben Ford of Oxford (England) Archaeology and director of excavation at the site. During a 5-month investigation at the 2,000-square-meter construction site, he and his colleagues uncovered the remnants of many ancient structures, including some blacksmith shops. The researchers drilled samples from each of 17 hearths, estimated their ages using paleomagnetic dating techniques, and then carbon-dated organic material such as ash, burned seeds, and small sticks—presumably the remnants of the hearths' last fires—to verify the results.

Most of the ancient structures were found in an area measuring 60 m long and 12 m wide, a hint that the densely packed buildings sat along an established road, says Ford. The full range of estimated ages of the Winchester hearths runs from the 9th century to the 14th. Preliminary results for two of the samples suggest that those structures were last used in the 840s and the 850s—decades that clearly predate the earthworks commissioned by King Alfred, Ford notes.

"These [findings] provide detail in the historical record for an area that isn't well known," says Mark Hounslow, a geographer at Lancaster (England) University, who has worked at the Winchester site.

Finding so many hearths of different ages at one site will be a boon for paleomagnetists, says Ford. Results of the team's paleomagnetic analyses can be added to comprehensive databases like Batt's, he notes. And, the new findings may allow scientists to fine-tune the patterns of magnetic pole movement inferred from those data.

By using paleomagnetic data, researchers no longer have to infer the ages of strata from the presence of easily dated objects such as coins or distinct forms of pottery, says Ford. "Now," he notes, "we can write history from archaeological data." 

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Stem cell breakthrough is like turning lead into gold 

Stem cell cultures are held up in a US lab. It was the kind ...
Stem cell cultures are held up in a US lab. It was the kind of breakthrough scientists had dreamed of for decades and its promise to help cure disease appears to be fast on the way to being realized.

It was the kind of breakthrough scientists had dreamed of for decades and its promise to help cure disease appears to be fast on the way to being realized.

Researchers in November announced they were able to turn the clock back on skin cells and transform them into stem cells, the mutable building blocks of organs and tissues.

Then just earlier this month a different team announced it had cured sickle cell anemia in mice using stem cells derived from adult mouse skin.

"This is truly the Holy Grail: To be able to take a few cells from a patient -- say a cheek swab or few skin cells -- and turn them into stem cells in the laboratory," said Robert Lanza, a stem cell pioneer at Advanced Cell Technology.

"This work represents a tremendous scientific milestone - the biological equivalent of the Wright Brothers' first airplane," he told AFP.

"It's bit like learning how to turn lead into gold."

Stem cells offer enormous potential for curing and treating disease because they can be transformed into any cell in the body and then hopefully used to replace damaged or diseased cells, tissues and organs.

But stem cell research has been highly controversial because -- until now -- viable embryos had to be destroyed to extract the stem cells.

US President George W. Bush has banned all federal funding for research on human embryonic stem cells and access to stem cells in other countries has also been restricted because of the difficulty in finding women willing to donate their eggs.

The new technique, while far from perfected, is so promising that the man who managed to clone the world's first sheep, Dolly, is giving up his work cloning embryos to focus on studying stem cells derived from skin cells.

"The fact that (the) introduction of a small number of proteins into adult human cells could produce cells that are equivalent to embryo stem cells takes us into an entirely new era of stem cell biology," said Ian Wilmut, the Scottish researcher who first created a viable clone by transferring a cell nucleus into a new embryo.

One of the greatest advantages of the new technique is its simplicity: it takes just four genes to turn the skin cell back into a stem cell.

This, unlike the complex and expensive process developed by Wilmut, can be done in a standard biological lab. And skin cells are much easier to harvest than embryos.

"It's an explosion of resources," said Konrad Hochedlinger, of the Harvard Stem Cell Institute.

Prior to this discovery, researchers who wanted to look at how diseases developed would usually have to study animals or organs harvested from cadavers because embryonic stem cells were so hard to use and access.

But with stem cells derived from skin, tissues and organs can be grown in a petri dish, making it easier for researchers to map the genetic structure of diseased cells, a process which could unlock a cure.

They could also allow researchers to do chemical screens to identify drugs which may cure or treat a disease, a process which could significantly speed up the process of bringing life-saving drugs to the market.

The use of skin cells will eventually allow doctors to create stem cells with a specific patient's genetic code, eliminating the risk that the body would reject transplanted tissues or organs.

Researchers have already shown this is possible when they cured sickle cell anemia in mice.

They used skin cells taken from the tails of sick mice, transformed them into stem cells, manipulated those stem cells into healthy bone marrow cells and then transplanted them into the sick mice.

And since the new cells came from the sick mice, there was also no need for dangerous immunosuppressant drugs to prevent rejection.

But leading stem cell researchers warned that the skin cells are not yet -- and might never be -- a substitute for embryonic stem cells.

"This new research is just the beginning -- we hardly understand how these cells work," said James Thomson of the University of Wisconsin at Madison, who led one of the two teams which made the simultaneous discoveries.

"It is not the time to abandon stem cell research," Thomson said, adding that embryonic stem cells will remain the "gold standard" by which other research is measured.

Further research is also needed to find a safer way to transform the skin cells and to make sure that the cells do not deteriorate over time.

Finding Alzheimer’s Before a Mind Fails

Ms. Kerley, 52, has spent much of her life in the shadow of an illness that gradually destroys memory, personality and the ability to think, speak and live independently. Her mother, grandmother and a maternal great-aunt all developed Alzheimer’s disease. Her mother, 78, is in a nursing home in the advanced stages of dementia, helpless and barely responsive.

“She’s in her own private purgatory,” Ms. Kerley said.

Ms. Kerley is part of an ambitious new scientific effort to find ways to detect Alzheimer’s disease at the earliest possible moment. Although the disease may seem like a calamity that strikes suddenly in old age, scientists now think it begins long before the mind fails.

“Alzheimer’s disease may be a chronic condition in which changes begin in midlife or even earlier,” said Dr. John C. Morris, director of the Alzheimer’s Disease Research Center at Washington University in St. Louis, where Ms. Kerley volunteers for studies.

But currently, the diagnosis is not made until symptoms develop, and by then it may already be too late to rescue the brain. Drugs now in use temporarily ease symptoms for some, but cannot halt the underlying disease.

Many scientists believe the best hope of progress, maybe the only hope, lies in detecting the disease early and devising treatments to stop it before brain damage becomes extensive. Better still, they would like to intervene even sooner, by identifying risk factors and treating people preventively — the same strategy that has markedly lowered death rates from heart disease, stroke and some cancers.

So far, Alzheimer’s has been unyielding. But research now under way may start answering major questions about when the disease begins and how best to fight it.

A radioactive dye called PIB (for Pittsburgh Compound B) has made it possible to use PET scans to find deposits of amyloid, an Alzheimer’s-related protein, in the brains of live human beings. It may lead to earlier diagnosis, help doctors distinguish Alzheimer’s from other forms of dementia and let them monitor the effects of treatment.

Studies with the dye have already found significant deposits in 20 percent to 25 percent of seemingly normal people over 65, suggesting that they may be on the way to Alzheimer’s, though only time will tell.

“PIB is about the future of where Alzheimer’s disease needs to be,” said Dr. William E. Klunk, a co-discoverer of the dye at the Alzheimer’s research center at the University of Pittsburgh. “PIB is being used today to help determine whether drugs that are meant to prevent or remove amyloid from the brain are working, so we can find drugs that prevent the underlying pathology of the disease.”

Though PIB is experimental now, studies began in November that are intended to lead to government approval for wider use.

Currently, for the most common form of Alzheimer’s disease, which occurs after age 65, there is no proven means of early detection, no definitive genetic test. But PIB tests might be ready before new treatments emerge, making it possible to predict who will develop Alzheimer’s — without being able to help.

Researchers are also using M.R.I. scans to look for early brain changes, and testing blood and spinal fluid for amyloid and other “biomarkers” to see if they can be used to predict Alzheimer’s or find it early.

Studies of families in which multiple members have dementia are helping to sort out the genetic underpinnings of the disease.

Finally, experiments are under way to find out whether drugs and vaccines can remove amyloid from the brain or prevent its buildup, and whether doing so would help patients. The new drugs, unlike the ones now available, have the potential to stop or slow the progress of the disease. At the very least, the drug studies will be the first real test of the leading theory of Alzheimer’s, which blames amyloid for setting off a chain of events that ultimately ruin the brain.

Some scientists doubt the amyloid theory, but even a staunch skeptic said the studies were important.

Among the skeptics is Dr. Peter Davies, a professor at Albert Einstein Medical College, who said: “You’ve got to try. Somebody’s going to get this right.”

But if the amyloid hypothesis does not hold up, much of Alzheimer’s research could wind up back at Square 1.

Answers are urgently needed. Alzheimer’s was first recognized 100 years ago, and in all that time science has been completely unable to change the course of the disease. Desperate families spend more than $1 billion a year on drugs approved for Alzheimer’s that generally have only small effects, if any, on symptoms. Patients’ agitation and hallucinations often drive relatives and nursing homes to resort to additional, powerful drugs approved for other diseases like schizophrenia, drugs that can deepen the oblivion and cause severe side effects like diabetes, stroke and movement disorders.

Alzheimer’s is the most common cause of dementia (artery disease, Parkinson’s and other brain disorders can also lead to dementia). Five million people in the United States have Alzheimer’s, most of them over 65. It is the nation’s sixth leading cause of death by disease, killing nearly 66,000 people a year and probably contributing to many more deaths. By 2050, according to the Alzheimer’s Association, 11 million to 16 million Americans will have the disease. “Sixteen million is a future we can’t countenance,” said William H. Thies, the association’s vice president for medical and scientific relations. “It will bankrupt our health care system.”

The costs are already enormous, $148 billion a year — more than three times the cost of chronic lung disease, even though Alzheimer’s kills only half as many people. To a great extent, increases in dementia are the price of progress: more and more people are living long enough to get Alzheimer’s, some because they survived heart disease, strokes or cancer. It is a cruel trade-off. The disease is by no means inevitable, but among people 85 and older, about 40 percent develop Alzheimer’s and spend their so-called golden years in a thicket of confusion, ultimately becoming incontinent, mute, bedridden or forced to use a wheelchair and completely dependent on others.

“It makes people wonder whether they really want to live that long,” Dr. Klunk said.

The potential market for prevention and treatment is enormous, and drug companies are eager to exploit it. If a drug could prevent Alzheimer’s or just reduce the risk, as statins like Lipitor do for heart disease, half the population over 55 would probably need to take it, Dr. Thies said.

If new drugs do emerge, they will come from studies in patients who already have symptoms, Dr. Thies said. But he said the emphasis would quickly shift to treating people at risk, before symptoms set in. Many researchers doubt that even the best preventive drugs will be able to heal the brains of people who are already demented.

Treating preventively, Dr. Thies said, “will be more satisfying to patients and physicians, and there will be an economic incentive because you’ll wind up treating more people.”

The only thing that could slow the drive for early treatment, he said, would be serious side effects — and Dr. Morris, at Washington University, said drugs powerful enough to treat Alzheimer’s would probably have strong side effects.

Researchers are especially eager to study people like Ms. Kerley, because the children of Alzheimer’s patients have a higher-than-average risk of dementia themselves, and tracking their brains and minds may open a window onto the earliest stages of the disease.

“I want to do anything I can possibly do to help find a cure or find a way to identify it earlier,” Ms. Kerley said. “We need to stop this. I don’t know if it will help my generation, but it will help my son’s.”

She figures that being a research subject may have advantages, too.

“We’re the first ones in line,” she said. “If I am genetically predisposed, and they have a preventive medication, they’ll tell me right away.”

Alzheimer’s Beginnings

Some forgetfulness is normal. Distraction, stress, fatigue and medications can contribute. A joking rule of thumb about Alzheimer’s is actually close to the truth: it’s O.K. to forget where you put your car keys, as long as you remember what a key is for. But worsening forgetfulness is a cause for concern.

Doctors use standard memory and reasoning tests to diagnose dementia, along with symptoms reported by the patient and family members. The term “mild cognitive impairment” is sometimes applied to small but measurable memory problems. But its meaning is unclear: some studies find that the impairment can resolve itself, while others suggest that it always progresses to dementia.

Even if older patients think more slowly or take longer to remember, as long as they can still function independently, they are not demented, Dr. Morris said.

In her heart, Ms. Kerley suspects that her mother’s Alzheimer’s disease began long before the official diagnosis in 2001 or even the tentative one in 1995 — years before, maybe decades. She wonders if the disease might explain, at least in part, her mother’s difficult personality and lack of interest in reading or education.

When does Alzheimer’s begin? The question haunts families and captivates scientists.

Dr. Morris said, “We think that by the time an individual begins to experience memory loss, there is already substantial brain damage in areas critical to memory and learning.”

No one knows whether the disease affects thinking, mood or personality before memory fails. Researchers think that the brain, like other vital organs, has a huge reserve capacity that can, at least for a time, hide the fact that a disease is steadily destroying it.

“I’m speculating that it does affect you throughout life,” said Dr. Richard Mayeux, a professor of neurology, psychiatry and epidemiology at Columbia University, and co-director of its Taub Institute for Research on Alzheimer’s Disease and the Aging Brain. “I think there’s a very long phase where people aren’t themselves.”

If Dr. Mayeux asks family members when a patient’s memory problem began, they almost always say it started a year and a half before. If he then asks when was the last time they thought the patient’s memory was perfectly normal, many reply that the patient never really had a great memory.

Several studies in which people had intelligence tests early in life and were then evaluated decades later have found that compared with the healthy people, those with Alzheimer’s had lower scores on the early tests.

“It raises the possibility for me that this is a genetic disorder that starts early in life,” Dr. Mayeux said.

He said those findings also made him wonder about the widely dispensed advice to read, take courses, solve puzzles and stay mentally active to ward off Alzheimer’s. The advice is based on studies showing that highly educated people have a lower risk of Alzheimer’s than do less-accomplished ones. But does that mean that mental activity prevents Alzheimer’s — or vice versa?

‘I Have Lost Myself’

The disease is named for Alois Alzheimer, a German doctor who first described it in Auguste D., a 51-year-old patient he saw in 1901. Her memory, speech and comprehension were failing, and she suffered from hallucinations and paranoid delusions that her husband was unfaithful. Unable to finish writing her own name, she told Alzheimer, “I have lost myself.”

She died in 1906, “completely apathetic,” curled up in a fetal position and “in spite of all the care and attention,” suffering from bedsores, Alzheimer wrote.

A century later, patients still die in much the same way. Although Alzheimer’s itself can kill by shutting down vital brain functions, infections usually end things first — pneumonia, bladder infections, sepsis from bedsores.

When Alzheimer dissected Auguste’s brain, he found it markedly shrunken, a wasteland of dead and dying nerve cells littered with strange deposits.

There were two types of deposits, plaques and tangles. Plaques occur between nerve cells, and are now known to consist of clumps of beta amyloid, an abnormal protein. Tangles form inside nerve cells, and are made of a protein called tau that is normally part of a system of tubules that carry nutrients to feed the cell. Once tau is damaged, the nerve cells essentially starve to death.

Until the 1970s Alzheimer’s disease was considered a rare brain disorder that mysteriously struck younger people like Auguste D.

It was thought to be different from “senility,” which was assumed to be a consequence of aging. But then researchers compared the brains of younger people who had died of Alzheimer’s with those of elderly people who had been senile, and discovered the same pathology — plaques and tangles. Senility, they decided, was not a natural part of aging; it was a disease.

The Amyloid Hypothesis

The leading theory of Alzheimer’s says that beta amyloid, or A-beta, is the main culprit, building gradually in the brain over decades and short-circuiting synapses, the junctions where nerve cells transmit signals to one other. Gradually, the theory goes, the cells quit working and die.

Everybody produces A-beta, but its purpose is not known. People who develop Alzheimer’s either make too much or cannot get rid of it. Although scientists once blamed plaques for all the trouble, more recent research suggests that the real toxins are smaller bundles of A-beta molecules that form long before plaques do.

Dr. Dennis J. Selkoe, a professor of neurologic diseases at Harvard, said that just as lowering cholesterol can prevent heart disease, lowering A-beta may prevent Alzheimer’s or slow it, particularly in the early stages — provided that drugs can be created to do the job.

Several drugs and vaccines are now being tested that either block the production of A-beta or help the body get rid of it.

Researchers are also testing anti-amyloid antibodies, which are proteins made by the immune system, as well as blood serum that contains the antibodies.

Eventually, Dr. Selkoe said, screening tests for Alzheimer’s “will be like getting an EKG in the doctor’s office at 45 or 50, and you’ll start treating right away to prevent Alzheimer’s rather than treat it.”

Other researchers are less enthusiastic, noting that there have been numerous failures and disappointments along the way. A vaccine study had to be halted in 2002 because 18 of 300 patients developed encephalitis, and 2 died. Some scientists worry that anti-amyloid vaccines in general could be dangerous, in part because the role of amyloid is not well understood and the brain may actually need it.

No Choice but to Cope

Even if current research yields new drugs, there is not likely to be a miracle pill that will bring people back from deep dementia. For now, there is no choice but to cope with the disease. Seventy percent of Alzheimer’s patients are cared for at home, and millions of families are struggling to look after them, piecing together a patchwork of relatives, friends, paid health aides and adult day-care programs.

Barbara Latshaw, 79, lives with her husband, David, and her sister in Crafton, Pa., near Pittsburgh. Ms. Latshaw, whose dementia was diagnosed in 1991, has not spoken in four years, and she can no longer smile. But she locks eyes with visitors and will not let go.

“There is still something alive in there,” said her sister, Fritzie Hess, 69. “I’m convinced of it.”

The family believes that, at least some of the time, she still understands them. They speak to her as if she does. She is with them, and yet gone, and they miss her terribly.

“We hope to keep her here at home until she passes on,” Ms. Hess said. “She’s a joy to us.”

Many families hope to keep Alzheimer’s patients at home, but not all can manage it, especially if family members have to go work or patients become combative, incontinent, immobile or unable to sleep at night.

“There are three of us taking care of my sister, and it works out beautifully,” Ms. Hess said. “We spell each other. I don’t know how these spouses manage, when it’s one on one.”

Ms. Hess and her brother-in-law are retired, and Ms. Latshaw’s daughter, Becky Bannon, 53, is free to visit many mornings to help them get her mother out of bed, massage and exercise her arms and legs, change her diaper and dress and feed her.

Ms. Latshaw used to be full of life. She loved to cook, played tennis and bridge, raised two children and took charge of redecorating the grand old family home. Then her memory began to slip: guests would arrive for dinner, and she would have no memory of inviting them. She forgot to look before pulling into traffic, and nearly caused an accident. She would wander out of the house, and local store clerks would take her home. She never turned hostile or angry, as many demented patients do, but she had vivid hallucinations of strings being caught in her teeth, and little men getting into her bed and jabbing her with broom straws. On especially bad nights, her husband would get up with her at 2 or 3 a.m. and make the two of them hot chocolate.

Aricept, an Alzheimer’s drug, made the hallucinations worse, while another drug, an antipsychotic used for schizophrenia, seemed to quell them. But the second drug had side effects: after taking it for several years, Ms. Latshaw began to grind her teeth, and could not stop moving her arms and legs.

Their father also suffered from dementia, Ms. Hess said, admitting that she wonders about herself.

“Naturally I’m a little bit concerned, but I think worry is such a waste of time, so I don’t dwell on it; I just don’t,” she said. “My friends always said, ‘You always had a bad memory.’ I see Barbara and David’s children having that same kind of memory.”

Ms. Hess has volunteered for studies at the University of Pittsburgh Medical Center, where she became the first person in the United States to have a PIB study of her brain.

“I’m very anxious to get to the bottom of this whole Alzheimer’s thing,” she said.

Nothing Left to Give

In an interview in the summer of 2006, Ms. Kerley described her mother this way: “She’s completely withdrawn in herself. She hasn’t recognized us for a few years. Basically she hums one line of one song over and over again. She seems to be stuck somewhere in her life between age 4 and 5.”

Ms. Kerley said she and her son Michael, then 21, visited every week or two.

“She loves getting her back rubbed, being smiled at, being hugged,” Ms. Kerley said. “She doesn’t know who we are. We’re going for us, not for her, because she doesn’t remember us the minute we walk out the door.”

She had signed her mother up for hospice care at the nursing home, meaning that she would receive medical care to keep her comfortable but no extraordinary measures like resuscitation if she began to fail. She said her mother would not want to be kept alive in her present condition.

“She has nothing left to give the world, and the world has nothing left to give to her,” Ms. Kerley said.

Nearly a year and a half later, her mother is still alive, even though Ms. Kerley has declined liquid nutritional supplements, antibiotics and flu and pneumonia shots.

Her mother does not even hum anymore, and spends much of her time in a fetal position, except when she is at the dinner table. She can still walk, if led.

“If my mother had her own choice, she would have offed herself a long time ago,” Ms. Kerley said. “There is no quality to her life.

“When she does go, it will be a blessing.”

Ms. Kerley has already arranged to donate her mother’s brain and her own to Washington University. She seriously doubts that she will develop Alzheimer’s. She is more like her father than her mother, she said, and she is the most educated person in her family, reads constantly and stays in shape by swing dancing two to five nights a week. And her students keep her sharp.

“If you want to keep up with me until you retire, that’s fine,” she said. “I’m betting I’m not going to have that problem.” 

Synesthesia: A mixing of the senses when the brain reorganizes

One morning seven years ago, Sherrilyn Roush woke to discover that the left side of her body had gone numb.

The cause was obvious, according to Roush, now 42 and a philosophy professor at the University of California, Berkeley: The day before, she had been given a prescription decongestant with an ingredient suspected of causing strokes in young women.

Five months later, the Food and Drug Administration took the drug off the market.

But Roush, then starting her career at Rice University in Houston, did not realize that her stroke would lead to sensations that few people have ever experienced.

A year and a half after the stroke, caused by a lesion the size of a lentil in a region of her midbrain, Roush began to feel tingling on her body in response to sounds.

Today, more than ever, she feels sounds on her skin.

The first time it happened, Roush was channel-surfing when she heard the voice of an announcer on a local FM station. When the announcer started to talk, she recalled, "I felt an unpleasant sensation on my left thigh, left arm, the back of my shoulder and even the outside of my left ear."

"It was the kind of icky feeling that uniformly washes over you at a scary movie. I had to stop listening. It made me cringe."

Tony Ro, a psychologist from Rice University who has followed her case from the beginning, said Roush has a rare case of acquired synesthesia.

Synesthesia is a condition marked by odd mixings of the senses. Sensory areas of the brain that do not normally communicate engage in cross-talk.

Most synesthetes are born with such crossed connections. Some experience complex tastes, like apple or bacon, in response to words. Others feel complex shapes, like pyramids, in response to tastes. Many see colors attached to specific letters or numbers.

In this case, Ro said, the crossed wiring developed as a consequence of the stroke. Imaging studies reveal that fiber tracts from Roush's midbrain that normally go to higher regions involved in touch are disorganized and diminished. Such disruption can lead to enhanced connectivity in remotely connected regions of the brain like hearing and touch.

Ro and colleagues have tested Roush for the last seven years, observing how her brain has reorganized. An article describing her case appears in the November issue of Annals of Neurology.

For several months, Roush found herself bumping into doors. When she drove, her car would veer to the right. But gradually, the weakness on her left side and the neglect of space around her left side diminished. Her only concession was to give up driving a car with a stick shift because of lingering weakness in her leg.

But in laboratory tests a year later, she exhibited a rare phenomenon. If simultaneously touched on both hands, she would feel an increased sense of pressure on her left hand. Her brain was reorganizing in ways that baffled her doctors.

Not long after that, sounds began to produce tingling, hair-raising sensations of touch on her body. Something about that radio announcer's voice - its pitch or timbre - was unbearably irritating.

But the soft sound of water bubbling is "soothing, almost like a massage on my skin," Roush said, adding, "Round sounds produce a very light tickle but without the annoying part of being tickled."

She always feels touch sensations, positive and negative, on the left side of her body, particularly the outside of her arm, thigh, head and shoulder. They do not reach the bottom of her leg. Sometimes they make her squirm. But most, she said, do not interfere with everyday life.

Recently, Roush learned how to exploit her oddly mixed up senses.

"I took up the string bass," she said. "Most people get pleasure from this instrument. It is huge. It has a soft, deep sound. But I get more pleasure out of it, right there in my left arm. When I play, it feels like a massage."

The Enduring Mysteries of Comets













For millennia, comets were believed to be omens of doom. Instead, solving the mysteries regarding these "dirty snowballs" could help reveal the part they played in the birth of life on Earth, as well as secrets concerning the rest of the galaxy.

Did comets help create Earth's seas?

For years scientists thought comets slamming against the newborn Earth helped deliver water to a once dry planet. But roughly a decade ago this view was shaken by the discovery that the water in comets and Earth's oceans did not match up in terms of hydrogen isotopes.

Calculations then showed it was highly improbable that enough icy rocks from the suspected homes of comets — the Kuiper belt past Neptune and the Oort cloud past that — could have collided with Earth to supply its oceans.

In the last two years, however, researchers have discovered comets in the outer part of the asteroid belt. These "main-belt comets" may have the right levels of hydrogen isotopes, and are perhaps close enough to Earth to have realistically brought us the seas that life emerged from.

"No one knows for certain yet where Earth's oceans came from," said University of Hawaii astrophysicist David Jewitt. "Earth's oceans are likely a mixture of water from all sorts of places, but the main-belt comets are very likely one of them."

Where do comets come from?

The suspected homes of comets include the Oort cloud, the Kuiper belt and now the asteroid belt. But are there more reservoirs of comets yet to be found?

The Oort cloud is a theoretical cloud of icy rocks roughly 4.6 trillion miles (7.5 trillion kilometers) from the sun thought to be the source of long-period comets — that is, ones that take more than a few centuries to complete their orbits. It was once thought the original home of short-period comets as well, until calculations suggested that was impossible.

About 20 years ago, the Kuiper belt roughly 4.6 billion miles (7.5 billion kilometers) from the sun was then proposed to be the home of short-period comets. "But measurements taken in the last few years raise some doubts about that," Jewitt explained. "Maybe there are other reservoirs of comets yet to be discovered."

Secrets regarding the birth of the solar system?

Comets were long thought to be primordial relics, pristine leftovers from the protoplanetary disk that once surrounded the newborn sun. As such, it was supposed they might hold secrets untouched for billions of years regarding the birth of our solar system.

Increasingly, however, it looks as if the comets we see are anything but unspoiled. Instead, "there is good evidence that many of them are nearly burned-out hulks, with neither the size, mass, shape nor spin they might have had before entering the solar system," Jewitt said.

Still, "since comets are icy, they're not entirely cooked, and we may learn a lot regarding the formation of the solar system from chemicals trapped in their ice," he added.

Comets so close to the sun?

The main-belt comets are themselves a mystery. Until their discovery, researchers had largely supposed no comets could have lasted that close to the sun without getting baked away after a few centuries or millennia.

Dirt coatings on main-belt comets could have protected them from sunlight for billions of years. Every now and again boulders a yard or larger tumbling around the asteroid belt might hit these comets, uncovering their ice and triggering the plumes of gas and dust that got them discovered in the first place.

"We expect to soon find many hundreds or thousands of main-belt comets," Jewitt said.

Interstellar comets?

As our solar system formed, calculations predict the gravitational pull of the planets would have scattered 90 to 99 percent of all comets that once orbited the sun away toward the stars, never to be seen again. "If every star does that, you would expect some of their comets to come toward us, but no such object has ever been seen," Jewitt said.

Still, as astronomical telescopes and techniques improve, Jewitt remains optimistic that such interstellar comets will be detected fairly soon. These comets would prove quite distinctive, zipping at great speeds and following trajectories completely unlike the orbits our comets follow.

"We could see interstellar comets for the first time in the next few years," Jewitt predicted. "It would be great if we saw one, especially so if we had the wherewithal to launch a mission to one, to get samples and study the diversity of comets in an interstellar and galactic context. But we have to find one first."

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