The invention:Adevice that provided the first direct evidence that the Sun runs on thermonuclear power and challenged existing models of the Sun. The people behind the invention: Raymond Davis, Jr. (1914- ), an American chemist John Norris Bahcall (1934- ), an American astrophysicist Missing Energy In 1871, Hermann von Helmholtz, the German physicist, anatomist, and physiologist, suggested that no ordinary chemical reaction could be responsible for the enormous energy output of the Sun. By the 1920’s, astrophysicists had realized that the energy radiated by the Sun must come from nuclear fusion, in which protons or nuclei combine to form larger nuclei and release energy.
The invention: The first commercially practical synthetic rubber, Neoprene gave a boost to polymer chemistry and the search for new materials. The people behind the invention: Wallace Hume Carothers (1896-1937), an American chemist Arnold Miller Collins (1899- ), an American chemist Elmer Keiser Bolton (1886-1968), an American chemist Julius Arthur Nieuwland (1879-1936), a Belgian American priest, botanist, and chemist Synthetic Rubber: A Mirage? The growing dependence of the industrialized nations upon elastomers (elastic substances) and the shortcomings of natural rubber motivated the twentieth century quest for rubber substitutes. By 1914
The invention: System of high-speed cooking that uses microwave radition to agitate liquid molecules to raise temperatures by friction. The people behind the invention: Percy L. Spencer (1894-1970), an American engineer Heinrich Hertz (1857-1894), a German physicist James Clerk Maxwell (1831-1879), a Scottish physicist The Nature of Microwaves Microwaves are electromagnetic waves, as are radio waves, X rays, and visible light. Water waves
Memory metal The invention: Known as nitinol, a metal alloy that returns to its original shape, after being deformed, when it is heated to the proper temperature. The person behind the invention: William Buehler (1923- ), an American metallurgist The Alloy with a Memory In 1960,William Buehler developed an alloy that consisted of 53 to 57 percent nickel (by weight) and the balance titanium. This alloy, which is called nitinol, turned out to have remarkable properties. Nitinol is a “memory metal,” which means that, given the proper conditions, objects made of nitinol can be restored to their original shapes even after they have been radically deformed. The return to the original shape
The invention: The first device used to measure the mass of atoms, which was found to be the result of the combination of isotopes. The people behind the invention: Francis William Aston (1877-1945), an English physicist who was awarded the 1922 Nobel Prize in Chemistry Sir Joseph John Thomson (1856-1940), an English physicist William Prout (1785-1850), an English biochemist Ernest Rutherford (1871-1937), an English physicist Same Element, Different Weights Isotopes are different forms of a chemical element that act similarly in chemical or physical reactions. Isotopes differ in two ways: They possess different atomic weights and different radioactive transformations. In 1803, John Dalton proposed a new atomic theory of chemistry that claimed that chemical elements in a compound combine by weight in whole number proportions to one another. By 1815, William Prout had taken Dalton’s hypothesis one step further and claimed that the atomic weights of elements were integral (the integers are the positive and negative whole numbers and zero) multiples
The invention: Early digital calculator designed to solve differential equations that was a forerunner of modern computers. The people behind the invention: Howard H. Aiken (1900-1973), Harvard University professor and architect of the Mark I Clair D. Lake (1888-1958), a senior engineer at IBM Francis E. Hamilton (1898-1972), an IBM engineer Benjamin M. Durfee (1897-1980), an IBM engineer The Human Computer The physical world can be described by means of mathematics. In principle, one can accurately describe nature down to the smallest detail.
The invention: The first X-ray procedure for detecting and diagnosing
breast cancer.
The people behind the invention:
Albert Salomon, the first researcher to use X-ray technology
instead of surgery to identify breast cancer
Jacob Gershon-Cohen (1899-1971), a breast cancer researcher
Studying Breast Cancer
Medical researchers have been studying breast cancer for more
than a century. At the end of the nineteenth century, however, no one
knew how to detect breast cancer until it was quite advanced. Often,
by the time it was detected, it was too late for surgery; many patients
who did have surgery died. So after X-ray technology first appeared
in 1896, cancer researchers were eager to experiment with it.
The first scientist to use X-ray techniques in breast cancer experiments
was Albert Salomon, a German surgeon. Trying to develop a
biopsy technique that could tell which tumors were cancerous and
thereby avoid unnecessary surgery, he X-rayed more than three
thousand breasts that had been removed from patients during breast
cancer surgery. In 1913, he published the results of his experiments,
showing that X rays could detect breast cancer. Different types of Xray
images, he said, showed different types of cancer.
Though Salomon is recognized as the inventor of breast radiology,
he never actually used his technique to diagnose breast cancer.
In fact, breast cancer radiology, which came to be known as “mammography,”
was not taken up quickly by other medical researchers.
Those who did try to reproduce his research often found that their
results were not conclusive.
During the 1920’s, however, more research was conducted in Leipzig,
Germany, and in South America. Eventually, the Leipzig researchers,
led by Erwin Payr, began to use mammography to diagnose
cancer. In the 1930’s, a Leipzig researcher named W. Vogel
published a paper that accurately described differences between
cancerous and noncancerous tumors as they appeared on X-ray photographs. Researchers in the United States paid little attention to
mammography until 1926. That year, a physician in Rochester, New
York, was using a fluoroscope to examine heart muscle in a patient
and discovered that the fluoroscope could be used to make images of
breast tissue as well. The physician, Stafford L. Warren, then developed
a stereoscopic technique that he used in examinations before
surgery. Warren published his findings in 1930; his article also described
changes in breast tissue that occurred because of pregnancy,
lactation (milk production), menstruation, and breast disease. Yet
Stafford’s technique was complicated and required equipment that
most physicians of the time did not have. Eventually, he lost interest
in mammography and went on to other research.
Using the Technique
In the late 1930’s, Jacob Gershon-Cohen became the first clinician
to advocate regular mammography for all women to detect breast
cancer before it became a major problem. Mammography was not
very expensive, he pointed out, and it was already quite accurate. A
milestone in breast cancer research came in 1956, when Gershon-
Cohen and others began a five-year study of more than 1,300 women
to test the accuracy of mammography for detecting breast cancer.
Each woman studied was screened once every six months. Of the
1,055 women who finished the study, 92 were diagnosed with benign
tumors and 23 with malignant tumors. Remarkably, out of all
these, only one diagnosis turned out to be wrong.
During the same period, Robert Egan of Houston began tracking
breast cancer X rays. Over a span of three years, one thousand X-ray
photographs were used to make diagnoses. When these diagnoses
were compared to the results of surgical biopsies, it was confirmed
that mammography had produced 238 correct diagnoses of cancer,
out of 240 cases. Egan therefore joined the crusade for regular breast
cancer screening.
Once mammography was finally accepted by doctors in the late
1950’s and early 1960’s, researchers realized that they needed a way
to teach mammography quickly and effectively to those who would
use it. A study was done, and it showed that any radiologist could
conduct the procedure with only five days of training.In the early 1970’s, the American Cancer Society and the National
Cancer Institute joined forces on a nationwide breast cancer
screening program called the “Breast Cancer Detection Demonstration
Project.” Its goal in 1971 was to screen more than 250,000
women over the age of thirty-five.
Since the 1960’s, however, some people had argued that mammography
was dangerous because it used radiation on patients. In
1976, Ralph Nader, a consumer advocate, stated that women who
were to undergo mammography should be given consent forms
that would list the dangers of radiation. In the years that followed,
mammography was refined to reduced the amount of radiation
needed to detect cancer. It became a standard tool for diagnosis, and
doctors recommended that women have a mammogram every two
or three years after the age of forty.
Impact
Radiology is not a science that concerns only breast cancer screening.
While it does provide the technical facilities necessary to practice
mammography, the photographic images obtained must be interpreted
by general practitioners, as well as by specialists. Once Gershon-Cohen had demonstrated the viability of the technique, a
means of training was devised that made it fairly easy for clinicians
to learn how to practice mammography successfully. Once all these
factors—accuracy, safety, simplicity—were in place, mammography
became an important factor in the fight against breast cancer.
The progress made in mammography during the twentieth century
was a major improvement in the effort to keep more women
from dying of breast cancer. The disease has always been one of the
primary contributors to the number of female cancer deaths that occur
annually in the United States and around the world. This high
figure stems from the fact that women had no way of detecting the
disease until tumors were in an advanced state.
Once Salomon’s procedure was utilized, physicians had a means
by which they could look inside breast tissue without engaging in
exploratory surgery, thus giving women a screening technique that
was simple and inexpensive. By 1971, a quarter million women over
age thirty-five had been screened. Twenty years later, that number
was in the millions.
The invention: System for conveying voice signals via wires over
long distances.
The people behind the invention:
Alexander Graham Bell (1847-1922), a Scottish American
inventor
Thomas A. Watson (1854-1934), an American electrical engineer
The Problem of Distance
The telephone may be the most important invention of the nineteenth
century. The device developed by Alexander Graham Bell
and Thomas A. Watson opened a new era in communication and
made it possible for people to converse over long distances for the
first time. During the last two decades of the nineteenth century and
the first decade of the twentieth century, the American Telephone
and Telegraph (AT&T) Company continued to refine and upgrade
telephone facilities, introducing such innovations as automatic dialing
and long-distance service.
One of the greatest challenges faced by Bell engineers was to
develop a way of maintaining signal quality over long distances.
Telephone wires were susceptible to interference from electrical
storms and other natural phenomena, and electrical resistance
and radiation caused a fairly rapid drop-off in signal strength,
which made long-distance conversations barely audible or unintelligible.
By 1900, Bell engineers had discovered that signal strength could
be improved somewhat by wrapping the main wire conductor with
thinner wires called “loading coils” at prescribed intervals along
the length of the cable. Using this procedure, Bell extended longdistance
service from New York to Denver, Colorado, which was
then considered the farthest point that could be reached with acceptable
quality. The result, however, was still unsatisfactory, and
Bell engineers realized that some form of signal amplification would
be necessary to improve the quality of the signal.A breakthrough came in 1906, when Lee de Forest invented the
“audion tube,” which could send and amplify radio waves. Bell scientists
immediately recognized the potential of the new device for
long-distance telephony and began building amplifiers that would
be placed strategically along the long-distance wire network.
Work progressed so quickly that by 1909, Bell officials were predicting
that the first transcontinental long-distance telephone service,
between New York and San Francisco, was imminent. In that
year, Bell president Theodore N. Vail went so far as to promise the
organizers of the Panama-Pacific Exposition, scheduled to open in
San Francisco in 1914, that Bell would offer a demonstration at
the exposition. The promise was risky, because certain technical
problems associated with sending a telephone signal over a 4,800-
kilometer wire had not yet been solved. De Forest’s audion tube was
a crude device, but progress was being made.
Two more breakthroughs came in 1912, when de Forest improved
on his original concept and Bell engineer Harold D. Arnold
improved it further. Bell bought the rights to de Forest’s vacuumtube
patents in 1913 and completed the construction of the New
York-San Francisco circuit. The last connection was made at the
Utah-Nevada border on June 17, 1914.
Success Leads to Further Improvements
Bell’s long-distance network was tested successfully on June 29,
1914, but the official demonstration was postponed until January
25, 1915, to accommodate the Panama-Pacific Exposition, which
had also been postponed. On that date, a connection was established
between Jekyll Island, Georgia, where Theodore Vail was recuperating
from an illness, and New York City, where Alexander
Graham Bell was standing by to talk to his former associate Thomas
Watson, who was in San Francisco. When everything was in place,
the following conversation took place. Bell: “Hoy! Hoy! Mr. Watson?
Are you there? Do you hear me?”Watson: “Yes, Dr. Bell, I hear
you perfectly. Do you hear me well?” Bell: “Yes, your voice is perfectly
distinct. It is as clear as if you were here in New York.”
The first transcontinental telephone conversation transmitted
by wire was followed quickly by another that was transmitted via radio. Although the Bell company was slow to recognize the potential
of radio wave amplification for the “wireless” transmission
of telephone conversations, by 1909 the company had made a significant
commitment to conduct research in radio telephony. On
April 4, 1915, a wireless signal was transmitted by Bell technicians
from Montauk Point on Long Island, New York, to Wilmington,
Delaware, a distance of more than 320 kilometers. Shortly thereafter,
a similar test was conducted between New York City and
Brunswick, Georgia, via a relay station at Montauk Point. The total
distance of the transmission was more than 1,600 kilometers. Finally,
in September, 1915, Vail placed a successful transcontinental radiotelephone
call from his office in New York to Bell engineering chief
J. J. Carty in San Francisco.
Only a month later, the first telephone transmission across the
Atlantic Ocean was accomplished via radio from Arlington, Virginia,
to the Eiffel Tower in Paris, France. The signal was detectable,
although its quality was poor. It would be ten years before true
transatlantic radio-telephone service would begin.
The Bell company recognized that creating a nationwide longdistance
network would increase the volume of telephone calls simply
by increasing the number of destinations that could be reached
from any single telephone station. As the network expanded, each
subscriber would have more reason to use the telephone more often,
thereby increasing Bell’s revenues. Thus, the company’s strategy
became one of tying local and regional networks together to create
one large system.
Impact
Just as the railroads had interconnected centers of commerce, industry,
and agriculture all across the continental United States in the
nineteenth century, the telephone promised to bring a new kind of
interconnection to the country in the twentieth century: instantaneous
voice communication. During the first quarter century after
the invention of the telephone and during its subsequent commercialization,
the emphasis of telephone companies was to set up central
office switches that would provide interconnections among
subscribers within a fairly limited geographical area. Large cities were wired quickly, and by the beginning of the twentieth century
most were served by telephone switches that could accommodate
thousands of subscribers.
The development of intercontinental telephone service was a
milestone in the history of telephony for two reasons. First, it was a
practical demonstration of the almost limitless applications of this
innovative technology. Second, for the first time in its brief history,
the telephone network took on a national character. It became clear
that large central office networks, even in large cities such as New
York, Chicago, and Baltimore, were merely small parts of a much
larger, universally accessible communication network that spanned
a continent. The next step would be to look abroad, to Europe and
beyond.
The invention: The first radio transmissions fromthe United States
to Europe opened a new era in telecommunications.
The people behind the invention:
Guglielmo Marconi (1874-1937), Italian inventor of transatlantic
telegraphy
Reginald Aubrey Fessenden (1866-1932), an American radio
engineer
Lee de Forest (1873-1961), an American inventor
Harold D. Arnold (1883-1933), an American physicist
John J. Carty (1861-1932), an American electrical engineer
An Accidental Broadcast
The idea of commercial transatlantic communication was first
conceived by Italian physicist and inventor Guglielmo Marconi, the
pioneer of wireless telegraphy. Marconi used a spark transmitter to
generate radio waves that were interrupted, or modulated, to form
the dots and dashes of Morse code. The rapid generation of sparks
created an electromagnetic disturbance that sent radio waves of different
frequencies into the air—a broad, noisy transmission that was
difficult to tune and detect.
The inventor Reginald Aubrey Fessenden produced an alternative
method that became the basis of radio technology in the twentieth
century. His continuous radio waves kept to one frequency,
making them much easier to detect at long distances. Furthermore,
the continuous waves could be modulated by an audio signal, making
it possible to transmit the sound of speech.
Fessenden used an alternator to generate electromagnetic waves
at the high frequencies required in radio transmission. It was specially
constructed at the laboratories of the General Electric Company.
The machine was shipped to Brant Rock, Massachusetts, in
1906 for testing. Radio messages were sent to a boat cruising offshore,
and the feasibility of radiotelephony was thus demonstrated.
Fessenden followed this success with a broadcast of messages and music between Brant Rock and a receiving station constructed at
Plymouth, Massachusetts.
The equipment installed at Brant Rock had a range of about 160
kilometers. The transmission distance was determined by the strength
of the electric power delivered by the alternator, which was measured
in watts. Fessenden’s alternator was rated at 500 watts, but it
usually delivered much less power.
Yet this was sufficient to send a radio message across the Atlantic.
Fessenden had built a receiving station at Machrihanish, Scotland,
to test the operation of a large rotary spark transmitter that he
had constructed. An operator at this station picked up the voice of
an engineer at Brant Rock who was sending instructions to Plymouth.
Thus, the first radiotelephone message had been sent across
the Atlantic by accident. Fessenden, however, decided not to make
this startling development public. The station at Machrihanish was
destroyed in a storm, making it impossible to carry out further tests.
The successful transmission undoubtedly had been the result of exceptionally
clear atmospheric conditions that might never again favor
the inventor.
One of the parties following the development of the experiments
in radio telephony was the American Telephone and Telegraph
(AT&T) Company. Fessenden entered into negotiations to sell his
system to the telephone company, but, because of the financial panic
of 1907, the sale was never made.
Virginia to Paris and Hawaii
The English physicist John Ambrose Fleming had invented a twoelement
(diode) vacuum tube in 1904 that could be used to generate
and detect radio waves. Two years later, the American inventor Lee
de Forest added a third element to the diode to produce his “audion”
(triode), which was a more sensitive detector. John J. Carty, head of a
research and development effort at AT&T, examined these new devices
carefully. He became convinced that an electronic amplifier, incorporating
the triode into its design, could be used to increase the
strength of telephone signals and to long distances.
On Carty’s advice, AT&T purchased the rights to de Forest’s
audion. A team of about twenty-five researchers, under the leadership of physicist Harold D. Arnold, were assigned the job of perfecting
the triode and turning it into a reliable amplifier. The improved
triode was responsible for the success of transcontinental cable telephone
service, which was introduced in January, 1915. The triode
was also the basis of AT&T’s foray into radio telephony.
Carty’s research plan called for a system with three components:
an oscillator to generate the radio waves, a modulator to add the
audio signals to the waves, and an amplifier to transmit the radio
waves. The total power output of the system was 7,500 watts,
enough to send the radio waves over thousands of kilometers.The apparatus was installed in the U.S. Navy’s radio tower in
Arlington, Virginia, in 1915. Radio messages from Arlington were
picked up at a receiving station in California, a distance of 4,000 kilometers,
then at a station in Pearl Harbor, Hawaii, which was 7,200
kilometers from Arlington. AT&T’s engineers had succeeded in
joining the company telephone lines with the radio transmitter at
Arlington; therefore, the president of AT&T, Theodore Vail, could
pick up his telephone and talk directly with someone in California.
The next experiment was to send a radio message fromArlington
to a receiving station set up in the Eiffel Tower in Paris. After several
unsuccessful attempts, the telephone engineers in the Eiffel Tower
finally heard Arlington’s messages on October 21, 1915. The AT&T
receiving station in Hawaii also picked up the messages. The two receiving
stations had to send their reply by telegraph to the United
States because both stations were set up to receive only. Two-way
radio communication was still years in the future.
Impact
The announcement that messages had been received in Paris was
front-page news and brought about an outburst of national pride in
the United States. The demonstration of transatlantic radio telephony
was more important as publicity for AT&T than as a scientific
advance. All the credit went to AT&T and to Carty’s laboratory.
Both Fessenden and de Forest attempted to draw attention to their
contributions to long-distance radio telephony, but to no avail. The
Arlington-to-Paris transmission was a triumph for corporate public
relations and corporate research.
The development of the triode had been achieved with large
teams of highly trained scientists—in contrast to the small-scale efforts
of Fessenden and de Forest, who had little formal scientific
training. Carty’s laboratory was an example of the new type of industrial
research that was to dominate the twentieth century. The
golden days of the lone inventor, in the mold of Thomas Edison or
Alexander Graham Bell, were gone.
In the years that followed the first transatlantic radio telephone
messages, little was done by AT&T to advance the technology or to
develop a commercial service. The equipment used in the 1915 demonstration was more a makeshift laboratory apparatus than a prototype
for a new radio technology. The messages sent were short and
faint. There was a great gulf between hearing “hello” and “goodbye”
amid the static. The many predictions of a direct telephone
connection between New York and other major cities overseas were
premature. It was not until 1927 that a transatlantic radio circuit was
opened for public use. By that time, a new technological direction
had been taken, and the method used in 1915 had been superseded
by shortwave radio communication.
The invention: Technique using laser light beams to vaporize the
plaque that clogs arteries.
The people behind the invention:
Albert Einstein (1879-1955), a theoretical American physicist
Theodore Harold Maiman (1927- ), inventor of the laser
Light, Lasers, and Coronary Arteries
Visible light, a type of electromagnetic radiation, is actually a
form of energy. The fact that the light beams produced by a light
bulb can warm an object demonstrates that this is the case. Light
beams are radiated in all directions by a light bulb. In contrast, the
device called the “laser” produces light that travels in the form of a
“coherent” unidirectional beam. Coherent light beams can be focused
on very small areas, generating sufficient heat to melt steel.
The term “laser” was invented in 1957 by R. Gordon Gould of
Columbia University. It stands for light amplification by stimulated
emission of radiation, the means by which laser light beams are
made. Many different materials—including solid ruby gemstones,
liquid dye solutions, and mixtures of gases—can produce such
beams in a process called “lasing.” The different types of lasers yield
light beams of different colors that have many uses in science, industry,
and medicine. For example, ruby lasers, which were developed
in 1960, are widely used in eye surgery. In 1983, a group of
physicians in Toulouse, France, used a laser for cardiovascular treatment.
They used the laser to vaporize the “atheroma” material that
clogs the arteries in the condition called “atherosclerosis.” The technique
that they used is known as “laser vaporization surgery.”
Laser Operation, Welding, and Surgery
Lasers are electronic devices that emit intense beams of light
when a process called “stimulated emission” occurs. The principles
of laser operation, including stimulated emission, were established
by Albert Einstein and other scientists in the first third of the twentieth century. In 1960, Theodore H. Maiman of the Hughes Research
Center in Malibu, California, built the first laser, using a ruby crystal
to produce a laser beam composed of red light.
All lasers are made up of three main components. The first of
these, the laser’s “active medium,” is a solid (like Maiman’s ruby
crystal), a liquid, or a gas that can be made to lase. The second component
is a flash lamp or some other light energy source that puts
light into the active medium. The third component is a pair of mirrors
that are situated on both sides of the active medium and are designed
in such a way that one mirror transmits part of the energy
that strikes it, yielding the light beam that leaves the laser.
Lasers can produce energy because light is one of many forms of
energy that are called, collectively, electromagnetic radiation (among
the other forms of electromagnetic radiation are X rays and radio
waves). These forms of electromagnetic radiation have different wavelengths;
the smaller the wavelength, the higher the energy level. The
energy level is measured in units called “quanta.” The emission of
light quanta from atoms that are said to be in the “excited state” produces
energy, and the absorption of quanta by unexcited atoms—
atoms said to be in the “ground state”—excites those atoms.
The familiar light bulb spontaneously and haphazardly emits
light of many wavelengths from excited atoms. This emission occurs
in all directions and at widely varying times. In contrast, the
light reflection between the mirrors at the ends of a laser causes all
of the many excited atoms present in the active medium simultaneously
to emit light waves of the same wavelength. This process is
called “stimulated emission.”
Stimulated emission ultimately causes a laser to yield a beam of
coherent light, which means that the wavelength, emission time,
and direction of all the waves in the laser beam are the same. The
use of focusing devices makes it possible to convert an emitted laser
beam into a point source that can be as small as a few thousandths of
an inch in diameter. Such focused beams are very hot, and they can
be used for such diverse functions as cutting or welding metal objects
and performing delicate surgery. The nature of the active medium
used in a laser determines the wavelength of its emitted light
beam; this in turn dictates both the energy of the emitted quanta and
the appropriate uses for the laser.Maiman’s ruby laser, for example, has been used since the 1960’s
in eye surgery to reattach detached retinas. This is done by focusing
the laser on the tiny retinal tear that causes a retina to become detached.
The very hot, high-intensity light beam then “welds” the
retina back into place, bloodlessly, by burning it to produce scar tissue.
The burning process has no effect on nearby tissues. Other
types of lasers have been used in surgeries on the digestive tract and
the uterus since the 1970’s.
In 1983, a group of physicians began using lasers to treat cardiovascular
disease. The original work, which was carried out by a
number of physicians in Toulouse, France, involved the vaporization
of atheroma deposits (atherosclerotic plaque) in a human artery. This very exciting event added a new method to medical science’s
arsenal of life-saving techniques.
Consequences
Since their discovery, lasers have been used for many purposes
in science and industry. Such uses include the study of the laws of
chemistry and physics, photography, communications, and surveying.
Lasers have been utilized in surgery since the mid-1960’s, and
their use has had a tremendous impact on medicine. The first type
of laser surgery to be conducted was the repair of detached retinas
via ruby lasers. This technique has become the method of choice for
such eye surgery because it takes only minutes to perform rather
than the hours required for conventional surgical methods. It is also
beneficial because the lasing of the surgical site cauterizes that site,
preventing bleeding.
In the late 1970’s, the use of other lasers for abdominal cancer
surgery and uterine surgery began and flourished. In these
forms of surgery, more powerful lasers are used. In the 1980’s,
laser vaporization surgery (LVS) began to be used to clear atherosclerotic
plaque (atheromas) from clogged arteries. This methodology
gives cardiologists a useful new tool. Before LVS was
available, surgeons dislodged atheromas by means of “transluminal
angioplasty,” which involved pushing small, fluoroscopeguided
inflatable balloons through clogged arteries.