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Guillaume Duchenne

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The search for ways to use electricity for medical treatment is well rooted in history. Peter Christian Abildgaard suggested the possibilities in a bizarre way in 1775, when he discovered that he could render a chicken unconscious with an electric shock, and then revive it the same way. In 1780, Luigi Galvani noticed that his static-electricity generator caused the muscles in a frog’s leg to contract. And between the late 1700s and early 1840s, when it first became known that each beat of the heart was accompanied by an electrical pulse, there was an explosion of interest in using electricity either to study or cure the body.  
 
The search for ways to use electricity for medical treatment is well rooted in history. Peter Christian Abildgaard suggested the possibilities in a bizarre way in 1775, when he discovered that he could render a chicken unconscious with an electric shock, and then revive it the same way. In 1780, Luigi Galvani noticed that his static-electricity generator caused the muscles in a frog’s leg to contract. And between the late 1700s and early 1840s, when it first became known that each beat of the heart was accompanied by an electrical pulse, there was an explosion of interest in using electricity either to study or cure the body.  
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Duchenne also employed the relatively new technology of photography to document his results, using a variety of subjects including actors, children and Parisian indigents. He published a book of his findings in 1862 that remained a standard text for many years.  
 
Duchenne also employed the relatively new technology of photography to document his results, using a variety of subjects including actors, children and Parisian indigents. He published a book of his findings in 1862 that remained a standard text for many years.  
  
Remembered as the father of electrotherapy and neuropathology, Duchenne’s name is memorialized in the disease Duchenne Muscular Dystrophy, one of the debilitating diseases that he hoped electrical stimulation might alleviate. But Duchenne’s work was little appreciated at the time. When he died in 1875, the direct use of electricity for questionable medical purposes (rather than simply studying its effects on the body) was reaching its height. For the next 75 years, machines using “faradic” or “galvanic” (dc) electricity would remain in widespread use. Although few of these devices produced reliable results, it would be many decades before physicians were finally convinced that electrotherapy had only a very limited value in clinical medicine. Eventually, however, the findings of the early pioneers such as Duchenne helped establish the basis for clinical neurology and paved the way for more sophisticated treatment methods.
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Remembered as the father of electrotherapy and neuropathology, Duchenne’s name is memorialized in the disease Duchenne Muscular Dystrophy, one of the debilitating diseases that he hoped electrical stimulation might alleviate. But Duchenne’s work was little appreciated at the time. When he died in 1875, the direct use of electricity for questionable medical purposes (rather than simply studying its effects on the body) was reaching its height. For the next 75 years, machines using “faradic” or “galvanic” (dc) electricity would remain in widespread use. Although few of these devices produced reliable results, it would be many decades before physicians were finally convinced that electrotherapy had only a very limited value in clinical medicine. Eventually, however, the findings of the early pioneers such as Duchenne helped establish the basis for clinical neurology and paved the way for more sophisticated treatment methods.  
  
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'''French physician Guillaume Duchenne specialized in the study of muscles and how they worked. In 1868 he was the first to extensively describe the progressive and destructive neuromuscular disorder now known as Duchenne Muscular Dystrophy (DMD). DMD causes the atrophy—or wasting away—of muscles. Duchenne is also considered the father of electrotherapy, or the use of electricity for medical purposes, as well as the father of neurology.'''
  
'''French physician Guillaume Duchenne specialized in the study of muscles and how they worked. In 1868 he was the first to extensively describe the progressive and destructive neuromuscular disorder now known as Duchenne Muscular Dystrophy (DMD). DMD causes the atrophy—or wasting away—of muscles. Duchenne is also considered the father of electrotherapy, or the use of electricity for medical purposes, as well as the father of neurology.'''
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'''Duchenne was born in 1806 in Boulogne-sur-Mer, a French coastal town. His father was a mariner, but Duchenne was not interested in following that path and instead pursued a career in medicine. In his mid-20s Duchenne’s wife died during childbirth. This led to a depression and he almost entirely abandoned his field. Then, at the age of 36, Duchenne moved to Paris and developed a fascination with the ability of electricity, when applied to a patient’s skin, to cause muscle contractions.'''  
  
'''Duchenne was born in 1806 in Boulogne-sur-Mer, a French coastal town. His father was a mariner, but Duchenne was not interested in following that path and instead pursued a career in medicine. In his mid-20s Duchenne’s wife died during childbirth. This led to a depression and he almost entirely abandoned his field. Then, at the age of 36, Duchenne moved to Paris and developed a fascination with the ability of electricity, when applied to a patient’s skin, to cause muscle contractions.'''
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'''In the 1840s, shortly after Michael Faraday’s invention of the induction coil, Duchenne began using the new invention to study paralysis and the ways that muscles contract. By applying voltage to muscles, even the muscles of the paralyzed or the recently dead, it was possible to make the muscle tissue twitch. Duchenne’s studies concentrated on the muscles of the hand, arm, foot, and face, and used what he called “localized faradization” (connecting the induction coil to the skin near the muscle) to determine what kind of electric shock resulted in a particular movement. He discovered that most motions were caused by a group of muscles working together rather than just a single muscle. He made a series of famous photographs showing how the muscles of the face were used to create facial expressions such as smiles and frowns and mapped these movements out. He noted, for example, that a fake smile used only the muscles around the mouth, but that a genuine smile caused facial contractions around the eyes.'''  
  
'''In the 1840s, shortly after Michael Faraday’s invention of the induction coil, Duchenne began using the new invention to study paralysis and the ways that muscles contract. By applying voltage to muscles, even the muscles of the paralyzed or the recently dead, it was possible to make the muscle tissue twitch. Duchenne’s studies concentrated on the muscles of the hand, arm, foot, and face, and used what he called “localized faradization” (connecting the induction coil to the skin near the muscle) to determine what kind of electric shock resulted in a particular movement. He discovered that most motions were caused by a group of muscles working together rather than just a single muscle. He made a series of famous photographs showing how the muscles of the face were used to create facial expressions such as smiles and frowns and mapped these movements out. He noted, for example, that a fake smile used only the muscles around the mouth, but that a genuine smile caused facial contractions around the eyes.'''
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'''Duchenne also attempted to use the induction coil as therapy for paralyzed patients. His pioneering work led eventually to the field of neurology, or the study of the nervous system. He remained hopeful that electricity would one day be used to help those suffering from DMD.'''  
  
'''Duchenne also attempted to use the induction coil as therapy for paralyzed patients. His pioneering work led eventually to the field of neurology, or the study of the nervous system. He remained hopeful that electricity would one day be used to help those suffering from DMD.'''
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'''In his later years, Duchenne suffered another deep depression after his son died. Duchenne died in 1875 after suffering a cerebral hemorrhage.'''  
  
'''In his later years, Duchenne suffered another deep depression after his son died. Duchenne died in 1875 after suffering a cerebral hemorrhage.'''
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== '''Further Reading'''  ==
  
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The Mechanism of Human Facial Expression.
  
== '''Further Reading''' ==
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G.-B. Duchenne de Boulogne.&nbsp;New York: Cambridge University Press, 1990.
 
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== '''Further Reading'''<br> ==
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Revision as of 16:06, 8 September 2008

Guillaume Duchenne: The Father of Electrotherapy and Neuropathology

Duchenne2.jpg

The search for ways to use electricity for medical treatment is well rooted in history. Peter Christian Abildgaard suggested the possibilities in a bizarre way in 1775, when he discovered that he could render a chicken unconscious with an electric shock, and then revive it the same way. In 1780, Luigi Galvani noticed that his static-electricity generator caused the muscles in a frog’s leg to contract. And between the late 1700s and early 1840s, when it first became known that each beat of the heart was accompanied by an electrical pulse, there was an explosion of interest in using electricity either to study or cure the body.

One of the key researchers during this period was French physician Guillaume Duchenne (1806-1875). Beginning in the 1840s, Duchenne used either batteries or Michael Faraday’s recently invented induction coil to apply currents to make muscles twitch, mapping the paths the current took through the body. As he learned more about the body, he found ways to apply the electrodes to isolate certain muscles. Conducting extensive experiments on the hands, feet and arms, he carefully mapped the muscles that cause smiles, frowns, looks of anxiety and other facial expressions. He also made limited progress using “faradic” (ac) currents to treat paralysis, finding that by applying high currents, certain patients could regain use of their muscles

Duchenne also employed the relatively new technology of photography to document his results, using a variety of subjects including actors, children and Parisian indigents. He published a book of his findings in 1862 that remained a standard text for many years.

Remembered as the father of electrotherapy and neuropathology, Duchenne’s name is memorialized in the disease Duchenne Muscular Dystrophy, one of the debilitating diseases that he hoped electrical stimulation might alleviate. But Duchenne’s work was little appreciated at the time. When he died in 1875, the direct use of electricity for questionable medical purposes (rather than simply studying its effects on the body) was reaching its height. For the next 75 years, machines using “faradic” or “galvanic” (dc) electricity would remain in widespread use. Although few of these devices produced reliable results, it would be many decades before physicians were finally convinced that electrotherapy had only a very limited value in clinical medicine. Eventually, however, the findings of the early pioneers such as Duchenne helped establish the basis for clinical neurology and paved the way for more sophisticated treatment methods.


French physician Guillaume Duchenne specialized in the study of muscles and how they worked. In 1868 he was the first to extensively describe the progressive and destructive neuromuscular disorder now known as Duchenne Muscular Dystrophy (DMD). DMD causes the atrophy—or wasting away—of muscles. Duchenne is also considered the father of electrotherapy, or the use of electricity for medical purposes, as well as the father of neurology.

Duchenne was born in 1806 in Boulogne-sur-Mer, a French coastal town. His father was a mariner, but Duchenne was not interested in following that path and instead pursued a career in medicine. In his mid-20s Duchenne’s wife died during childbirth. This led to a depression and he almost entirely abandoned his field. Then, at the age of 36, Duchenne moved to Paris and developed a fascination with the ability of electricity, when applied to a patient’s skin, to cause muscle contractions.

In the 1840s, shortly after Michael Faraday’s invention of the induction coil, Duchenne began using the new invention to study paralysis and the ways that muscles contract. By applying voltage to muscles, even the muscles of the paralyzed or the recently dead, it was possible to make the muscle tissue twitch. Duchenne’s studies concentrated on the muscles of the hand, arm, foot, and face, and used what he called “localized faradization” (connecting the induction coil to the skin near the muscle) to determine what kind of electric shock resulted in a particular movement. He discovered that most motions were caused by a group of muscles working together rather than just a single muscle. He made a series of famous photographs showing how the muscles of the face were used to create facial expressions such as smiles and frowns and mapped these movements out. He noted, for example, that a fake smile used only the muscles around the mouth, but that a genuine smile caused facial contractions around the eyes.

Duchenne also attempted to use the induction coil as therapy for paralyzed patients. His pioneering work led eventually to the field of neurology, or the study of the nervous system. He remained hopeful that electricity would one day be used to help those suffering from DMD.

In his later years, Duchenne suffered another deep depression after his son died. Duchenne died in 1875 after suffering a cerebral hemorrhage.


Further Reading

The Mechanism of Human Facial Expression.

G.-B. Duchenne de Boulogne. New York: Cambridge University Press, 1990.

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