Breathtaking science: biologists home in on the brain area that drives respiration.Nearly 2,400 years ago in a treatise aptly titled "On Breath," Aristotle posed a question that continues to captivate scientists today: "How can we account for the maintenance of the breath inherent in us, and for its increase?" In a suburb just outside Washington, D.C., Jeffrey C. Smith shows just how close modern researchers are to answering that question. With the aid of a powerful microscope, a computer monitor, a loudspeaker, and an array of other devices, he and a colleague use a minuscule electrode to listen in on the electrical activity of a paper-thin disc of living brain tissue. Every few seconds, the speaker crackles crackles a small, sharp sound heard on auscultation. Caused by dry, bristly hair and insufficient pressure on the stethoscope head. Also characteristic of emphysema, especially when it is subcutaneous. with sound. That recurring noise is compelling evidence that biologists have finally identified what French physiologist Jean Pierre Marie Pierre Marie (born September 9, 1853, died April 13. 1940) was a French neurologist, who began his medical career in 1878 as an assistant to the famous neurologist Jean-Martin Charcot (1825-1893) at the Salpêtrière and Bicêtre Hospitals in Paris. Flourens more than a century ago called the noeud vital--the vital node. It's the source of a body's natural breathing rhythm. Over the past decade, Smith and other neuroscientists have homed in on this rhythm-generating kernel of nerve cells. They've located it within a well-defined region of the brainstem, the part of the brain that sits at the top of the spinal cord spinal cord, the part of the nervous system occupying the hollow interior (vertebral canal) of the series of vertebrae that form the spinal column, technically known as the vertebral column. and controls most of the body's automatic functions. This brainstem area, called the pre-Botzinger complex The Pre-Bötzinger Complex (pBc) is a cluster of interneurons in the ventrolateral medulla essential to the generation of respiratory rhythm in mammals. The exact mechanism of the rhythm generation and transmission to motonucluei remains controversial and the topic of much present , appears to drive both the normal, quiet breathing pattern and more complicated breathing actions such as sighs and gasps. "We're very far along the road of solving the basic problem of how we breathe," says Smith, who works at the National Institute of Neurological Disorders and Stroke The National Institute of Neurological Disorders and Stroke is a part of the U.S. National Institutes of Health. The NINDS conducts and supports research on brain and nervous system disorders. Created by the U.S. in Bethesda, Md. That solution is of more than academic interest. Understanding how the brain controls breathing could suggest new ways to prevent sudden infant death syndrome sudden infant death syndrome (SIDS) or crib death, sudden, unexpected, and unexplained death of an apparently healthy infant under one year of age (usually between two weeks and eight months old). (SIDS SIDS sudden infant death syndrome. SIDS abbr. sudden infant death syndrome SIDS, n See syndrome, sudden infant death. ), point toward safer anesthetics Anesthetics Drugs or methodologies used to make a body area free of sensation or pain. Mentioned in: Appendectomy , and lead to better treatments for respiratory conditions such as sleep apnea sleep apnea, episodes of interrupted breathing during sleep. Obstructive sleep apnea is a common disorder in which relaxation of muscles in the throat repeatedly close off the airway during sleep; the person wakes just enough to take a gasping breath. , in which people have difficulty breathing while asleep. "There's considerable clinical relevance," says Smith. THE VITAL NODE With two treatises on the topic, Aristotle was among the first to record his thoughts on the role of breathing. "A few of the earlier natural philosophers have dealt with respiration; some of them have offered no explanation why this phenomenon occurs in living creatures; other have discussed it without much insight, and with insufficient experience of the facts," he dismissively noted. Aristotle, of course, had his own theory. He argued that breathing cools the body heat generated by the "fiery nature of the soul which exists in the heart." It was another 2,000 years before scientists began to recognize that breathing's core function is to draw in oxygen from the air and expel carbon dioxide carbon dioxide, chemical compound, CO2, a colorless, odorless, tasteless gas that is about one and one-half times as dense as air under ordinary conditions of temperature and pressure. . Although people can hold their breaths for a while and sometimes exert great control over breathing, the process usually is on autopilot. And for good reason. "From birth until death, you can't go too long without breathing," Jack Feldman of the University of California, Los Angeles UCLA comprises the College of Letters and Science (the primary undergraduate college), seven professional schools, and five professional Health Science schools. Since 2001, UCLA has enrolled over 33,000 total students, and that number is steadily rising. wryly noted in a lecture at the Society for Neuroscience For other uses, see SFN (disambiguation). The Society for Neuroscience (SfN) is a professional society for basic scientists and physicians around the world whose research is focused on the study of the brain and nervous system. meeting in Orlando last November. A person's heart can beat on its own, but it takes brainpower brain·pow·er n. 1. Intellectual capacity. 2. People of well-developed mental abilities: a country that doesn't value its brainpower. Noun 1. to drive even the automatic inhaling and exhaling ex·hale v. ex·haled, ex·hal·ing, ex·hales v.intr. 1. a. To breathe out. b. To emit air or vapor. 2. To be given off or emitted. v.tr. of air. Galen, a Greek physician who lived a few generations after Aristotle, may have been the first to realize that. He noted that gladiators gladiators [Lat.,=swordsmen], in ancient Rome, class of professional fighters, who performed for exhibition. Gladiatorial combats usually took place in amphitheaters. They probably were introduced from Etruria and originally were funeral games. and animals could usually still breathe if injured below the neck but sometimes stopped breathing immediately when suffering neck and head injuries. That observation points to the brain as the breathing center, but it doesn't indicate a specific part of the brain. When investigators in the 18th century showed that rabbits continue to breathe after their cerebrum cerebrum: see brain. cerebrum Largest part of the brain. The two cerebral hemispheres consist of an inner core of myelinated nerve fibres, the white matter, and a heavily convoluted outer cortex of gray matter (see cerebral cortex). and cerebellum cerebellum (sĕr'əbĕl`əm), portion of the brain that coordinates movements of voluntary (skeletal) muscles. It contains about half of the brain's neurons, but these particular nerve cells are so small that the cerebellum accounts for are removed, researchers began to concentrate on the brainstem. In the 1840s, Flourens narrowed the field's focus to a specific brainstem region within an area called the medulla medulla: see brain stem. . Lesions in this area, his noeud vital, stopped respiration in animals. Over the next century or so, researchers tried to better define the boundaries of the noeud vital. Initially, they mostly performed lesion experiments, and then later they began recording the electrical activity of the brains of sedated cats. "Breathing is the only movement that continues to be generated spontaneously by the brain in the deeply anesthetized a·nes·the·tize also a·naes·the·tize tr.v. a·nes·the·tized, a·nes·the·tiz·ing, a·nes·the·tiz·es To induce anesthesia in. a·nes animal," notes Smith. In the 1980s, researchers found that the neural basis of respiration could be studied in brainstems--attached to spinal cords--surgically removed from newborn rodents and kept alive in laboratory dishes. This tissue contains brainstem nerves that control muscles involved in breathing, such as the tongue and diaphragm muscles. Even in a lab dish, these nerves continue to show periodic bursts of electrical activity that the scientists concluded reflect a basic respiratory rhythm respiratory rhythm, n a regular, oscillating cycle of inspiration and expiration, controlled by neuronal impulses transmitted between the muscles of inspiration in the chest and the respiratory centers in the brain. . The bursts occur at a slower frequency than the normal breathing rate, says Smith, because the tissue is kept in oxygen-rich, lower-than-body-temperature conditions that reduce the typical bursting rate. In the mid-1980s, Smith joined Feldman's group and began an effort to further pinpoint the noeud vital. He painstakingly carved out pieces of the newborn rat brainstem and documented whether the respiratory rhythm persisted. In 1991, Smith, Feldman, and their colleagues reported that this rhythm could be traced to an area of the medulla near another brain region that controls breathing out. The region involved in exhaling had been named the Botzinger complex after a German wine that scientists were drinking when they announced its discovery, so Smith and Feldman dubbed the newly recognized area the pre-Botzinger complex (PBC PBC 1 Peripheral blood cells 2 Primary biliary cirrhosis, see there ). The investigators also reported that nerve cells within this complex exhibit periodic bursts of electrical activity. Calling these cells "pacemaker neurons," they proposed that a network of these cells is responsible for the rhythmic electrical activity observed in the nerves controlling respiratory muscles. More recently, neuroscientists have sought a more molecular way to identify which nerve cells in the PBC generate the respiratory rhythm. In 1999, Feldman's group reported rhythmic electrical activity in a set of about 600 PBC neurons that display a cell-sulfate protein that responds to a brain chemical called substance P. Two years later, the scientists established the importance of those cells. They injected the PBC of live rats with a toxin that gradually destroys nerve cells bearing the substance P receptor. For a few days after the injections, the rats breathed normally. But after the toxin had killed more than 75 percent of the targeted nerve cells, the rodents began to breath so irregularly that they could not regulate the carbon dioxide and oxygen in their blood. Some of the rats died. At the Society for Neuroscience meeting, Boston researchers investigating the origin of SIDS reported that the receptor for substance P may have led them to the human noeud vital. "We look at sites in the brainstem that are critical for the control of things like respiratory function, heart rate, and temperature control," explains David Paterson David A. Paterson (born May 20, 1954) is an American politician and the current Lieutenant Governor of New York. He is the first African American to hold this position. He was selected as running mate by New York Attorney General and Democratic Party nominee Eliot Spitzer in the of Children's Hospital A children's hospital is a hospital which offers its services exclusively to children. The number of children's hospitals proliferated in the 20th century, as pediatric medical and surgical specialties separated from internal medicine and adult surgical specialties. in Boston. "There's a body of evidence suggesting that respiratory failure Respiratory Failure Definition Respiratory failure is nearly any condition that affects breathing function or the lungs themselves and can result in failure of the lungs to function properly. is part of the underlying cause of SIDS." The investigators studied the brainstems of five infants who had died of natural causes other than SIDS. Using an antibody marker that binds to the substance P receptor, the researchers found nerve cells that carry the receptor and are in a location in the infant brains roughly corresponding to that of the PBC in rodents. "We still have a lot of work to prove that it's the same region that we see in animals," cautions Patterson. If it is, however, his team plans to investigate whether this brain region is abnormal in infants who died of SIDS or other respiratory disorders. A SIGH IN A DISH Does the PBC control all types of breathing? Yes, says Jan Marino Ramirez of the University of Chicago. He studies sighs and gasps, in addition to the typical, resting breathing pattern that scientists call eupnea eupnea /eup·nea/ (up-ne´ah) normal respiration.eupne´ic eup·ne·a n. Easy, free respiration, as is observed normally under resting conditions. . A sigh is a breath with an extended period of inspiration, according to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. Ramirez. Most people think of a sigh as the loud exhaling that follows this intake of air, he notes. Infants tend to sigh about every 10 minutes, but this frequency goes down as a person grows up. "The sigh is an arousal mechanism. Ninety percent of the time when you wake up at night, [it's] due to a sigh or starts with a sigh," notes Ramirez. On the other hand, a gasp is a much more rapid, dramatic intake of air. The gasp, says Ramirez, is largely a last-ditch effort to bring in air when the body is starved for oxygen. There's evidence that infants who die of SIDS don't sigh or gasp normally. "Basically, the two emergency mechanisms, the sigh and the gasp, are reduced [in SIDS babies]," says Ramirez. About 2 years ago, he and his colleagues reported that sighs and gasps can be discerned within the respiratory rhythm recorded with electrodes from rodent brainstem tissue. Whereas eupnea shows up as single bursts of electrical activity, occasionally a second, larger burst immediately follows this regular burst. Ramirez considers this a sigh. Moreover, if the rodent brainstem is subjected to low oxygen availability, the respiratory rhythm occasionally exhibits spasms of electrical activity that are briefer but much stronger than a typical burst. Ramirez interprets those powerful surges as the equivalent of gasps. When the investigators looked to see where each of these different bursting patterns originated in the brainstem, they found that the electrical activity always centered within the PBC. These findings stunned Ramirez. He had long thought that sighs and gasps were triggered by networks of nerve cells distinct from the one that controls normal breathing. Now, he argues that a single neural network neural network or neural computing, computer architecture modeled upon the human brain's interconnected system of neurons. Neural networks imitate the brain's ability to sort out patterns and learn from trial and error, discerning and extracting simply reconfigures itself to produce different kinds of respiration. "The same network can generate normal breathing, gasping and sighing," he says. FINDING THE RHYTHM Not everyone is convinced by the current evidence pointing to the PBC as the neural locus of breathing. Some scientists still argue that a much larger network of nerve cells drives the respiratory rhythm. Even Smith and Feldman acknowledge that there's much more to the neural control of breathing than the PBC. "The evidence is pretty unequivocal that this is a key element for the generation of respiratory rhythm. But in an intact animal, there are other things going on" that influence this rhythm, Feldman says. "You might need an engine in a car, but you can't drive down the street with just the engine." Donald McCrimmon of Northwestern University in Evanston, Ill., says that few scientists question that the rhythmic activity of the PBC in a laboratory dish reflects some aspect of breathing. "But how you really build a robust respiratory-control system-on top of this [complex] that generates a rhythm--is the really big question," he adds. An equally big question for McCrimmon and others who embrace the PBC as the noeud vital is how the basic respiratory rhythm of eupnea arises, seemingly from fewer than 1,000 nerve cells. More than a decade ago, when Feldman and Smith first proposed that the periodic electrical bursts seen in pacemaker neurons could drive that rhythm, that model made sense to many scientists. Recently, however, Feldman has developed reservations about it. "It was such a compelling and straightforward explanation that it rose from hypothesis to paradigm before one had the chance to do the experiments needed to test it," he says. In the May 30, 2002 Neuron, Feldman's group offered data reinforcing his doubts. The investigators reported that treating the PBC in rodent brainstems with a drug called riluzole didn't alter the recorded respiratory rhythm. That surprised Feldman bemuse be·muse tr.v. be·mused, be·mus·ing, be·mus·es 1. To cause to be bewildered; confuse. See Synonyms at daze. 2. To cause to be engrossed in thought. riluzole blocks the periodic electrical bursts of pacemaker neurons by inhibiting cellular pores known as ion channels. He and his colleagues concluded that the pacemaker bursting isn't at the heart of the respiratory rhythm. However, that result hasn't been confirmed. Smith's group recently conducted similar experiments and found that riluzole treatments do indeed interrupt the respiratory rhythm recorded from rodent brain tissue. And Ramirez has evidence that riluzole can block the gasping rhythm, but not the normal breathing rhythm. His studies suggest that there may be different kinds of pacemaker neurons within the PBC. These discrepancies may be related to the way the brain tissues are sliced and exposed to the drug, suggests Smith. "It's certainly something that's going to be resolved over the next few months," McCrimmon says. ONE NODE OR TWO It may take longer to address the tantalizing tan·ta·lize tr.v. tan·ta·lized, tan·ta·liz·ing, tan·ta·liz·es To excite (another) by exposing something desirable while keeping it out of reach. question of whether there's a more primitive noeud vital within the mammalian brain, an issue Feldman broached at the Society for Neuroscience meeting. He noted that opiates Opiates Analgesic, pain killing drugs, such as heroin and morphine that depress the central nervous system. Mentioned in: Withdrawal Syndromes slow a person's breathing rate, which can be a considerable problem for physicians administering opioid-based narcotics narcotics n. 1) techinically, drugs which dull the senses. 2) a popular generic term for drugs which cannot be legally possessed, sold, or transported except for medicinal uses for which a physician or dentist's prescription is required. . In still unpublished work, Feldman's group found that rats don't respond to opiates by gradually breathing slower but instead by skipping breaths. Feldman interprets his group's data as evidence for two sources of respiratory rhythm within the brainstem, an opioid-insensitive one with a naturally slow breathing rate and the PBC, which is opioid-sensitive and generates a faster respiratory rhythm. Japanese researchers have recently identified a brainstem region near the PBC that exhibits a respiratory rhythm and is insensitive to opioids, Feldman notes. "Our current thinking is that the PBC in mammals is the dominant rhythm generator, but one has to consider the role of this second group of cells," he says. Feldman speculates that this newfound area appeared early in vertebrate evolution to drive the slower respiratory rhythm of fish, amphibians amphibians members of the animal class Amphibia. Includes frogs, toads, newts, salamanders and cecilians all capable of living on land or in water. , reptiles, and other animals that don't have a diaphragm. But the faster-paced PBC arose in mammals as they evolved a bellows-like diaphragm and had a greater demand for oxygen, he suggests. A second noeud vital would add a new dimension to studies of the neural control of breathing. Still, with the PBC in hand, researchers remain confident that they are close to explaining one of the most fundamental examples of how the brain generates a behavior. "There's a reason to hope that in the not too distant future, we'll be able to say that this is the basic [brain] circuitry for generating the respiratory rhythm," says McCrimmon. |
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