RHYTHM OF THE HEART

The world which surrounds us is saturated with rhythms. We encounter them incessantly, from the very first moments of our lives. Rhythm is the movement of the cradle and the song which accompanies it, the blinking of a lighthouse and the pounding of waves against the shore, the rocking of a train and the croaking of frogs near the tracks. The rhythms of the world penetrate us, introducing their own meter and compelling us to respond. The first peoples associated rhythm with birth. A god in the Polynesian islands molded a small clay figurine of a woman-mother and danced before her for three days and three nights. Drums accelerated the rhythm, and with every movement of his dancing body he enticed and pleaded. Until, finally, as Czeslaw Milosz writes, matter could no longer maintain its inertia. The first tremor of rhythm ran through her awakening her from a timeless sleep. Her response was hesitant: she extended a knee as if testing to see whether she really was something other than earth.

And perhaps this rhythm, beaten out on drums, came from the depths of the universe? Maybe it was triggered by signals issuing from intergalactic spaces-regular, measured signals emitted from the interior of colossal bodies next to which our sun is a dust mote? This gigantic aggregate of matter, the sources of powerful magnetic and gravitational fields-neutron stars-send into the universe-and to us-radio waves of tremendous intensity. They possess such perfect regularity that the centers from which they come are called pulsars. Is it impossible to imagine pulsars imposing their rhythm on the beating drums, and then to imagine the first pulse of blood, coursing through man just awakening to life, as a response to their rhythm?

Today we locate this clock in the brain--in the part we call the hypothalamus. It is there in two collections of gray matter, in the two subthalamic nuclei, that the biological clock and its most essential part-the circadian oscillator tick. It seems that the mechanism of a clock sets up the cycle of repeating reactions: the coding of genes and protein synthesis. These reactions arrange themselves into a feedback loop: genes, called "clock" genes code protein, which collect and thus put a stop to a reverse coding of genes. Together with the degradation (deterioration) of the protein the coding proceeds again and the protein producing cycle is resumed. This clock mechanism, characterized by rhythmicality, is common to all species-from a fruit fly to man. It is joined with the emission of circadian rhythms, dependent on changes in the cell membrane. Once they become active, they spread into the closest neighborhood, and also to other parts of the brain.

But of what use would a watch be if one could not set it to local time? The biological clock is hidden in the brain-directly over the intersection of the visual cortex. And the transformed light signals-using a shortcut-bring to it constant news of the world, just as the neurons creating its structure convey information to the brain from the interior of the organism. In our genetic clockwork, the rhythms of our inner and outer worlds coincide and harmonize with each other.

In some people the biological clock is in a hurry. At the threshold of the new millennium, in the state of Utah, a few families were found in which all members--from grandchildren to grandparents-wake up four hours earlier than anyone else. They get up, bright-eyed and bushy-tailed, while their neighbors continue to sleep much longer. It is as if their clock were set four hours ahead. In these early birds, there has been a change in a "single letter" - a nucleotide in one of their clock genes. And maybe the night owls carry in their clocks another delicate gene mutation? Medicine is already beginning to look for cures which will be able to intervene in the workings of the biological clock, to correct the annoying time changes such as those we experience after transoceanic flights in jets. Will the future produce a new group of doctor-clockmakers? In our country will the Minister of Health add one more medical specialization to the seventy-two already in existence? And will he call these specialists by the very scholarly name of "chronologists" to avoid confusion?

Of the many rhythms active in our organism the heartbeat is the closest to us perhaps because it has always been a telling indication of life-biological as well as emotional. Doesn’t a doctor listen to a patient’s beating heart just as attentively as a writer listens to his hero’s? And don’t both, doctor and writer, borrow these words to describe their condition by saying that the heart pounds, flutters or fades?
For the heart has played an enormous role as the center of psychic powers, even as far back as in the oldest living homogenous world civilization, the Egyptian. It enters poetry, religion, hieratic texts, and grows to the rank of the chief organ not just in the body but also as the main center of emotion and becomes almost the "essence of the human being" in a person. In period of the Old Kingdom, five thousand years ago, only the heart of a man would be tossed on the scale in the last judgment by Osiris. A pure heart had to weigh less than the lightest feather on the scales standing before him. Otherwise the heart was immediately devoured by the monster waiting alongside and the afterlife of the Egyptian ended in disgrace for all eternity.

As for the heart, it is not its harmony with its environment as much as the independence of its rhythm that is most intriguing. Let us recall a school biology lesson. A heart removed from a frog and placed on the table beats for a few long-lasting minutes. Everyday, in dozens of operating rooms in our country, surgeons stop ailing hearts by freezing the organism, proceed to do complicated operations, and then activate the heart once again with an electrical current when they are finished. Even more amazing is that fact that during transplant operations, the human heart--removed from the body of the donor, placed in a foreign system, and awakened by an electric shock to its wall that lasts barely a fraction of a second-starts up again and beats rhythmically. These examples indicate that within the heart there must be a mechanism capable of rousing the heart to rhythmic work.

This mechanism is made up of specialized cells, generating and transmitting impulses. They are not distributed randomly but join into a coordinated system. We call it the autonomous system of the heart or, more frequently, the command center. The first name emphasizes the autonomy, first and foremost, the unfailing, mechanical regularity of the system’s work; the second underscores its role in the distribution of impulses. Large concentrations of cells in the system meet in terminals, or stations, between which the impulses travel on their tracks of fibers. 

The command system, like an army at the front, has its hierarchy, ensuring the succession of leadership in the case that earlier leaders die. At the top of the hierarchical ladder stands the sinoatrial node, setting the pace, that is, it makes the first move. It emits impulses with the greatest frequency. It represses, therefore, all the other potential starters and defines the heartbeat. If the node is injured, the leadership role is taken up by the next, lower echelon centers, imposing rhythms with a lower and lower frequency. When they go silent, the heart activates its last emergency mechanism, concealed in the muscle, and begins to beat with the slowest rhythm, which maintains circulation of systems at rest, but does not allow any activity. Then we are dealing with a complete heart block, as the direct terminals and heretofore navigable pathways have been destroyed or blocked.

What are these signals with which we have come the entire way, from the first station to the last? We describe them as electrical phenomena. And we say that they occur when there are fissures in the cell walls, small canals by way of which some charged atoms enter and others leave. This phenomenon repeats itself rhythmically, eliciting differences in potential. Electrical discharges flow through well-known circuits to muscle tissue which constricts. But who, within the cell walls, with exact rhythmic precision, opens the gates through which the charged atoms jump? What kind of metronome beats out the first rhythm from which is born the heartbeat? This we do not know. And we slide over the surface of phenomena with this electrical current.

Does our heart beat with the mechanical precision of a metronome? Not everyone’s. The explanation is as follows. The birth of impulses in the cells of the sinoatrial node repeats itself with an ideal rhythm, to the beat of the most sensitive of metronomes. But before the impulse leaves the node--to travel over the pathways created for it and makes the heart contract-before this happens, it will experience the unbelievably subtle influence of the sympathetic nervous system. This is a delicate response, which we are incapable of detecting with a stethoscope. We may, however, notice it by analyzing the long transcription of the electrocardiogram. When we measure the pauses between consecutive heartbeats over a period of a few minutes, we can see, that in many of us there are discreet differences between them; the deviate from the average by just one hundredth of a second.

This brings to mind tempo rubato, a characteristic feature of Chopin’s music. There are many descriptions of a Chopin rubato. It is supposed to be a way of performing a work "with a subtle disquieting rhythm." Rubato, according to others, relies on "minute shifts between notes of the melodic voice in the field of its own beat, against a background of a steadily mounting bass. Francis Liszt described a Chopin rubato by comparing it to a tree, "whose crown leans in all directions in a wind while the roots stand firm in the earth."
Chopin used the term rubato to mean playing senzo rigore in the years 1824-1835 in his mazurkas as well as his nocturnes. He stopped using the term in 1836. Gastone Belotti considers the reasons for this to be obvious: from the instant of maturity all of his performances became rubato.
There are hearts in which rubato, that "subtle disquieting rhythm" is clearly registered as in the mature work of Chopin; there are others in which, as in Chopin’s early, youthful work, the rhythm is imperceptible. The former, afflicted by serious illness, rarely stop suddenly, as if the lack of stiffness, their flexibility, tendency to rhythmic freedom had better prepared them for the advent of sinister, morbid rhythms. Analyzing these discreet deviations from the ideal rhythm under the influence of heart rate variability is finding wider and wider application in the assessment of the risk of sudden heart attack among those who have already had an obstruction.

Doctors have always attached great important to measuring the pulse, and they became quite proficient at it. In the Third Century B.C., Herophilos of Alexandria determined the various stages of a pulse with the aid of a clock of his own construction; he carried it with him when visiting his patients. For centuries the waves of the pulse have been measured in all possible ways, in the belief, not without foundation, that this is the path to knowing the secrets of the heart’s workings and those of the entire organism. And not so long ago medical students had to describe, in one fell swoop, the basic characteristics of a pulse such as speed, filling, pressure, frequency and beat. The number of words used to try and capture these qualities must have seemed endless to them: twin pulse, thread pulse, anacrotic or, when all other adjectives failed, a weird pulse. Has all that knowledge been forgotten in the epoch of almighty technology? Not at all. The acclaimed Dorland’s Medical Dictionary, in the 2000 edition, advertised as a compendium of the most useful information for medical practitioners in the third millennium, describes... eighty-eight kinds of pulse!

Of course, measuring a pulse soon took second place to listening to a heart. The French doctor Rene Laennec invented auscultation one day when, wanting to avoid the inappropriate placement of his ear to the breast of a young female patient, he rolled a sheet of paper into a tube, tied it with a string, and placed it in the vicinity of her heart; he could not have imagined that his invention would open up an entire world of literally the closest sounds, a world unavailable to our ears up to that moment. Arrhythmias offer an excellent example. A single extra systole is like a slight misstep in a dance-one lilt, probably unnoticed, and in the next step we pick up the rhythm which carries us further along. The rhythm of the heart, punctuated by repeated premature contractions, makes us realize that syncopations were not a discovery originating with jazz musicians. In the irregularity of a complete pause between contractions, they change, the rhythmic accent shifts. The rhythm of a galloping horse resounds in a heart with an incapacitated left chamber; in English this is called a "gallop rhythm." The beating of a heart suffering a complete block is interrupted now and again by a loud "cannon blast" (the simultaneous contraction of atria and ventricles), followed by the quiet echo of contracting atria.

Echo: the name of a mountain nymph. Greek myths explained in various ways how she became the personification of an ethereal, returning voice. Having fallen in love with Narcissus, who did not return her affection, she fell into such deep despair that she began to disappear, until only her voice remained. Apparently it was also for her concealing of Zeus’s love affairs that Hera condemned Echo to repeat the last word of whatever was said to her. So it is not strange that languages new in the making were beginning to repeat her name. She came to inhabit them for good and became one of the most commonly used words in modern medicine. Echo, echolocation, echocardiogram... We penetrate the heart with voice waves and they bounce back and return to us like an echo from which we construct the image of the heart itself. This image is amazing for its accuracy of detail. The diagnostic apparatus is developing so quickly one might think it was trying to match in perfection the echolocation... of a bat.
And echocardiogram revealing the details of the anatomy of the heart or the contractibility of its muscle, allows us to understand the reason for the disruption of the rhythm. In an electrocardiogram we see it. Especially valuable is the portable electrocardiograph popularly known as the Holter monitor (named after an American doctor) which records the workings of the heart over a twenty-four hour period. In this memoir, written by the heart, every twitch is noted. And so is each, even the slightest, arrhythmia or lack of oxygen. This record is an invaluable aid in daily medical diagnoses. And even more advanced analytical tools are being developed for use in detecting delicate asynchronicities in the workings of the heart. Mathematicians and physicists are coming to the aid of doctors by applying non-linear systems dynamics and chaos theory to the examination of these exceptionally complicated phenomena.

How many conveniences there are today for medical students who want to divine the music of the heart! Over the bridge, where the ribs are attached, we place a membrane with an electronic amplifier. Out of it come six pairs of acoustic ducts, just like those in a regular stethoscope. Thus six people can receive the sound phenomena from the same place over the heart. On the screen of a portable computer runs a crooked electrocardiogram, and under it a phonocardiogram-a continuous record of tones, whispers, all the acoustical phenomena the heart emits. One can stop, "freeze" and analyze.

People have dreamed about being able to freeze sounds, words, even music for a very long time. Antiphones, a member of Plato’s household, tells about a country whose winters were so severe that words froze in the air. In the summer when the words melted, the residents would find out what had been said during the winter, just as Plato’s students would learn only in old age the meaning of the words uttered by their master in their youth. Many centuries later a certain Italian merchant (described by Baldassare Castiglione) set off in winter for the Ukraine to get himself a sable fur. He got stuck on the frozen bank of the Dnieper where he was conducting negotiations with Muscovite merchants bivouacking on the opposite bank. The words were not getting across, however; they froze en route and hung in the air like icicles. Then the Polish translators made a fire in the middle of river. The thawing words contained such high prices, however, that the Italian quickly returned, empty-handed, to his sunny homeland.
But who could surpass Baron von Munchhausen’s stories about winterlands! Rushing once in a sleigh over the icy wastelands of Russia, he told the postilion to play his horn the entire way back. The fact that not a single sound made it out of the horn should not surprise us. All got stuck in the horn, frozen. But that evening at the inn, music began to pour out of the horn hung by the fireplace and "to joyously melt the hearts so cruelly frozen."
In an operating room, when the doctor "freezes" a heart, lowering the temperature by a few degrees, he stops the music and rhythm because the heart stops. Mechanical pumps replace the heart and push the blood through the blood vessels. After the operation the warmed heart starts up its work, emits tones. The circulatory system begins to function once again driven by the rhythm of the heart.

When I was a new doctor and Wroclaw was hit with the iciest winters of the century, a completely frozen man was carried into the hospital at three in the morning. He was found on the banks of the Oder, where the temperature read minus thirty-five degrees Centigrade. He was as stiff and cold as an icicle, he wasn’t breathing, and his heart had stopped beating. The EKG registered a straight horizontal line. People were just beginning to talk about resuscitation; we had no equipment. I was there with a nurse. I began to massage his heart, and she gave him mouth to mouth. Every breath he released filled the room with alcoholic fumes. His heartbeat returned after about an hour of massaging his heart, his breath after two. The next day the dead man walked out on his own two feet, having upbraided us earlier for losing his pack of extra strong cigarettes."

Concerned, we sent an account of what happened to Lancet even though we could not answer the editor’s question: what was the body temperature of the resuscitated man. Over twenty-five years later the same paper printed the story of an accident involving a world-class Norwegian skier in the far North. She had fallen into a deep ice pit from which she was extracted two hours later, showing no signs of life and with a body temperature measuring 13.7 degrees Centigrade. She was transported by rescue airplane to Tromso. Her heart began to function only after a few hours of pumping her blood through the heaters of an extrasystemic circulatory system. She left the hospital after five months of rehabilitation. Such incidents have lead people working in wards of intensive therapy with patients resuscitated on the streets and brought in, to use mattresses that cool the body at least a few degrees. They do this in the hope that they can stall the moment of irreversible damage to the brain and thus enable the pulse and heartbeat to return more quickly.

You would not be able to take the pulse or to measure the blood pressure of thousands of Americans who nonetheless move around quite freely. They have, sewn into their hearts, small pumps aiding blood flow from the left ventricle to the aorta in a constant, non-pulsating way. In the world there are also a few patients whose hearts have been removed and replaced with a completely artificial heart the size of a grapefruit-all titanium and plastic-"the latest in the most advanced technology that a human being has ever carried within." Also popular are electric fibrillators, and the choice of antiarrhythmic prescriptions is exceptionally wide and still growing. Yet there are times when the strongest medicines will not work but a good word does.

Years ago Jerzy Turowicz, the editor in chief of the Polish weekly Tygodnik Powszechny, came to our clinic because he had a terrible infection. We were able to bring the infection under control, but the arrhythmia remained. His heart beat with a bad, menacing rhythm, one of those which do not retreat by themselves and augur the worst danger. We prescribed strong medicines-without result. We had reached the limits of what we could do. One evening I visited Jerzy in a private room, listened to his heart and returned home depressed by my own sense of powerlessness. When early the next morning I put the stethoscope to his chest, I heard a pure, measured, correct heartbeat. I did not believe my ears, but the EKG confirmed my reading. Astonished, I asked, "Jerzy, did something happen last night?" He replied with his gentle, kind smile: "You know, the Pope called me, after midnight, from the Vatican."

The mystery of circulation in the human body was discovered almost two hundred years after the discovery that the earth and the planets revolve around the sun. Our inability to see a phenomenon so important and relevant to each of us must seem incomprehensible, especially since the combination of experiments necessary to determine this truth could have been conceived and performed without any impediments in the course of the previous millennia. William Harvey, the man who discovered the circulatory system, was an experienced anatomy-pathologist and a scholar with an insatiable curiosity. Before he got interested in man, he completed the dissection of around two hundred various animals, including an ostrich, which at the beginning of the seventeenth century in London was not the easiest task. Next, by using simple cuts and bandaging the human hand, he arrived at the conclusion that blood leaves the heart through the arteries and flows back through the veins.
Comparing the orbiting of the planets around the sun to the circulation of blood in the human body directs one’s thought to music. Pythagoras claimed that the rhythmic movement of the planets was the source of music. The music of the heavenly spheres, the expression of perfect harmony, always resounds even though we may never hear it. Similarly, we do not hear the rhythmic surging of the blood because it is with us from birth. It reaches us only in rare moments, when the harmony of the organism is seriously disturbed, when it feels bad-in illness.

My cherished Oxford Companion to Music defines rhythm as the face of music, turned in the direction of time. How could one relate this to the heart?
Blood surges into billions of our cells like an ocean wave licking the sandy shore, rubbing up against it and then going back out, only to return after an interval of time. Our great internal organs and the cells which make them are endlessly rocked by waves of incoming and outgoing tides. They feel, they hear the rush and rhythm of blood which "binds the distant shores together with a thread of understanding" and tells them about the passage of time.

AFTER THE GENOME