The river of consciousness

Oliver Sacks, 1933-2015

Book - 2017

"Two weeks before his death, Oliver Sacks outlined the contents of The River of Consciousness, the last book he would oversee. The best-selling author of On the Move, Musicophilia, and The Man Who Mistook His Wife for a Hat, Sacks is known for his illuminating case histories about people living with neurological conditions at the far borderlands of human experience. But his grasp of science was not restricted to neuroscience or medicine; he was fascinated by the issues, ideas, and questions of all the sciences. That wide-ranging expertise and passion informs the perspective of this book, in which he interrogates the nature not only of human experience but of all life. In The River of Consciousness, Dr. Sacks takes on evolution, botany,... chemistry, medicine, neuroscience, and the arts, and calls upon his great scientific and creative heroes--above all, Darwin, Freud, and William James. For Sacks, these thinkers were constant companions from an early age; the questions they explored--the meaning of evolution, the roots of creativity, and the nature of consciousness--lie at the heart of science and of this book. The River of Consciousness demonstrates Sacks's unparalleled ability to make unexpected connections, his sheer joy in knowledge, and his unceasing, timeless endeavor to understand what makes us human."--Dust jacket flap.

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Subjects
Published
New York : Alfred A. Knopf 2017.
Language
English
Main Author
Oliver Sacks, 1933-2015 (author)
Item Description
"A Borzoi book."
Physical Description
x, 237 pages ; 22 cm
Bibliography
Includes bibliographical references (pages 219-228) and index.
ISBN
9780385352567
  • Darwin and the meaning of flowers
  • Speed
  • Sentience : the mental lives of plants and worms
  • The other road : Freud as neurologist
  • The fallibility of memory
  • Mishearings
  • The creative self
  • A general feeling of disorder
  • The river of consciousness
  • Scotoma : forgetting and neglect in science.
Review by Choice Review

Sacks outlined the contents for this compelling collection of essays two weeks prior to his death in 2015. Three colleagues were entrusted to see the book through publication. (Most of the essays had previously, though obscurely, been published.) In typical Sacks style, the topics covered reflect the author's vast range of knowledge and his natural gift for storytelling. Topics include Darwin's work with plants; speed, movement, and time; a glimpse of Freud as a neurologist; memory and its errors; the nature of mishearings; and reflections on both evolution and consciousness. The essays are all enlightening, entertaining, and a pleasure to read and are of value to scholars and lay readers alike. The author's love of learning is evident in each well-crafted piece. Sacks's reputation as a neurologist and an accomplished writer is well known, and this volume is an excellent addition to his other works--most recently, On the Move (CH, Dec'15, 53-1809) and Hallucinations (CH, Apr'13, 50-4720). Summing Up: Highly recommended. All readers. --Jan Bailey, Caldwell Community College and Technical Institute

Copyright American Library Association, used with permission.
Review by New York Times Review

BUNK: The Rise of Hoaxes, Humbug, Plagiarists, Phonies, Post-Facts, and Fake News, by Kevin Young. (Graywolf, $30.) Young's enthralling, essential history is unapologetically subjective - and timely. Again and again, he plumbs the undercurrents of a hoax to discover fearfulness and racism lurking inside. A BOLD AND DANGEROUS FAMILY: The Remarkable Story of an Italian Mother, Her Two Sons, and Their Fight Against Fascism, by Caroline Moorehead. (Harper/HarperCollins, $27.99.) This portrait of a renowned family of Italian anti-fascists, the Rossellis of Florence, depicts the ethical imperative and repercussions of dissent. The book revolves around two brothers whose resistance efforts ended only when they were murdered in 1937, in France. THE RIVER OF CONSCIOUSNESS, by Oliver Sacks. (Knopf, $27.) In this last, posthumous collection of essays, Sacks brilliantly delves into his favorite themes: the evolution of life, the workings of memory and the nature of creativity. THE ODYSSEY, by Homer. Translated by Emily Wilson. (Norton, $39.95.) This landmark translation matches the original's line count while drawing on a spare, simple and direct idiom that strips away formulaic language to let the characters take center stage. ENDURANCE: A Year in Space, a Lifetime of Discovery, by Scott Kelly. (Knopf, $29.95.) In this charming if occasionally convoluted memoir, Kelly details the endless dedication that led to his groundbreaking 12 months in space. He pulls back the curtain separating the myth of the astronaut from its human realities. RAMP HOLLOW: The Ordeal of Appalachia, by Steven Stoll. (Hill & Wang, $30.) Stoll's thesis is built around the concept of dispossession among the people of Appalachia. While the book is meticulously researched, it is also light and readable. Its great strength is that it acknowledges something our politics often fails to: that not everyone wants the same things. THE SECOND COMING OF THE KKK: The Ku Klux Klan of the 1920s and the American Political Tradition, by Linda Gordon. (Liveright, $27.95.) In an enlightening study troubling for its contemporary relevance, Gordon says "the K.K.K. may actually have enunciated values with which a majority of 1920s Americans agreed." FREYA, by Anthony Quinn. (Europa, paper, $19.) The journalist heroine of Quinn's novel is both headstrong and ambitious. Neither will be assets in post-World War II Britain. THE RELIVE BOX: And Other Stories, by T. Coraghessan Boyle. (Ecco/HarperCollins, $25.99.) Set in a close alternate reality, Boyle's skewed stories feel as if they're coming from the end of the world, from a time when we will finally be unable to live with what we are and what we have and what we have done. The full reviews of these and other recent books are on the web: nytimes.com/books

Copyright (c) The New York Times Company [July 29, 2018]
Review by Booklist Review

Revered neurologist Sacks specified the contents of this collection shortly before his death, and he seems to have named it thematically (though it includes an essay with the same title). This is a book about acting purposefully toward an end, a primary function of evolution and of consciousness. It opens with an appreciation of Darwin's botanical works, which, though sans theory, illustrate purposiveness continually. Other essays' titles seem more on-topic but teem with surprises; the one entitled Sentience is more particularly named by its brow-raising subtitle, The Mental Lives of Plants and Worms. Freud, explorer of the subconscious, seems a natural enough subject; the surprise this time is that Sacks appraises the Viennese clinician's purely neurological work. Such revealing of lesser-known aspects of a subject is Sacks' great didactic and aesthetic strength. He engages and deepens our attention through the historic and personal particulars with which he argues his points about what, say, memory, or forgetting, or creativity, or A General Feeling of Disorder, involves organismically. So doing, he has made permanent contributions to literature.--Olson, Ray Copyright 2017 Booklist

From Booklist, Copyright (c) American Library Association. Used with permission.
Review by Publisher's Weekly Review

Acclaimed neurologist Sacks (1933-2015) demonstrates the range of his knowledge of evolution, botany, chemistry, medicine, neuroscience, and the arts in this collection of 10 essays he was working on before his death in 2015. The book is a tribute to his appreciation of all that's beautifully complex in humans. In "Darwin and the Meaning of Flowers," Sacks examines Darwin's late-career studies of plants and worms, writing of Darwin's belief that natural beauty "always reflected function and adaptation at work." In "Speed," he lauds William James for his exploration of the perception of time and how it was altered "by the effects of certain drugs." Sacks also lends his own perspective on the perception of time, gleaned from working with patients with "disorders of neural speed," which he documented in 1973's Awakenings. One of the most moving pieces, "The Fallibility of Memory," argues that humans are "landed with memories which have fallibilities, frailties, and imperfections-but also great flexibility and creativity." Sacks pays homage to Freud in "Mishearings," asserting that Freudian slips are more than expressions of repressed feelings: "They reflect, to some extent, one's own interests and experiences." Sacks also writes about his own cancer in "A General Feeling of Disorder" and how a respite from sickness filled him with gratitude. Readers will feel a similar sense of gratitude for the extraordinary work that Sacks left behind. (Nov.) © Copyright PWxyz, LLC. All rights reserved.

(c) Copyright PWxyz, LLC. All rights reserved
Review by Library Journal Review

One of two titles neurologist Sacks (The Man Who Mistook His Wife for a Hat; Hallucinations) was working on when he died in 2015, this volume is a collection of essays, some of which were published previously in The New York Review of Books. Sacks begins with Charles Darwin and continues with pieces on Sigmund Freud, memory, creativity, illness, and consciousness. He alludes to writers who greatly influenced him, such as William James; adds digressive but informative footnotes; and refers to his own books when they provide fuller explorations of a topic. The author's unconventional points of view are potentially the most informative part of the work. He examines well-known ideas from lesser-known angles-for instance, that Darwin was also a botanist and supported his theory with botanical experimentation. Throughout, Sacks displays his marvelous skill with words, rich knowledge of medicine and science and their histories, observational skills, curiosity, and humor, and it's impossible not to feel the loss of this amazing thinker. VERDICT This title gives readers plenty to think about, such as the nature of consciousness and the cultural limitations of science. Every reader should be able to find something to enjoy and appreciate here. [See Prepub Alert, 4/10/17.]-Nancy H. Fontaine, Norwich P.L., VT © Copyright 2017. Library Journals LLC, a wholly owned subsidiary of Media Source, Inc. No redistribution permitted.

(c) Copyright Library Journals LLC, a wholly owned subsidiary of Media Source, Inc. No redistribution permitted.
Review by Kirkus Book Review

Fans of the late neurologist have another chance to enjoy this erudite, compassionate storyteller, essayist, and memoirist in what may be his final work.This collection of 10 essays, some of which appeared previously in the New York Review of Books, was assembled by three colleagues from an outline provided by Sacks (Gratitude, 2015, etc.) two weeks before his death in 2015. Here, the author explores evolution, time, memory and forgetting, experience, creativity, and consciousness. As his colleagues note, Sacks "interrogates the nature not only of human experience but of all life (including botanical life)." Readers will see how Darwin's botanical work provided the strongest evidence for evolution and natural selection, the different ways in which time is perceived and experienced, and the fallibility of memory (explored in a fascinating piece on cryptomnesia, or unconscious plagiarism). The essay on misheard words, a real problem for the aging Sacks, is the shortest entry and also the funniest. The most speculative is "Scotoma," a neurological term for a disconnect in perception, which Sacks uses to refer to the neglect or oversight of an idea proposed or a discovery made before its time. This gives the author the chance to explore how the history of science might have been different. The longest, densest, and most technically demanding is the title essay, "The River of Consciousness," in which Sacks examines what neuroscientists have begun to learn about the neural basis of consciousness, from relatively simple mechanisms such as perception to more complex issues such as memory, imagery, and reflection. Interestingly, the collection can be seen as a subtle reminder of this polymath's previous works, for references to a number of these appear throughout the text and in footnotes. A collection of dissimilar pieces that reveal the scope of the author's interestssometimes challenging, always rewarding. Copyright Kirkus Reviews, used with permission.

Copyright (c) Kirkus Reviews, used with permission.

9780385352567|excerpt Sacks / RIVER OF CONSCIOUSNESS Darwin and the Meaning of Flowers We all know the canonical story of Charles Darwin: the twenty-­two-­year-­old embarking on the Beagle, going to the ends of the earth; Darwin in Patagonia; Darwin on the Argentine pampas (managing to lasso the legs of his own horse); Darwin in South America, collecting the bones of giant extinct animals; Darwin in Australia--­still a religious believer--­startled at his first sight of a kangaroo ("surely two distinct Creators must have been at work"). And, of course, Darwin in the Galápagos, observing how the finches were different on each island, starting to experience the seismic shift in understanding how living things evolve that, a quarter of a century later, would result in the publication of On the Origin of Species. The story climaxes here, with the publication of the Origin in November 1859, and has a sort of elegiac postscript: a vision of the older and ailing Darwin, in the twenty-­odd years remaining to him, pottering around his gardens at Down House with no particular plan or purpose, perhaps throwing off a book or two, but with his major work long completed. Nothing could be further from the truth. Darwin remained intensely sensitive both to criticisms and to evidence supporting his theory of natural selection, and this led him to bring out no fewer than five editions of the Origin. He might indeed have retreated (or returned) to his garden and his greenhouses after 1859 (there were extensive grounds around Down House, and five greenhouses), but for him these became engines of war, from which he would lob great missiles of evidence at the skeptics outside--­descriptions of extraordinary structures and behaviors in plants very difficult to ascribe to special creation or design--­a mass of evidence for evolution and natural selection even more overwhelming than that presented in the Origin. Strangely, even Darwin scholars pay relatively little attention to this botanical work, even though it encompassed six books and seventy-­odd papers. Thus Duane Isely, in his 1994 book, One Hundred and One Botanists, writes that while more has been written about Darwin than any other biologist who ever lived . . . [he] is rarely presented as a botanist. . . . The fact that he wrote several books about his research on plants is mentioned in much Darwinia, but it is casual, somewhat in the light of "Well, the great man needs to play now and then." Darwin had always had a special, tender feeling for plants and a special admiration, too. ("It has always pleased me to exalt plants in the scale of organised beings," he wrote in his autobiography.) He grew up in a botanical family--­his grandfather Erasmus Darwin had written a long, two-­volume poem called The Botanic Garden, and Charles himself grew up in a house whose extensive gardens were filled not only with flowers but with a variety of apple trees crossbred for increased vigor. As a university student at Cambridge, the only lectures Darwin consistently attended were those of the botanist J. S. Henslow, and it was Henslow, recognizing the extraordinary qualities of his student, who recommended him for a position on the Beagle. It was to Henslow that Darwin wrote very detailed letters full of observations about the fauna and flora and geology of the places he visited. (These letters, when printed and circulated, were to make Darwin famous in scientific circles even before the Beagle returned to England.) And it was for Henslow that Darwin, in the Galápagos, made a careful collection of all the plants in flower and noted how different islands in the archipelago could often have different species of the same genus. This was to become a crucial piece of evidence for him as he thought about the role of geographical divergence in the origin of new species. Indeed, as David Kohn pointed out in a splendid 2008 essay, Darwin's Galápagos plant specimens, numbering well over two hundred, constituted "the single most influential natural history collection of live organisms in the entire history of science. . . . They also would turn out to be Darwin's best documented example of the evolution of species on the islands." (The birds Darwin collected, by contrast, were not always correctly identified or labeled with their island of origin, and it was only on his return to England that these, supplemented by the specimens collected by his shipmates, were sorted out by the ornithologist John Gould.) Darwin became close friends with two botanists, Joseph Dalton Hooker at Kew Gardens and Asa Gray at Harvard. Hooker had become his confidant in the 1840s--­the only man to whom he showed the first draft of his work on evolution--­and Asa Gray was to join the inner circle in the 1850s. Darwin would write to them both with increasing enthusiasm about "our theory." Yet though Darwin was happy to call himself a geologist (he wrote three geological books based on his observations during the voyage of the Beagle and conceived a strikingly original theory on the origin of coral atolls, which was confirmed experimentally only in the second half of the twentieth century), he always insisted that he was not a botanist. One reason was that botany had (despite a precocious start in the early eighteenth century with Stephen Hales's Vegetable Staticks, a book full of fascinating experiments on plant physiology) remained almost entirely a descriptive and taxonomic discipline: plants were identified, classified, and named but not investigated. Darwin, by contrast, was preeminently an investigator, concerned with the "how" and "why" of plant structure and behavior, not just the "what." Botany was not a mere avocation or hobby for Darwin, as it was for so many in the Victorian age; the study of plants was always infused for him with theoretical purpose, and the theoretical purpose had to do with evolution and natural selection. It was, as his son Francis wrote, "as though he were charged with theorising power ready to flow into any channel on the slightest disturbance, so that no fact, however small, could avoid releasing a stream of theory." And the flow went both ways; Darwin himself often said that "no one could be a good observer unless he was an active theoriser." In the eighteenth century, the Swedish scientist Carl Linnaeus had shown that flowers had sexual organs (pistils and stamens), and indeed had based his classifications on these. But it was almost universally believed that flowers were self-­fertilized--­why else would each flower contain both male and female organs? Linnaeus himself made merry with the idea, portraying a flower with nine stamens and one pistil as a bedchamber in which a maiden was surrounded by nine lovers. A similar conceit appeared in the second volume of Darwin's grandfather's book The Botanic Garden, titled The Loves of the Plants. This was the atmosphere in which the younger Darwin grew up. But within a year or two of his return from the Beagle, Darwin felt forced, on theoretical grounds, to question the idea of self-­fertilization. In an 1837 notebook, he wrote, "Do not plants which have male and female organs together yet receive influence from other plants?" If plants were ever to evolve, he reasoned, cross-­fertilization was crucial--­otherwise, no modifications could ever occur, and the world would be stuck with a single, self-­reproducing plant instead of the extraordinary range of species it actually had. In the early 1840s, Darwin started to test his theory, dissecting a variety of flowers (azaleas and rhododendrons among them) and demonstrating that many of these had structural devices for preventing or minimizing self-­pollination. But it was only after On the Origin of Species was published in 1859 that Darwin could turn his full attention to plants. And where his early work was primarily as an observer and a collector, experiments now became his chief way of obtaining new knowledge. He had observed, as others had, that primrose flowers came in two different forms: a "pin" form with a long style--­the female part of the flower--­and a "thrum" form with a short style. These differences were thought to have no particular significance. But Darwin suspected otherwise, and examining bunches of primroses that his children brought him, he found that the ratio of pins to thrums was exactly one to one. Darwin's imagination was instantly aroused: a one-­to-­one ratio was what one might expect of species with separate males and females--­could it be that the long-­styled flowers, though hermaphrodites, were in the process of becoming female flowers and the short-­styled ones male flowers? Was he actually seeing intermediate forms, evolution in action? It was a lovely idea, but it did not hold up, for the short-­styled flowers, the putative males, produced as much seed as the long-­styled, "female" ones. Here (as his friend T. H. Huxley would have put it) was "the slaying of a beautiful hypothesis by an ugly fact." What, then, was the meaning of these different styles and their one-­to-­one ratio? Giving up theorizing, Darwin turned to experiment. Painstakingly, he tried acting as a pollinator himself, lying facedown on the lawn and transferring pollen from flower to flower: long-­styled to long-­styled, short-­styled to short-­styled, long-­styled to short-­styled, and vice versa. When seeds were produced, he collected and weighed them and found that the richest crop of seeds came from the crossbred flowers. He concluded that heterostyly, in which plants have styles of different length, was a special device that had evolved to facilitate outbreeding and that crossing increased the number and vitality of seeds (he called this "hybrid vigour"). Darwin later wrote, "I do not think anything in my scientific life has given me so much satisfaction as making out the meaning of the structure of these plants." Although this subject remained a special interest of Darwin's (he published a book on it in 1877, The Different Forms of Flowers on Plants of the Same Species), his central concern was how flowering plants adapted themselves to using insects as agents for their own fertilization. It was well known that insects were attracted to certain flowers, visited them, and could emerge from blossoms covered with pollen. But no one had thought this was of much importance, since it was assumed that flowers were self-­pollinated. Darwin had already become suspicious of this by 1840, and in the 1850s he set five of his children to work plotting the flight routes of male humble bees. He especially admired the native orchids that grew in the meadows around Down, so he started with those. Then, with the help of friends and correspondents who sent him orchids to study, and especially Hooker, who was now director of Kew Gardens, he extended his studies to tropical orchids of all kinds. The orchid work moved quickly and well, and in 1862 Darwin was able to send his manuscript to the printers. The book had a typically long and explicit Victorian title, On the Various Contrivances by Which British and Foreign Orchids Are Fertilised by Insects. His intentions, or hopes, were made clear in its opening pages: In my volume "On the Origin of Species" I gave only general reasons for the belief that it is an almost universal law of nature that the higher organic beings require an occasional cross with another individual. . . . I wish here to show that I have not spoken without having gone into details. . . . This treatise affords me also an opportunity of attempting to show that the study of organic beings may be as interesting to an observer who is fully convinced that the structure of each is due to secondary laws, as to one who views every trifling detail of structure as the result of the direct interposition of the Creator. Here, in no uncertain terms, Darwin is throwing down the gauntlet, saying, "Explain that better--­if you can." Darwin interrogated orchids, interrogated flowers, as no one had ever done before, and in his orchid book he provided enormous detail, far more than is to be found in the Origin. This was not because he was pedantic or obsessional but because he felt that every detail was potentially significant. It is sometimes said that God is in the details, but for Darwin it was not God but natural selection, acting over millions of years, which shone out from the details, details that were unintelligible, senseless, except in the light of history and evolution. His botanical researches, his son Francis wrote, supplied an argument against those critics who have so freely dogmatised as to the uselessness of particular structures, and as to the consequent impossibility of their having been developed by means of natural selection. His observations on Orchids enabled him to say: "I can show the meaning of some of the apparently meaningless ridges and horns; who will now venture to say that this or that structure is useless?" In a 1793 book titled The Secret of Nature in the Form and Fertilization of Flowers Discovered, the German botanist Christian Konrad Sprengel, a most careful observer, had noted that bees laden with pollen would carry it from one flower to another. Darwin always called this a "wonderful" book. But Sprengel, though he drew close, missed the final secret, because he was still wedded to the Linnaean idea of flowers as self-­fertilizing and thought of flowers of the same species as essentially identical. It was here that Darwin made a radical break and cracked the secret of flowers, by showing that their special features--­the various patterns, colors, shapes, nectars, and scents by which they lured insects to flit from one plant to another, and the devices which ensured that the insects would pick up pollen before they left the flower--­were all "contrivances," as he put it; they had all evolved in the service of cross-­fertilization. What had once been a pretty picture of insects buzzing about brightly colored flowers now became an essential drama in life, full of biological depth and meaning. The colors and smells of flowers were adapted to insects' senses. While bees are attracted to blue and yellow flowers, they ignore red ones, because they are red-­blind. On the other hand, their ability to see beyond the violet is exploited by flowers which use ultraviolet markings--­the honey guides that direct bees to their nectaries. Butterflies, with good red vision, fertilize red flowers but may ignore the blue and violet ones. Flowers pollinated by night-­flying moths tend to lack color but to exude their scents at night. And flowers pollinated by flies, which live on decaying matter, may mimic the (to us) foul smells of putrid flesh. It was not just the evolution of plants but the coevolution of plants and insects that Darwin illuminated for the first time. Thus natural selection would ensure that the mouth parts of insects matched the structure of their preferred flowers--­and Darwin took special delight in making predictions here. Examining one Madagascan orchid with a nectary nearly a foot long, he predicted that a moth would be found with a proboscis long enough to probe its depths; decades after his death, such a moth was finally discovered. The Origin was a frontal assault (delicately presented though it was) on creationism, and while Darwin had been careful to say little in the book about human evolution, the implications of his theory were perfectly clear. It was especially the idea that man could be regarded as a mere animal--­an ape--­descended from other animals that had provoked outrage and ridicule. But for most people, plants were a different matter--­they neither moved nor felt; they inhabited a kingdom of their own, separated from the animal kingdom by a great gulf. The evolution of plants, Darwin sensed, might seem less relevant, or less threatening, than the evolution of animals, and so more accessible to calm and rational consideration. Indeed, he wrote to Asa Gray, "no one else has perceived that my chief interest in my orchid book, has been that it was a 'flank movement' on the enemy." Darwin was never belligerent, like his "bulldog" Huxley, but he knew that there was a battle to wage, and he was not averse to military metaphors. It is, however, not militancy or polemic that shines out of the orchid book; it is sheer joy, delight in what he was seeing. This delight and exuberance burst out of his letters: You cannot conceive how the Orchids have delighted me. . . . What wonderful structures! . . . The beauty of the adaptation of parts seems to me unparalleled. . . . I was almost mad at the wealth of Orchids. . . . One splendid flower of Catasetum, the most wonderful Orchid I have seen. . . . Happy man, he [who] has actually seen crowds of bees flying round Catasetum, with the pollinia sticking to their backs! . . . I never was more interested in any subject in all my life than in this of Orchids. The fertilization of flowers engaged Darwin to the end of his life, and the orchid book was followed, nearly fifteen years later, by a more general book, The Effects of Cross and Self Fertilisation in the Vegetable Kingdom. But plants also have to survive, flourish, and find (or create) niches in the world, if they are ever to reach the point of reproduction. Darwin was equally interested in the devices and adaptations by which plants survived and in their varied and sometimes astonishing lifestyles, which included sense organs and motor powers akin to those of animals. In 1860, during a summer holiday, Darwin first encountered and became enamored of insect-­eating plants, and this started a series of investigations that culminated fifteen years later in the publication of Insectivorous Plants. This volume has an easy, companionable style and starts, like most of his books, with a personal recollection: I was surprised by finding how large a number of insects were caught by the leaves of the common sun-­dew (Drosera rotundifolia) on a heath in Sussex. . . . On one plant all six leaves had caught their prey. . . . Many plants cause the death of insects . . . without thereby receiving, as far as we can perceive, any advantage; but it was soon evident that Drosera was excellently adapted for the special purpose of catching insects. The idea of adaptation was always in Darwin's mind, and one look at the sundew showed him that these were adaptations of an entirely novel kind, for Drosera's leaves not only had a sticky surface but were covered with delicate filaments (Darwin called them "tentacles") with glands at their tips. What were these for? he wondered. "If a small organic or inorganic object be placed on the glands in the centre of a leaf," he observed, they transmit a motor impulse to the marginal tentacles. . . . The nearer ones are first affected and slowly bend towards the centre, and then those farther off, until at last all become closely inflected over the object. But if the object was not nourishing, it was speedily released. Darwin went on to demonstrate this by putting blobs of egg white on some leaves and similar blobs of inorganic matter on others. The inorganic matter was quickly released, but the egg white was retained and stimulated the formation of a ferment and an acid that soon digested and absorbed it. It was similar with insects, especially live ones. Here, without a mouth, or a gut, or nerves, Drosera efficiently captured its prey and absorbed it, using special digestive enzymes. Darwin addressed not only how Drosera functioned but why it had adopted so extraordinary a lifestyle: he observed that the plant grew in bogs, in acidic soil that was relatively barren of organic material and assimilable nitrogen. Few plants could survive in such conditions, but Drosera had found a way to claim this niche by absorbing its nitrogen directly from insects rather than from the soil. Amazed by the animal-­like coordination of Drosera's tentacles, which closed on its prey like those of a sea anemone, and by the plant's animal-­like ability to digest, Darwin wrote to Asa Gray, "You are unjust on the merits of my beloved Drosera; it is a wonderful plant, or rather a most sagacious animal. I will stick up for Drosera to the day of my death." And he became still more enthusiastic about Drosera when he found that making a small nick in half of a leaf would paralyze just that half, as if a nerve had been cut. The appearance of such a leaf, he wrote, resembled "a man with his backbone broken and lower extremities paralysed." Darwin later received specimens of the Venus flytrap--­a member of the sundew family--­which, the moment its trigger-­like hairs were touched, would clap its leaves together on an insect and imprison it. The flytrap's reactions were so fast that Darwin wondered whether electricity could be involved, something analogous to a nerve impulse. He discussed this with his physiologist colleague Burdon Sanderson and was delighted when Sanderson was able to show that electric current was indeed generated by the leaves and could also stimulate them to close. "When the leaves are irritated," Darwin recounted in Insectivorous Plants, "the current is disturbed in the same manner as takes place during the contraction of the muscle of an animal." Plants are often regarded as insensate and immobile--­but the insect-­eating plants provided a spectacular rebuttal of this notion, and now, eager to examine other aspects of plant motion, Darwin turned to an exploration of climbing plants. (This would culminate in the publication of On the Movements and Habits of Climbing Plants.) Climbing was an efficient adaptation, allowing plants to disburden themselves of rigid supporting tissue by using other plants to support and elevate them. And there was not just one way of climbing but many. There were twining plants, leaf-­climbers, and plants that climbed with the use of tendrils. These especially fascinated Darwin--­it was almost, he felt, as if they had "eyes" and could "survey" their surroundings for suitable supports. "I believe, Sir, the tendrils can see," he wrote to Asa Gray. How did such complex adaptations arise? Darwin saw twining plants as ancestral to other climbing plants, and he thought that tendril-­bearing plants had evolved from these, and leaf-­climbers, in turn, from tendril-­bearers, each development opening up more and more possible niches--­roles for the organism in its environment. Thus climbing plants had evolved over time--­they had not all been created in an instant, by divine fiat. But how did twining itself start? Darwin had observed twisting movements in the stems, leaves, and roots of every plant he had examined, and such twisting movements (which he called circumnutation) could also be observed in the earliest evolved plants: cycads, ferns, seaweeds, too. When plants grow towards the light, they do not just thrust upwards; they twist, they corkscrew, towards the light. Circumnutation, Darwin came to think, was a universal disposition of plants and the antecedent of all other twisting movements in plants. These thoughts, along with dozens of beautiful experiments, were set out in his last botanical book, The Power of Movement in Plants, published in 1880. Among the many charming and ingenious experiments he recounted was one in which he planted oat seedlings, shone light on them from different directions, and found that they always bent or twisted towards the light, even when it was too dim to be seen by human eyes. Was there (as he imagined of the tips of tendrils) a photosensitive region, a sort of "eye" at the tips of the seedling leaves? He devised little caps, darkened with India ink, to cover these and found that they no longer responded to light. It was clear, he concluded, that when light fell on the leaf tip, it stimulated the tip to release some sort of messenger which, reaching the "motor" parts of the seedling, caused it to twist towards the light. Similarly, the primary roots (or radicles) of seedlings, which have to negotiate all sorts of obstacles, Darwin found to be extremely sensitive to contact, gravity, pressure, moisture, chemical gradients, etc. He wrote, There is no structure in plants more wonderful, as far as its functions are concerned, than the tip of the radicle. . . . It is hardly an exaggeration to say that the tip of the radicle . . . acts like the brain of one of the lower animals . . . receiving impressions from the sense-­organs, and directing the several movements. But as Janet Browne remarks in her biography of Darwin, The Power of Movement in Plants was "an unexpectedly controversial book." Darwin's idea of circumnutation was roundly criticized. He had always acknowledged it as a speculative leap, but a more cutting criticism came from the German botanist Julius Sachs, who, in Browne's words, "sneered at Darwin's suggestion that the tip of the root might be compared to the brain of a simple organism and declared that Darwin's home-­based experimental techniques were laughably defective." However homely Darwin's techniques, though, his observations were precise and correct. His ideas of a chemical messenger being transmitted downwards from the sensitive tip of the seedling to its "motor" tissue were to lead the way, fifty years later, to the discovery of plant hormones like auxins, which, in plants, play many of the roles that nervous systems do in animals. Darwin had been an invalid for forty years, with an enigmatic illness that had assailed him since his return from the Galápagos. He would sometimes spend entire days vomiting or confined to his sofa, and as he grew older, he developed heart problems, too. But his intellectual energy and creativity never wavered. He wrote ten books after the Origin, many of which went through major revisions themselves--­to say nothing of dozens of articles and innumerable letters. He continued to pursue his varied interests throughout his life. In 1877 he published a second edition, greatly enlarged and revised, of his orchid book (originally published fifteen years earlier). My friend Eric Korn, an antiquarian and Darwin specialist, told me that he once had a copy of this in which there was slipped the counterfoil of an 1882 postal order for two shillings and nine pence, signed by Darwin himself, in payment for a new orchid specimen. Darwin was to die in April of that year, but he was still in love with orchids and collecting them for study within weeks of his death. Natural beauty, for Darwin, was not just aesthetic; it always reflected function and adaptation at work. Orchids were not just ornamental, to be displayed in a garden or a bouquet; they were wonderful contrivances, examples of nature's imagination, natural selection, at work. Flowers required no Creator, but were wholly intelligible as products of accident and selection, of tiny incremental changes extending over hundreds of millions of years. This, for Darwin, was the meaning of flowers, the meaning of all adaptations, plant and animal, the meaning of natural selection. It is often felt that Darwin, more than anyone, banished "meaning" from the world--­in the sense of any overall divine meaning or purpose. There is indeed no design, no plan, no blueprint in Darwin's world; natural selection has no direction or aim, nor any goal to which it strives. Darwinism, it is often said, spelled the end of teleological thinking. And yet, his son Francis writes, one of the greatest services rendered by my father to the study of Natural History is the revival of Teleology. The evolutionist studies the purpose or meaning of organs with the zeal of the older Teleologist, but with far wider and more coherent purpose. He has the invigorating knowledge that he is gaining not isolated conceptions of the economy of the present, but a coherent view of both past and present. And even where he fails to discover the use of any part, he may, by a knowledge of its structure, unravel the history of the past vicissitudes in the life of the species. In this way a vigour and unity is given to the study of the forms of organised beings, which before it lacked. And this, Francis suggests, was "effected almost as much by Darwin's special botanical work as by the Origin of Species." By asking why, by seeking meaning (not in any final sense, but in the immediate sense of use or purpose), Darwin found in his botanical work the strongest evidence for evolution and natural selection. And in doing so, he transformed botany itself from a purely descriptive discipline into an evolutionary science. Botany, indeed, was the first evolutionary science, and Darwin's botanical work was to lead the way to all the other evolutionary sciences--­and to the insight, as Theodosius Dobzhansky put it, that "nothing in biology makes sense except in the light of evolution." Darwin spoke of the Origin as "one long argument." His botanical books, by contrast, were more personal and lyrical, less systematic in form, and they secured their effects by demonstration, not argument. According to Francis Darwin, Asa Gray observed that if the orchid book "had appeared before the Origin, the author would have been canonized rather than anathematized by the natural theologians." Linus Pauling has said that he read the Origin before he was nine. I was not that precocious and could not have followed its "one long argument" at that age. But I had an intimation of Darwin's vision of the world in our own garden--­a garden which, on summer days, was full of flowers and bees buzzing from one flower to another. It was my mother, botanically inclined, who explained to me what the bees were doing, their legs yellow with pollen, and how they and the flowers depended on each other. While most of the flowers in the garden had rich scents and colors, we also had two magnolia trees, with huge but pale and scentless flowers. The magnolia flowers, when ripe, would be crawling with tiny insects, little beetles. Magnolias, my mother explained, were among the most ancient of flowering plants and had appeared nearly a hundred million years ago, at a time when "modern" insects like bees had not yet evolved, so they had to rely on a more ancient insect, a beetle, for pollination. Bees and butterflies, flowers with colors and scents, were not preordained, waiting in the wings--­and they might never have appeared. They would develop together, in infinitesimal stages, over millions of years. The idea of a world without bees or butterflies, without scent or color, affected me with a sense of awe. The notion of such vast eons of time--­and the power of tiny, undirected changes which by their accumulation could generate new worlds, worlds of enormous richness and variety--­was intoxicating. Evolutionary theory provided, for many of us, a sense of deep meaning and satisfaction that belief in a divine plan had never achieved. The world that presented itself to us became a transparent surface, through which one could see the whole history of life. The idea that it could have worked out differently, that dinosaurs might still be roaming the earth or that human beings might never have evolved, was a dizzying one. It made life seem all the more precious and a wonderful, ongoing adventure ("a glorious accident," as Stephen Jay Gould called it)--­not fixed or predetermined, but always susceptible to change and new experience. Life on our planet is several billion years old, and we literally embody this deep history in our structures, our behaviors, our instincts, our genes. We humans retain, for example, the remnants of gill arches, much modified, from our fishy ancestors and even the neural systems that once controlled gill movement. As Darwin wrote in The Descent of Man, "Man still bears in his bodily frame the indelible stamp of his lowly origin." We bear, too, an even older past; we are made of cells, and cells go back to the very origin of life. In 1837, in the first of many notebooks he was to keep on "the species problem," Darwin sketched a tree of life. Its brachiating shape, so archetypal and potent, reflected the balance of evolution and extinction. Darwin always stressed the continuity of life, how all living things are descended from a common ancestor, and how we are in this sense all related to each other. So humans are related not only to apes and other animals but to plants too. (Plants and animals, we know now, share 70 percent of their DNA.) And yet, because of that great engine of natural selection--­variation--­every species is unique and each individual is unique, too. The tree of life shows at a glance the antiquity and the kinship of all living organisms and how there is "descent with modification" (as Darwin originally called evolution) at every juncture. It shows too that evolution never stops, never repeats itself, never goes backwards. It shows the irrevocability of extinction--­if a branch is cut off, a particular evolutionary path is lost forever. I rejoice in the knowledge of my biological uniqueness and my biological antiquity and my biological kinship with all other forms of life. This knowledge roots me, allows me to feel at home in the natural world, to feel that I have my own sense of biological meaning, whatever my role in the cultural, human world. And although animal life is far more complex than vegetable life, and human life far more complex than the life of other animals, I trace back this sense of biological meaning to Darwin's epiphany on the meaning of flowers, and to my own intimations of this in a London garden, nearly a lifetime ago. Excerpted from The River of Consciousness by Oliver Sacks All rights reserved by the original copyright owners. Excerpts are provided for display purposes only and may not be reproduced, reprinted or distributed without the written permission of the publisher.