Journal of Neuro-Ophthalmology, December 2003, Volume 23, Issue 4

Adelbert Ames and the Dartmouth Eye Institute

LEGACY Adelbert Ames and the Dartmouth Eye Institute Susan M. Pepin, MD The striking of friendships and the meetings of minds have yielded advances in many fields. For example, there is the meeting of Frans Cornelius Donders and Albrecht von Graefe in London in 1851, which joined knowledge of physics and optics to clinical ophthalmology. Another gath­ering occurred in Hanover, New Hampshire, early in the twentieth century. The founder of the Dartmouth Eye Insti­tute ( DEI), Adelbert Ames II ( Figs. 1- 3), drew leaders in ophthalmology to this rural hamlet and sparked excitement in vision research. The story of the DEI stands as an example of collabo­ration among investigators from multiple fields that began as one individual's quest to understand what influences how we see. From 1921 to 1947, Ames brought together, among others, Walter Lancaster, Kenneth Ogle, Arthur Linksz, Paul Boeder, Hermann Burian, and Alfred Bielschowsky. Little evidence marks its erstwhile promi­nence, but the DEI used a collection of diversely trained researchers committed to furthering the understanding of vision and perception. Many of the topics explored by this fortuitous assemblage of people flourish in modern vision research. Ames came from a distinguished family. His mater­nal grandfather, Benjamin Butler, was a general and gover­nor of Massachusetts. General Butler ran unsuccessfully for President in 1884. His father, Adelbert Ames I, had been a general in the Civil War and later a Mississippi governor and United States senator. As a Harvard undergraduate, Ames took courses from William James and George Santayana. After complet­ing Harvard Law School, he became disillusioned with le­gal practice and became an artist. Inspired by his sisters, who were painters, he tried " to make exact color reproduc­tions of scenes" ( 1). With his sister Blanche Ames, he devised a color notation system consisting of more than 3,300 different color variations ( 1). ( By comparison, the in­fluential system created by the artist Albert Henry Munsell, From the Division of Ophthalmology, Dartmouth Hitchcock Medical Center, Lebanon, New Hampshire. Address correspondence to Susan M. Pepin, MD, Division of Ophthal­mology, Dartmouth Hitchcock Medical Center, One Medical Center Drive, Lebanon, New Hampshire 03756; E- mail: Susan. M. Pepin@ hitchcock. org and still used by clinicians and artists, contains only 1200 color variations [ 2].) While traveling around New En­gland painting landscapes and sculpting, Ames' analyt­ical mind contemplated the relationship between what one sees and what can be represented in art. How, he wondered, does the visual system reproduce the reality of the environ­ment? To approach the problem, he sought to understand the basics of image formation in the eye by studying its optical FIGURE 1. Adelbert Ames II, founder of the Dartmouth Eye Institute ( circa 1940). ( Courtesy of Dartmouth College Li­brary) Copyright © Lippincott Williams & Wilkins. Unauthorized reproduction of this article is prohibited. 290 JNeuro- Ophthalmol, Vol. 23, No. 4, 2003 Adelbert Ames and the Dartmouth Eye Institute JNeuro- Ophthalmol, Vol. 23, No. 4, 2003 FIGURE 2. Ames playing polo for the Myopia Hunt Club in 1906. ( Courtesy of Dartmouth College Library) characteristics. In 1914, he accepted a research fellowship with John Wallace Baird, a psychologist at Clark Univer­sity, and began more formal work in visual perception. In 1919, after a stint in the United States Army, where he gained experience designing instruments, Ames came to Hanover, New Hampshire, to consult with physics profes­sor Charles A. Proctor. Ames, his sister Blanche, and Proc­tor worked on a " binocular camera" which would simulate the superimposition in the brain of the retinal images seen by each eye. In 1921, Ames and Proctor published their first paper, " Dioptrics of the Eye," in the Journal of the Optical Society of America ( 3). The article attracted so much attention that Ernest Hopkins, the president of Dartmouth College, cre­ated the Department of Research in Physiologic Optics. Ames was elected Professor of Research in Physiologic Op­tics and given a Master of Art Degree by Dartmouth Col­lege later that year. When Ames and Proctor began their collaboration, the geometry of binocular vision was an area of active in­terest. It was during this time that Gordon H. Gliddon, a lens designer for Eastman Kodak Company, arrived in Hanover to enroll as Ames' graduate student. With Gliddon's help and expertise in lenses, Ames built a camera whose lens Copyright © Lippincott Williams & Wilkins. Una could simulate various optical aberrations of the eye. The goal was to produce photographs that could guide artists in portraying a scene as the human visual system allows it to be perceived. Ames' personal excitement about vision research was drawing other colleagues and graduate students to Dart­mouth. In 1930, Kenneth N. Ogle submitted his Ph. D. thesis under Ames with the title " The Resolving Power of the Hu­man Eye." The combined results of these researchers led to the establishment of the Dartmouth Eye Institute ( DEI) as separate from the Department of Physics ( Fig. 4). A grow­ing team of investigators shifted from exploring the optical properties of a single eye to the problem of binocular vision and space perception. The influence of retinal disparity on binocular depth perception had been studied by Panum and others in the early and mid- nineteenth century. In 1858, Panum had de­scribed the range of fixation with minimal retinal disparity over which fusion of two images can occur. By 1928, Ames and his colleagues had pursued an understanding of the in­fluence of binocular vision on perception. In particular, Ames recognized that depth perception was not the simple fusion of two images focused on each retina, and that when FIGURE 3. Ames ( in knickers on right) and Dean of Fresh­man and Director of Admissions for Dartmouth College Robert C. Strong on the Dartmouth Campus in the late 1930s. ( Courtesy of Dartmouth College Library) reproduction of this article is prohibited. 291 JNeuro- Ophthalmol, Vol. 23, No. 4, 2003 Pepin FIGURE 4. 4 Webster Street, Hanover, New Hampshire, home of the Clinical Division of the DEI in the 1930s. ( Cour­tesy of Dartmouth College Library) the two retinal images do notmatch, distortions of space can result. He believed that prisms could correct horizontal and vertical misalignments of the two eyes, but wanted to better correct what he called " a turning movement of the eye about the visual axis itself" ( 4). He gained a patent for an instru­ment he called the Lyman Dingbat, a device mounted on spectacles and designed to correct rotational mismatches between two eyes ( Fig. 5). The DEFs early fame came from the development of instrumentation and techniques for the measurement and correction of anomalies in the size and shape of ocular im­ages. Fheorists such as Donders ( 1864) had appreciated that large differences in image size from anisometropia make binocular vision difficult or impossible. Fhe DEI group fas­tened on this problem and used mathematical models to de­termine some of its causes, including unequal optics be­tween the two eyes. Meticulous clinical experiments were performed to verify the anomalies. The technology devel­oped was used to evaluate patients and correct the phenom­ena. The term " aniseikonia," combining the three Greek words meaning " not equal image," was coined in 1932, based on input from Harvard professors Charles Gulick, professor of classics, and Walter Fancaster, MD, a leading ophthalmologist who would later join the Dartmouth group. DEI researchers reported evidence that image size differ­ences as small as 0.5% to 2% might cause problems with fusion and that patients perceiving this image size differ­ence might experience distortions of space and depth ( 5). Ames, Ogle and Gliddon believed that people with aniseikonia might not recognize the distortions but would have " asthenopic symptoms." In 1932, Ames, Gliddon, and Ogle published " Size and Shape of Ocular Images, Part 1" in the Archives of Oph­thalmology ( 6), describing the theory and methods used in their new ocular measuring instrument, the eikonometer, to determine differences in the size and shape of images per­ceived by the two eyes ( Fig. 6). Fhe instrument design grew out of the theory of Hering's longitudinal horopter appara­tus and Fschernak's binocular devise developed in 1930. Fhe authors made an argument for the impact of this size and shape difference on binocular depth perception and the impact of a disturbance in binocularity on " mental causes of discomfort" ( 6). The second part of this article, published a month later by DEI researchers Elmer H. Carlton, MD and Feo F. Madigan, OD, reported case studies proving that in­numerable symptoms could be relieved by correcting re­fractive errors and interocular image size differences ( 7). Carlton, who had graduated from Dartmouth Medical School in 1897, served as a clinical instructor in otolaryn­gology and ophthalmology until he lost his right arm to an infection developed while he was operating. With his left arm, he became an expert refractionist and remained at the DEI from 1928 until it closed. Madigan had been a former student under Gliddon at the Rochester School of Optom­etry. These collaborators alleged that aniseikonia causes FIGURE 5. The " Lyman Dingbat." In 1928, Ames got the patent on this device for the correction of cyclophorias. It combines a negative power lens as the eyepiece and a posi­tive power lens as the objective lens placed at 90° to the first lens. Two reflectors are used, one between the lenses and one outside the Galilean telescope. The reflectors allow rotation of the image in the vertical and horizontal axes. ( No one alive knows the origin of the term " Lyman Ding­bat.") ( Courtesy of Dartmouth College Library) Copyright © Lippincott Williams & Wilkins. Unauthorized reproduction of this article is prohibited. 292 © 2003 Lippincott Williams & Wilkins Adelbert Ames and the Dartmouth Eye Institute JNeuro- Ophthalmol, Vol. 23, No. 4, 2003 FIGURE 6. Leo Madigan OD experimenting at the DEI with an early model of an eikonometer ( circa 1934). ( Courtesy of Dartmouth College Library) mysterious and incurable headaches, nervousness, bodily fatigue, stomach disorders, dizzy spells, carsickness, and unaccountable drowsiness. They reported that correction of image size differences brought complete relief of symp­toms to 20% of patients, partial relief to 60%, and no relief to 20% ( 7). According to Ames and his colleagues, retinal image asymmetry could be produced by retinal anatomic differ­ences or by the lens system of the two eyes. The accommo­dation of one eye might differ from that of the other eye, or one eye alone may have astigmatism. When correction of the differences required lenses with powers greater than 0.50 diopter, there was a difference in the exterior focal dis­tance that would blur one image. Ames and Gliddon devel­oped aniseikonic lenses, submitting in 1929 a patent based on a telescopic combination of plates to allow the enlarge­ment of an image on the retina along one axis to equalize dimensions without alteration in the vergence of light. Spectacles could be individualized for each patient based on measurements that would equalize the nodal points in the two eyes. Eyeglasses were made with multiple and su­perimposed lens elements to correct changes in vergence and retinal dimensional inequality ( Fig. 7). Laid out in more than a hundred subsequent publica­tions in such journals as the American Journal of Ophthal­mology and the American Journal of Optometry, the DEFs work became the premise for the instruction in aniseikonia in optometry and ophthalmology climes and academic de­partments across the United States. In 1933, Ames and Gliddon were awarded a bronze medal by the American Medical Association for their work on aniseikonia ( Fig. 8). Advertisements and publicity for the DEI group empha­sized that traditional methods of refractive measurement did not uncover all the abnormal physiology that might cause symptoms. Thousands of patients from all over the world were drawn to little Hanover, New Hampshire in the hope that detection and correction of aniseikonia would obliterate their symptoms. DEI exponents practiced in Bos­ton, New York, Baltimore, Washington DC, Atlanta, and San Francisco ( 8). Perhaps the most famous ophthalmologist to work at the DEI was Dr. Alfred Bielschowsky ( Figures 9- 11). A well- known European ophthalmologist, Bielschowsky had studied under Drs. Ewald Hering and Carl Sattler in Leipzig, Germany. Early in his career, he became the direc­tor of the Eye Clinic at the University of Breslau and pub­lished the first sensory description of monocular diplopia and later many articles on ocular motility disorders. In 1934, the " pope of strabismus" accepted an invitation to visit the United States from Arnold Knapp MD, an ophthal­mologist and the editor of the Archives of Ophthalmology. On his tour of the United States, Bielschowsky met Ames, who invited him to visit Hanover and the DEI. Bielschowsky was offered the position of clinical director of the DEI. At first he decided to return to Breslau, but as a Jew, he became a target of anti- Semitic demonstrations out­side his office and in his lectures. He later accepted the DEI offer and returned to Hanover. The presence of Bielschowsky augmented the scien­tific reputation of the DEI. " Herr Doktor" spent a produc­tive 5 years examining patients, performing surgery, and publishing his comprehensive " Lectures on Motor Anoma­lies," including " The Etiology of Squint" and " Functional Disturbances of the Eyes" ( 9,10), Although he enthusiasti­cally supported the development of " evidence of a causal connection between aniseikonia and the deficiency of fu­sion" as a cause of strabismus, Bielschowsky's own in­volvement in aniseikonia was limited ( 11). Early in his time at the DEI, he brought his former student Dr. Werner FIGURE 7. Iseikonic lenses produced in 1987. The patient had 2.50 diopters of astigmatism OS. Multiple plus or mi­nus lenses were cemented together on the edges in iseikonic lenses to allow not merely focusing of light rays but equalization of image size on the retina of the two eyes. Copyright © Lippincott Williams & Wilkins. Unauthorized reproduction of this article is prohibited. 293 JNeuro- Ophthalmol, Vol. 23, No. 4, 2003 Pepin FIGURE 8. Bronze medal given to Ames and Gliddon by the American Medical Association on May 29, 1933 for their work on aniseikonia, considered a " significant appli­cation of physics and physiologic optics to ophthalmol­ogy." ( Courtesy of Dartmouth College Library) Herzau to Hanover. Herzau had trained in Prague and later worked under Bielschowsky in Breslau. When Herzau de­cided to return to Germany in 1935, Bielschowsky invited another European trained ophthalmologist, Dr. Hermann Burian from Prague, to join the group ( Fig. 12). Burian stayed at the DEI for 10 years before leaving for a private practice in Boston, and, in 1951, for the University of Iowa, where he continued to contribute greatly to the field of oph­thalmology. Bielschowsky died suddenly after attempted pneumoencephalography in New York as part of the diag­nostic investigation of a brain tumor. His grave lies in the cemetery in the center of the Dartmouth College campus. In the autumn of 1940, Lancaster ( Fig. 13) agreed to replace Bielschowsky as the clinical director of the DEI. While many others had been skeptical of the work at the DEI, Lancaster had been involved with the group for many years while in practice in Boston. His wife Emma Winter was a descendant of Eleazer Wheelock, the founder of Dart­mouth College. Lancaster found that he had little influence on the direction of DEI research or policy and resigned after just 2 years to return to his practice in Boston. Over the course of almost 20 years, members of the DEI ( Fig. 14) collaborated under Ames' direction to over­come technical and theoretical challenges involved in un­derstanding the physics, physiology, and psychology of vi­sion. In their research synopsis forthe staff bulletin in 1941, they wrote collectively: " As civilization advances, life increasingly depends on the efficiency of our space- perception capacity. Pi­loting airplanes and driving motor cars are examples FIGURE 10. Bielschowsky examines a patient for binocu-larity at the DEI as Medical Director ( circa 1937). ( Courtesy of Dartmouth College Library) Copyright © Lippincott Williams & Wilkins. Unauthorized reproduction of this article is prohibited. 294 © 2003 Lippincott Williams & Wilkins Adelbert Ames and the Dartmouth Eye Institute JNeuro- Ophthalmol, Vol. 23, No. 4, 2003 FIGURE 11. Bielschowsky working at the DEI in 1938 with his copy of Duke- Elder's System of Ophthalmology at his side. ( Courtesy of Dartmouth College Library) of modern activity placing increasing dependence upon this function of vision. The most important con­tribution made by the Dartmouth Eye Institute has been its advance in the basic knowledge of space per­ception. Dartmouth's discoveries of such basic scien­tific laws and its application of these laws to the relief of human suffering and in the individual's occupa­tional capacity, have in turn led to the Institute's col­laboration with instrument and lens makers to make this new knowledge widely available."( 8) Despite the enthusiasm and efforts of the researchers, financial support for the DEI was always a problem. The FIGURE 12. Dr. Hermann Burian examines a patient for aniseikonia with a simple slit lamp in the Research Division of the DEI in 1937. ( Courtesy of Dartmouth College Library) FIGURE 13. Walter Lancaster, MD, in 1940, during his brief role as Clinical Director of the DEI. ( Courtesy of Dart­mouth College Library) Rockefeller Foundation contributed funding in the early years. But the combination of Ames' shift in interest away from the clinical work of the DEI, postwar changes, and hierarchical interplay between Dartmouth College, the Medical School, and the Hitchcock Clinic made for an un­certain fiscal environment. Lack of independent support and politics within the university eventually led to the DEFs closure in 1947. David C. Bisno, MD has written an extensive description of the DEI, attributing its closure to Dartmouth College president Hopkin's greater loyalty to the undergraduate college than to the graduate schools ( 12). In the DEFs final years, Ames and some of his col­leagues shifted their interests toward psychology. While this shift reflects Ames' broad interest in perception, it may also be the result of the inability of his optical systems and iseikonic lenses to correct or explain visual experience. Ames' later writings discuss an " assumptive world" based on an internalized perceptual system, a reminder of his original quest to understand the interplay between percep­tion of reality and art. From the middle of the 1930s until his death, he studied visual illusions, collectively published un­der the title'' Ames' Demonstrations in Perception'' ( 13). He Copyright © Lippincott Williams & Wilkins. Unauthorized reproduction of this article is prohibited. 295 JNeuro- Ophthalmol, Vol. 23, No. 4, 2003 Pepin FIGURE 14. DEI members in 1941. First row ( left to right): Leo F. Madigan, Gordon H. Gliddon, Walter B. Lancaster, Adelbert Ames, John Pearson, Elmer H. Carleton. Second row: Wendell Triller, Hermann M. Burian, Henry A. Imus, Kenneth N. Ogle, Arthur Linksz, Isabelle Andrus, Robert E. Bannon, Camilla Hubscher, Rudolph T. Textor. Third row: Irving E. Bender, Milton R. Thorburn, Ruth Humble, Helen Heartz, Leon E. Straw, Donald W. McKechney, Ellen Shattuck. Fourth row: Barbara Jordan, Arlene Jenney, Mary England, Mary Beebe, Isabel Dickinson, Barbara Holden, Rosamond Scott, Norma DesRoches. ( Courtesy of Dartmouth College Library) moved freely between historically unrelated fields, a skill that might have served him well today with the current em­phasis on multidisciplinary scholarship. In an example of his interest in the philosophical and social implications of vision, he wrote that " the insights gained in the study of visual sensation can serve as indispensable leads to better understanding and more effective handling of the com­plexities of social relationships" ( 14). In his later years, Ames was trying to elucidate the interdependencies be­tween perception, action, and purpose. For example, he de­veloped " demonstrations" of trompe l'oeil for the psychol­ogy laboratory that challenged perceptual interpretation by creating illusions. With the creation of " the leaf room," he hoped to achieve an environment with a minimum of mon­ocular depth cues. In a cube of wire mesh mounted on a wire frame, oak leaves were used to cover all but one open side ( Fig. 15). Ames then used eikonic lenses to enlarge the im­age on the retina along one axis without altering the optical properties of the two retinal images. With this protocol, he studied binocular space perception with altered binocular disparities without affecting other distance clues ( 13). His work had a strong influence on the evolution of psychology, particularly through his relationship with Hadley Cantril, PhD, professor of psychology at Princeton University. Ames died in Hanover in 1955, after receiving a Doc­tor of Laws degree from Dartmouth College in 1954 for his significant influence as a " lifelong student of human per­ception." Reminders of Ames and the DEI linger in Hanover. There is the patient who brings an odd set of spectacles to the clinic. A past employee of the DEI fondly recalls the enjoyment several researchers would get from sending a newly hired nurse on an urgent errand to the hospital stor­age rooms in search of one hundred feet of Fallopian tube. But the DEFs work on aniseikonia has not endured within FIGURE 15. The Leaf Room ( circa 1939). Ames developed the Leaf Room, lined with leaves, to eliminate the cues for perspective interpretation so that the observer in front of the room would have to depend primarily on binocular vision or stereopsis for three- dimensional perception. When iseikonic lenses were introduced to alter the two ocular images, the observer would see the room as tipped, with the floor and ceiling raised or lowered. The room can still be found in the basement of the Hopkins Center at Dartmouth College. ( Courtesy of Dartmouth College Library) Copyright © Lippincott Williams & Wilkins. Unauthorized reproduction of this article is prohibited. 296 © 2003 Lippincott Williams & Wilkins Adelbert Ames and the Dartmouth Eye Institute JNeuro- Ophthalmol, Vol. 23, No. 4, 2003 the scientific or clinical arenas of ophthalmology. Claims of curing so many nonspecific symptoms with eikonic lenses seem over zealous today. A small amount of aniseikonia is now considered common and of no clinical consequence. The mathematics involved in understanding or correcting large differences in the size of optical images of the two eyes has disappeared from ophthalmology training, perhaps because advances in contact lenses and refractive surgery have eliminated large interocular image size disparities. The legacy of the DEI lies rather in the productive effort of a cohort of researchers devoted to understanding vision. Ames propelled the careers and research efforts of many others who spread out from Hanover to make sub­stantial contributions in the fields of optics, visual percep­tion, and psychology. Acknowledgments A special thanks to Sarah Hartwell at the Rauner Spe­cial Collections Library, to Patrick Saine, CRA, M. Ed, and Kimberly Strain, CO A, CRA, for their assistance with ar­chived photographs and manuscript preparation and to David Bisno, MD and Arthur Jampolsky, MD for their help and expertise with the manuscript and subject matter. REFERENCES 1. Ames AJr. Systems of color standards. J Optic Soc America 1921: 5: 160- 170. 2. Munsell AH. Atlas of the Munsell Color System. Massachusetts: Wadsworth, Howland and Co., Inc., Printers, 1915. 3. Ames A Jr, Proctor CA. Dioptrics of the eye. J Optic Soc America 1921; 5: 22- 84. 4. Ames A Jr, Gliddon, GH. United States Patent # 1,908,296. May 9, 1933. 5. Ames A Jr, Ogle KN, Gliddon, GH. Corresponding retinal points, the horopter and size and shape of ocular images. J Optic Soc America 1932; 22: 575- 632. 6. Ames A Jr, Gliddon GH, Ogle KN. Size and shape of ocular images: I. Methods of determination and physiologic significance. Arch Ophthalmol 1932; 7: 576- 597. 7. Carleton EH, Madigan LF. Size and shape of ocular images: II. Clinical significance. Arch Ophthalmol 1932: 7: 720- 738. 8. Staff Bulletin forthe Dartmouth Eye Institute. 1941. 9. Bielschowsky A. The etiology of squint. Am J Ophthalmol 1937: 20: 478- 489. 10. Bielschowsky A. Functional disturbances of the eyes. Arch Oph­thalmol 1936; 15: 589- 603. 11. Bielschowsky, A. Congenital and acquired deficiencies of fusion. Am J Ophthalmol 1935; 18: 925- 937. 12. Bisno, DC. Eyes in the Storm, President Hopkin ' s Dilemma. The Dartmouth Eye Institute. Norwich Press Books, 1994: 101- 166. 13. Ittelson WH. The Ames Demonstrations in Perception. New York: HafnerPub. Co., 1968. 14. Ames A. Sensations, Their Nature and Origin: Brief Statement of the Findings of the Dartmouth Eye Institute, 1945. Copyright © Lippincott Williams & Wilkins. Unauthorized reproduction of this article is prohibited. 297