Detection and Assessment of Color Vision Anomalies and Deficiencies in Children
2001; Slack Incorporated (United States); Volume: 38; Issue: 4 Linguagem: Inglês
10.3928/0191-3913-20010701-05
ISSN1938-2405
AutoresM A Díez, María José Luque Cobija, Pascual Capilla, Juan F. Gómez, Dolores de Fez Sáiz,
Tópico(s)Color perception and design
ResumoReview ArticleDetection and Assessment of Color Vision Anomalies and Deficiencies in Children Maria Amparo Díez, OD, , , OD Maria Jose Luque, PhD, , , PhD Pascual Capilla, PhD, , , PhD Juan Gómez, MSc, , and , MSc Maria Dolores de Fez, PhD, , PhD Maria Amparo Díez, OD , Maria Jose Luque, PhD , Pascual Capilla, PhD , Juan Gómez, MSc , and Maria Dolores de Fez, PhD Journal of Pediatric Ophthalmology & Strabismus, 2013;38(4):195–205Published Online:July 01, 2001https://doi.org/10.3928/0191-3913-20010701-05Cited by:3PDFView Full Text ToolsAdd to favoritesDownload CitationsTrack Citations ShareShare onFacebookTwitterLinkedInRedditEmail SectionsMore1. Pokotny J, Smith VC. Congenital and Acquired Colour Vision Defeca. London, England: Grune-Stratton; 1979. Google Scholar2. Artigas JM, Capilla P, Felipe A. Pujol J. ?ptica Fuio??gico. Pr?taflsica ? ?a VaUn. New York, NY: McGraw-Hill InterAmericana; 1995. Google Scholar3. Flctcher R, Volte 1. Defective colour vision. In: Fundamentals. Diagnosis ami Management. Bristol, United Kingdom: Adam HilgerLtd; 1985:134-209,417-150. Google Scholar4. Foster DH. Iahirited and Acquired Colour Vision Difidencia. Vol 7. London, England: MacmiMan Press; 1991. Google Scholar5. Estévez O. Anomallas Cromáticos, Ciencia del Color. Valéncia, Spain: Universitat de Valéncia; 1983. Google Scholar6. Alpem M, Pugh EN Jr. Variation in die action spectrum of crythrolabe among deaKnnopes.JPtrpielfLonJ). 1977;266; 613-646. Google Scholar7. Alpern M, Wake T. Cone pigments in human deutan colour vision defects. J Pfrysiol (Lenii). 1977:266:595-612. Google Scholar8. Alpern M, Modlet J. The red and green cone visual pigraenis of deuteranoinalous muuamacy. J Physiol (Lend). 1977:266:647-675. Google Scholar9. Bowmarkcr JK, Dannali HJ, MoUon JD. The violet-sensitive receptors of primate retinae. J Physiol (Lend). 1979;292:31P. Google Scholar10. Bowmarker JK, Dannali HJ, Mollon JD. Microspectrophorometric demonstration of four classes ofphototeceptor in an old world primate, Macaca fascicularis. J Physiol (Land). l980i298:13M43. Google Scholar11. Nimeroff I. Deuteranopic convergence point. / Opt Sac Am. 1970;60:966-969. Google Scholar12. MacLeod DI, Lennie R Red-green blindness confined to one eye. Vision Kn. 1976; 16:691 -702. Google Scholar13. Graham CH, Hsia Y. The spectral luminosity curve for a dichromarie eye and a normal eye in the same person. Proc Nati Acaii Sci USA. 1958;44:46-49. Google Scholar14. Graham CH, Hsia Y. Some visual funciions of a unìlaterally dichromatic subject. In: Visual Problems of Colour.Vol 1. London, England: HMSO; 1958:279-295. Google Scholar15. Graham CH, Hsia Y. Color defeci and color theory: studies on normal and color-blind persons including a unilaierally dichromatic subject. Scitncf. 1958; 127:675-682. Google Scholar16. Bender BG, Ruddock KH, de Vries de Mol EC, Went LN. The colour vision characteristics of an observer with unilateral defeclive colour vision: results and analysis. Vision Ra. 1972;12;20352057. Google Scholar17. Walls GL. Notes on four tritanopes. Vision KfS. 1964;4:3-16. Google Scholar18. Kaiser PK, Boynton RM. Human Coler Vision. Washingion, DC: Optical Society of America: 1996. Google Scholar19. Dim MA, Capilla P, Luque MJ. Detección de patologías mediante tesis psicofisico;, II: patologías que afectan a los caminos visuales paralelos. Vtry Oír. 1999;133:1 55-167. Google Scholar20. Alexander KR. The Turnus Pediatrie Color Perception Test as a color vision screener: a comparative study. American Journal of Physiological Optics. 1975:52:338-342. Google Scholar21. Vies II. A clinical evaluation of color testing and color perception. American Journal of 'Optomeny. 1966;43:582-592. Google Scholar22. Wildman PR. Teacher awareness of color deficiency and predictive results. American Journal ofOptometry. 1966;43:305-312. Google Scholar23. Taylor WO. Diagnosis of colour-vision defects in very young children. Lances. 1970; 1:78 1 -7 82. Google Scholar24. Verrkst G, Hermans G. Les aptitudes visuelles professionnelles. BuU Sue Belge Ophtabnol. 1975:169:1-552. Google Scholar25. Diez MA, Capilla R Luque MJ, Detección de patologías mediante tests psicofïsicos, L características de los caminos visuales paralelos. Very Oír. 1999:132:49-57. Google Scholar26. Sloan LL Testing for deficient color perception in children, int Ophthalmol Clin. 1963:3:697-705. Google Scholar27. Gallaghet JR, Gailagher CD. Color vision screening of preschool and first grade children. Arch Ophthabnol. 1964;72:200-211. Google Scholar28. Delthi S, Sourdille J. Perdriel G. Appreciation des fonctions visuelles chez l'enfant de 2 à 6 ans. Bulletin de la Société d'Ophtalmologie de France. 1968;6S: 1-167. Google Scholar29. Bacon L. Colour vision defect- an educational handicap. Medical Officer. 1971;125:199-209. Google Scholar30. Schneider H. Farbenrehlsichiîgkeit, Hindernis bei Mengenlehre. Deutsch Arzteblatt. 1972;17:1051. Google Scholar31. Espinda SD. Colour vision deficiency in third and six grade boys in association to academic achievement and descriptive behavioral patterns. Disability Abstract International. 1971:32:786. Google Scholar32. Espinda S. Color vision deficiency: a learning disability? / Learn Disabil. 1973;6:163-166. Google Scholar33. Snyder C. The psychological implications of being color blind. Journal of Special Educativa. I973;7:51-54. Google Scholar34. Immura T. Concerning the social adaptability of persons wiih congenital defective color vision [abstract], folia Ophthalmologica Japónica. 1977:28:890-892. Google Scholar35. Ohba N, Fujîno T. Tanino T. Yano M, Totsuka S. lnaba Z. Anomalous vision in daily activities of congenital color vision defectives. Folia Ophthalmologica Japónica. 1977;28:876-878. Google Scholar36. Richards OW. Color vision marked improvement: age 10 io 14. The Optical Journal and Rcvittv of Qpromftry, 1975;112:7-12. Google Scholar37. rosvenor T. Are visual anomalies related to reading abilityí/?t? OptomAsioc. 1977:48:510-517. Google Scholar38. Richer S, Adams AJ. An experimental test of filter-aided dichromatic color discrimination. American Journal ofOptometry and Physiological Opón. 1984:61:256-264. Google Scholar39. Richer S, Adams AJ. Development of quantitative tools for filteraided dichromats. American Journal of Opiomclry and Physiological Optics. 1984:61:246-255. Google Scholar40. Jennings JE. Color-Vision and Color- Blindness. 2nd ed. Philadelphia, Pa: Davis; 1905. Google Scholar41. Stonebridge EH. Practical help for color defectives. Ophthalmological Optics. 1968;68:62. Google Scholar42. McKay Taylor CO. The Optician. 1978;175:9. Google Scholar43. Birch-Hirschfcld. Neodym Glass. Berlin, Germany; Kargen 1932. Google Scholar44- Phillips RA, Kondig W. Recognition of traffic signals viewed through colored filters. / Opt Sac Am. 1975;65:1 106-1 113. Google Scholar45. National Research Council. Procedures jor Testing Color Vision: Rfpen af Working Party 41 of the National Research Council. Washington, DC: National Academy Press; 1981. Google Scholar46. Reed JD. The effect of illumination in changing the stimuli in pseudo-isochromatic plates. J Opt Sec Am. 1944;34:350. Google Scholar47. Hardy LH, Rand G, RitderMC. Effect of quality of illumination on resulis of the lshihara test, y Opt Soc Am. 1946:36:86-94. Google Scholar48. Volk D, Fry GA. Effecr of quality of illumination and distance of observation and performance in the lshihara lest. American Journal ofOptometry. 1947;24:99-122. Google Scholar49. Schmidt 1. Effect of illumination in testing color vision wiih Rl.C. C\IKS. J Opt Soc Am. 1952:42:951-955. Google Scholar50. Katavisto M. Pseudoisochromatic plates and artificia! lighi. Acta Opbthabnologica-KjoBenhaim. 1961:39:337-390. Google Scholar51. Higgings KE, Moskowitz-Cook A, Knoblauch K. Color vision testing: an alternative source of illuminant C. Modem Problems in Ophthalmology. 1978;19:113-121. Google Scholar52. Sloan LL. An improved screening test for red-green color deficiency composed of available pseudoisochromatic plates. J Opt SocAm. 1945:35:761-766. Google Scholar53. Farnsworth D, Reed JD, Shilling CW. The effect of certain illuminants on scores made on pseudoisochromatic tests. In: Color Vision Report, 4. New London, Conn: US Naval Medical Research Laboratory, 1948. Google Scholar54. PokornyJ, Smith VC. Evaluation of single-pigment shift model of anomalous crichromacy./ OptSoc Am. 1977:67:1196-1209. Google Scholar55. Crone RA. Quantitative diagnosis of defective color vision. A comparative evaluation of the lshihara test, the Farnsworth dichoconious test and the Hardy-Rand-Ritler polychromatic plates. AmJ Opbthalmol. 1961:51:298-305. Google Scholar56. Dain SJ, Honson V], Selection of an optima] light source for the F-M 100 Hue test. Doc Ophthacmol. 1989:52:425-432. Google Scholar57. Verriest G. Colour vision tests in children, pan I. Attiv Fondazioni Giorgio Ronchi. 1981:36:83-90. Google Scholar58. Belcher S, Greenshields K, Wright WD. A colour vision survey. BrJOphthelmol. 1958;5 1:355-359. Google Scholar59. Bitch J, McKccvcr LM. Survey of the accuracy of new pseudoisochromatic plates. Ophthalmic Physiot Opt. 1993:13:35-40. Google Scholar60. Mantyjarvi M. Colour vision testing in prc-school-aged children, Ophthalmologies. 1991;202:147-151. Google Scholar61. Hardy LH, Rand G, Ritder MC. The H.R.R. polychromatic plates. J OptAmSoc. 1945:44:509-523. Google Scholar62. CammockT, Cairns E, Concurrent validity of a children's version of the Slroop Color-Word Tesr: the Fruit Distraction Test. Percept MotSkiUs. 1979:49:611-616. Google Scholar63. Kojima K, Matsubara H. Color Vision Tat Plates for Infants. Tokyo: Handaya Co; 1957. Google Scholar64. Lee DY, Cotter SA, French AL. Evaluation of Kojima-Matsubara color vision tets plates: validity in young children. Opium Vis Sd, 1997:74:726-731. Google Scholar65. Stag DR, Evereti M, Swanson WH. The importance of controlled illumination in color vision testing in a pediatrie ophthalmology clinical practice. J Pediatr Ophthalmel Strabismus. 1993:30:39-42. Google Scholar66. Swanson WH, Evetett M. Color vision screening of young children. J Pediatr Opbthalmol Strabismus. 1 992;29:49-54. Google Scholar67. ConcrSA, Lee DY, French AL. Evaluation of a new color vision test: Color Vision Test Made Easy. OptomVaSci. 1999;76:63 1-636. Google Scholar68. Sloan LL, Habel A. Tests for color deficiency based on the EI.C. principle: a comparative study. Arch OphthalmoL 1956:55:229-239. Google Scholar69. Peters GA. The new Dvorine colour perception test. Oplometry Weekly. 1954;11:1801-1803. Google Scholar70. Stcen JA, Lewis MF. Color defective vision and day and night recognition of aviation color signal light flashes. Aerospace Mtdictne. 1972;43:34-36. Google Scholar71. Umazume K, Seki R, Obi S. Trial manufacture of a new color vision test plates. Aaa Sac Ophthalmol Jpn. 1954:58:732-735. Google Scholar72. Umazumc K, Scki R. Obi S. Studies in trial make of new color vision test plates. Acta Sec Ophthalmol Jpn. 1 956:60:1780- 1782. Google Scholar73. Uroazume K, Seki R, Obi S, Shimizu K. Studies in trial make of new color vision test plates. Acte Sec Opbthalmol Jpn. 1955:59:765-766. Google Scholar74. Mukai M, Yamamoto K, YoshinagaY. Sato K, Ohta M. Studies in the color test plates for infants. }ap Msehr Ptakt Augfnheili. 1960:54:715-719. Google Scholar75. Hukarni K. Studies on Tokyo Medical College color vision test for school children. Folia Ophthalmologies Japónica. 1960:11:842-845. Google Scholar76. Hukami K. Evaluation of Kojima-Matsubaras pseudo-isochromalic plates for children. Folia Ophthalmologies Japónica. 1961:12:392-396. Google Scholar77. Hukami K. Color vision rest for children under 6 years of age. Folia Ophthalmoiogica japónica. 1961; 12:590-594. Google Scholar78. Hukarai K, Iwata C. Color discrimination test for children aged 4 to 7 years. Folia Ophthalmologu -a Japónica. 1967;18:1067-1071. Google Scholar79. Pinckers A. The Farnsworth tritan plate. Ophlhalmologica. 1972;I64:137-142. Google Scholar80. Ontani K, Ohta Y, Kogure S, Kato H, Shimiiu K, Seki T. Farnsworth tritan plate./ Clin Ophthalmol. 1974;28:25-30. Google Scholar81. Gardiner E A colour vision test foi young children and the handicapped. Dev Mea" Child Neural. 1973; 15:437-440. Google Scholar82. Hahn CS. Nao Psnajoisoctiromaric Coloar Vision Test. 4th ed. Seoul. Korea: Hard! Medical Instruments Manufacturing Co; 1991. Google Scholar83. Hahn CS. Evaluation of congenital color vision deficiencies. Korean J Ophthalmol. 1991:5:26-29. Google Scholar84. Dain SJ, Gray S, Tran L. Colorimetrie analysis and perfomance assessment of the Hahn New Pscudoisochromatic Colour Vision Test. Color R, -search and Application. 1988;23:69-77. Google Scholar85. Chauhan BC, Block MT. City tests and information theory. Ophthalmic anil Physiological Optici. 1986:6:157-103. Google Scholar86. Flctcher R]. A modified D-15 rest. Modern PrebUms of Ophthalmology. 1972;ll:22-24. Google Scholar87. Taylor SK The effect of restricted viewing time on the perfbrmance of colour defectives using rhe City University Colour Vision Test. Ophthalmic Physio! Opi. 1984;4:49-52. Google Scholar88. Birch J. Clinical use of the City University Test (2nd edition). Ophthalmic Physiol Oft. 1997:17:466-472. Google Scholar89. Pease PL, Alien J. A new test for screening color vision: concurrent validity and utility. American Journal of Optometry and Physiological Optics. 1988:65:729-738. Google Scholar90. Mantyjarvi M. Veihagen Pfiigertrident pseudoisochromatic plates in screening congenital red-green vision defects. Gratffs Arch Clin of OphthalmoL 1991;229:145-146. Google Scholar91. Khavina AE, Marre M. Marre B. The i tudy of color vision in children. Oftalmologicheskii ZhurnaL 1990:8:458. Google Scholar92. Marre M, Marre E, Lange C, Roiczsch R, Buchmann JH. Sender R. Early diagnosis of congenital disorders of color vision with the Veihagen "Pflügerhaken Color Charts foi evaluating color perception" in 3375 preschool children. Klin Monaabl Augtnbeilkd. 1990; 196:2 1-25. Google Scholar93. Okuma T, Masuda H, Kawada C, Shinjo U. Ishihara-Okuma's new lest plaies for colour defectives. AcIa Sof Ophthoimol Jpn. 1973;77: 1359- 1365. Google Scholar94. Lanthony P. The Okuma's test: an evaluation. Ophthaimologica. 1990;200:84-88. Google Scholar95. Littlewood R, Hyde F. Screening for congenital colour vision defects. A comparison between the Okuma and Ishihara plates. Aust N Z J OphihahnoL 1993;2 1:3 1-35. Google Scholar96. Guerin-Rktard Y. Contribution à Lftade el à L'intérit ? Diagnostic Précoce, des l'âge Scolaire, des Anomalies du Sens Celaré Matière D'orientation Profàienncl/c [thesis]. Paris. Fiance; 1962. Google Scholar97. Taylor WO. An advisory clinic for colour defective childrt Trans Ophthalmal Soc UK. 1966;86:591-607. Google Scholar98. Birch J, Chisholm IA. Kinncat P, ci al. Clinical testing meihoi In: Congeniali Acquired Celar Vision Defeca. New York, N Gruñe St Srratton; 1979:83-135. Google Scholar99. Birch J. Use of the Famsworth-Munsell 100-Hue lest in! examination of congenital coloi vision defects. Ophthalmic a Physiological Optics. 1989:9:156-162. Google Scholar100. Sassoon HF. Blue vision in children. What is the clinical signi canee of diminished acuity= CUn Pedietr. 1973:12:351-354. Google Scholar101. O'Connell EM. Davis M. Sassoon HF. Blue perception and leaf ing disabilities in students. Journal ofOptometrj Vision Theortii 1974;5:50-57. Google Scholar102. Sassoon HF, Davis M. O'Connell EM. Vision rests as predict, of learning disabilities. J Am Optom Assoc. 1977:48:49-55. Google Scholar103. Maurer D, Lewis TL, Cavanagh P, Anstïs S. A new test of lur nous efficiency for babies, inursi Ophthalmol Vis Sci. 1989:30:25 303. Google Scholar104. Cavanagh P, Anstis S, Mathcr G. Screening for color blindons ing opiokinetic nystagmus. Invest Ophthalmol Vis S 1984:25:463-466. Google Scholar105, White CT, Katoka RW, Martin Jl. Colour-evoked potemia development of a methodology for the analysis of the procès; involved in colour vision. In: Desmedí J, ed. Vinai Evok Potentials in Man: New Developments. Oxford, United Kingdot Claredon; 1977:250-272. Google Scholar106. Ver Hoeve JN, France TD, Bousch GA. A sweep VEP test f color vision deficits in infants and young children. / Pfdif. Ophthalmol Strabismus. 1996:33:298-302. Google Scholar107. Kemp CM, Jacobson SG, Faulkner DJ. Walt RW. Visual rimerie and rhodopsin levels in humans with vitamin A deficiency. EJ EycRes. 1988:46:185-197. Google Scholar108. Reddy V, Vijayalaxmi. Colour vision in vitamin A deficiency, i Mea J. 1977:1(6053):81. Google Scholar109. Rieger G. The effect of combined iodine treatment in Ball Ha on the color perception of patients. Klin MonatsU Augmhcilkc 1988; 193:41 6-419. Google Scholar110. LaBissoniere Red. int Contact Lens CUn. 1974;l:48-55. Google Scholar111. Schmidt I. Comments on the X-Chrom lens. J Am Optom AISOI 1972:43:199-201. Google Scholar112. Zeltzct Hl. The X-Chrom contact lens and color deficiency. Op J Re» Optom. 1973il 10:15-19. Google Scholar113. Kemmetmuller H, Keck G, Cabaj A. L'effet des lentilles de contad teintées sut Ic sens chromatique. Contactologica. 1980;2: 273-280. Google Scholar114. Welsh KT»; Vaughan JA, Rasmussen PG. Acromcdical implications of the X-Chrom lens for improving color vision deficiencies. Aviat Space Environ Mea. 1979;50:249-255. Google Scholar115. Hartenbaum NP. Stack CM. Color vision deficiency and the XChrom lens. Occup Health Saf 1997:66:36-40,42. Google Scholar116. Schlanger JL. The JLS lens: an aid for patients with color vision problems. AmJ Optom Physiol Opt. 1985:62:149-151. Google Scholar117. Kassar BS, Dresner SC, May JG, Marx MS, Safir A. Evaluation of the X-Chrom lens and color deficiency. CLAOJ. 1 984; 1 0: 1 00-1 03. Google Scholar118. Matsumoto ER, Johnson CA, Post RB. Effea of X-Chrom lens wear on chromatic discrimination and stereopsis in color déficient observers. AmJ Optom Physiol Opt. 1983:60:297-302. Google Scholar119. Paulson HM. The X-Chrom lens foi collection of color deficiency. MUMeJ. 1980:145:557-560. Google Scholar120. Knoblauch K, McMahon MJ. Discrimination of binocular color mixtures in dichromacy: evaluation of the Maxwell-Comsweet conjecture./ Opt Sac Am. 1995:12:2219-2229. Google Scholar121. Adams AJ, Tague MK. Performance of air traffic control tasks by protanopic color defectives. Am J Optom Phyiial Opt, 1985:62:744-750. Google Scholar122. Polizzotto L. Effects of usine an orange niter on the color perception of dichiomats. Am] Optom Physiol Opt. 1984:61:532-537. Google Scholar123. Richards OW. Limited improvement of color deficient vision with colored fillers. J Am Optom Assoc. 1983:54:537-539. Google Scholar Previous article Next article FiguresReferencesRelatedDetailsCited by Tang T, Álvaro L, Alvarez J, Maule J, Skelton A, Franklin A and Bosten J (2021) ColourSpot, a novel gamified tablet-based test for accurate diagnosis of color vision deficiency in young children, Behavior Research Methods, 10.3758/s13428-021-01622-5, 54:3, (1148-1160), Online publication date: 1-Jun-2022. Rigaudière F, Leid J, Viénot F and Le Gargasson J (2006) Comprendre et tester les déficiences de la vision des couleurs de l'enfant, en pratique, Journal Français d'Ophtalmologie, 10.1016/S0181-5512(06)73755-X, 29:1, (87-102), Online publication date: 1-Jan-2006. Citirik M, Acaroglu G, Batman C and Zilelioglu O (2009) Congenital Color Blindness in Young Turkish Men, Ophthalmic Epidemiology, 10.1080/09286580590932743, 12:2, (133-137), Online publication date: 1-Jan-2005. Request Permissions InformationCopyright 2013, SLACK IncorporatedPDF download
Referência(s)