Scanning laser ophthalmoscope fundus perimetry: The microperimetry

Imagem de Miniatura
Arquivos
art_BITTENCOURT_Scanning_laser_ophthalmoscope_fundus_perimetry_The_microperimetry_2014.PDF (1.35 MB)
Citações na Scopus
0
Tipo de produção
bookPart
Data de publicação
2014
DOI
Scopus
Título da Revista
ISSN da Revista
Título do Volume
Editora
CRC PRESS
Autores
BITTENCOURT, M. G.
LIU, H.
HANOUT, M.
SEPAH, Y. J.
DO, D. V.
NGUYEN, Q. D.
Citação
Bittencourt, M. G.; Ferraz, D. A.; Liu, H.; Hanout, M.; Sepah, Y. J.; Do, D. V.; Nguyen, Q. D.. Scanning laser ophthalmoscope fundus perimetry: The microperimetry. In: . OPHTHALMOLOGICAL IMAGING AND APPLICATIONS: CRC PRESS, 2014. p.333-354.
Projetos de Pesquisa
Unidades Organizacionais
Fascículo
Resumo
Visual perception is the ultimate outcome of a variety of discriminative functions of the visual system in which the macular function plays a great role. For many years, physicians relied on best-corrected visual acuity (VA) measurements and retinoscopy to assess macular dysfunction. It is well known, however, that VA cannot fully distinguish deterioration of macular function. Throughout the ophthalmic history, several clinical examinations were designed to aid in the assessment of the various aspects of the visual function. Some of them are still in use such as contrast sensitivity, reading speed, macular recovery function, low-luminance VA, and color acuity, among others. However, no other functional test has shown the same ability of localizing retinal function depression as perimetry does. © 2014 by Taylor & Francis Group, LLC.
Palavras-chave
URI
https://observatorio.fm.usp.br/handle/OPI/51185
Referências
  1. Anderson, D.R., (1987) Perimetry with and without Automation., , 2nd edn. St Louis, MO: Mosby
  2. Heijl, A., Patella, V., (2002) Essential Perimetry: The Field Analyzer Primer, , Dublin, CA: Carl Zeiss Meditec Inc
  3. Midena, E., Radin, P.P., Convento, E., Cavarzeran, F., Macular automatic fundus perimetry threshold versus standard perimetry threshold (2007) Eur J Ophthalmol, 17 (1), pp. 63-68
  4. Ratra, V., Ratra, D., Gupta, M., Vaitheeswaran, K., Comparison between Humphrey Field Analyzer and Micro Perimeter 1 in normal and glaucoma subjects (2012) Oman J Ophthalmol, 5 (2), pp. 97-102
  5. Johnson, C.A., Wall, M., Thompson, H.S., A history of perimetry and visual field testing (2011) Optom Vis Sci, 88 (1), pp. EE8-E15
  6. Meditec, C.Z., (2002) Perimetry brochure, , http://www.meditec.zeiss.com/88256DE3007B916B/0/2A853BEEDCDF977CC1257BEA004A7414/$file/effective_perimetry_the_field_analyzer_primer.pdf
  7. (2013) HAAG-STREIT Diagnostics, Switzerland, , http://www.haag-streit.com/products/perimetry/octopusr-900.html, accessed March
  8. Crossland, M.D., Engel, S.A., Legge, G.E., The preferred retinal locus in macular disease: Toward a consensus definition (2011) Retina, 31 (10), pp. 2109-2114
  9. Mainster, M.A., Timberla Ke, G.T., Webb, R.H., Hughes, G.W., Scanning laser ophthalmoscopy. Clinical applications (1982) Ophthalmology, 89 (7), pp. 852-857
  10. Subramanian, V., Jost, R.M., Birch, E.E., A quantitative study of fixation stability in amblyopia (2013) Invest Ophthalmol Vis Sci, 54 (3), pp. 1998-2003
  11. Andersen, M.V., Scanning laser ophthalmoscope microperimetry compared with Octopus perimetry in normal subjects (1996) Acta Ophthalmol Scand, 74 (2), pp. 135-139
  12. Menke, M.N., Sato, E., Van De Velde, F.J., Feke, G.T., Combined use of SLO microperimetry and OCT for retinal functional and structural testing (2006) Graefes Arch Clin Exp Ophthalmol, 244 (5), pp. 634-638
  13. Anastasakis, A., McAnany, J.J., Fishman, G.A., Seiple, W.H., Clinical value, normative retinal sensitivity values, and intrasession repeatability using a combined spectral domain optical coherence tomography/scanning laser ophthalmoscope microperimeter (2011) Eye (Lond), 25 (2), pp. 245-251
  14. Webb, R.H., Hughes, G.W., Scanning laser ophthalmoscope (1981) IEEE Trans Biomed Eng, 28 (7), pp. 488-492
  15. Midena, E., Radin, P.P., Pilotto, E., Ghirlando, A., Convento, E., Varano, M., Fixation pattern and macular sensitivity in eyes with subfoveal choroidal neovascularization secondary to age-related macular degeneration. A microperimetry study (2004) Semin Ophthalmol, 19 (1-2), pp. 55-61
  16. Rohrschneider, K., Springer, C., Bultmann, S., Volcker, H.E., Microperimetry—Comparison between the micro perimeter 1 and scanning laser ophthalmoscope—Fundus perimetry (2005) Am J Ophthalmol, 139 (1), pp. 125-134
  17. Steinman, R.M., Cushman, W.B., Martins, A.J., The precision of gaze. A review (1982) Hum Neurobiol, 1 (2), pp. 97-109
  18. Chen, F.K., Patel, P.J., Xing, W., Bunce, C., Egan, C., Tufail, A.T., Coffey, P.J., Da Cruz, L., Test-retest variability of microperimetry using the Nidek MP1 in patients with macular disease (2009) Invest Ophthalmol Vis Sci, 50 (7), pp. 3464-3472
  19. Rohrschneider, K., Fendrich, T., Becker, M., Krastel, H., Kruse, F.E., Volcker, H.E., Static fundus perimetry using the scanning laser ophthalmoscope with an automated threshold strategy (1995) Graefes Arch Clin Exp Ophthalmol, 233 (12), pp. 743-749
  20. Rohrschneider, K., Bethke-Jaenicke, C., Becker, M., Kruse, F.E., Blankenagel, A., Volcker, H.E., Fundus-controlled examination of reading in eyes with macular pathology (1996) Ger J Ophthalmol, 5 (5), pp. 300-307
  21. Varano, M., Scassa, C., Scanning laser ophthalmoscope microperimetry (1998) Semin Ophthalmol, 13 (4), pp. 203-209
  22. Fujii, G.Y., De Juan, E., Jr., Humayun, M.S., Sunness, J.S., Chang, T.S., Rossi, J.V., Characteristics of visual loss by scanning laser ophthalmoscope microperimetry in eyes with subfoveal choroidal neovascularization secondary to age-related macular degeneration (2003) Am J Ophthalmol, 136 (6), pp. 1067-1078
  23. Crossland, M.D., Culham, L.E., Rubin, G.S., Fixation stability and reading speed in patients with newly developed macular disease (2004) Ophthalmic Physiol Opt, 24 (4), pp. 327-333
  24. Nishida, Y., Murata, T., Yoshida, K., Sawada, T., Kani, K., An automated measuring system for fundus perimetry (2002) Jpn J Ophthalmol, 46 (6), pp. 627-633
  25. Shah, V.A., Chalam, K.V., Values for macular perimetry using the MP-1 microperimeter in normal subjects (2009) Ophthalmic Res, 41 (1), pp. 9-13
  26. Sawa, M., Gomi, F., Toyoda, A., Ikuno, Y., Fujikado, T., Tano, Y., A microperimeter that provides fixation pattern and retinal sensitivity measurement (2006) Jpn J Ophthalmol, 50 (2), pp. 111-115
  27. Midena, E., Vujosevic, S., Convento, E., Manfre, A., Cavarzeran, F., Pilotto, E., Microperimetry and fundus autofluorescence in patients with early age-related macular degeneration (2007) Br J Ophthalmol, 91 (11), pp. 1499-1503
  28. Crossland, M.D., Dunbar, H.M., Rubin, G.S., Fixation stability measurement using the MP1 microperimeter (2009) Retina, 29 (5), pp. 651-656
  29. Amore, F.M., Fasciani, R., Silvestri, V., Crossland, M.D., De Waure, C., Cruciani, F., Reibaldi, A., Relationship between fixation stability measured with MP-1 and reading performance (2013) Ophthalmic Physiol Opt, 33 (5), pp. 611-617
  30. Tarita-Nistor, L., Gonzalez, E.G., Markowitz, S.N., Steinbach, M.J., Plasticity of fixation in patients with central vision loss (2009) Vis Neurosci, 26 (5-6), pp. 487-494
  31. Landa, G., Rosen, R.B., Garcia, P.M., Seiple, W.H., Combined three-dimensional spectral OCT/SLO topography and microperimetry: Steps toward achieving functional spectral OCT/SLO (2010) Ophthalmic Res, 43 (2), pp. 92-98
  32. Sabates, F.N., Vincent, R.D., Koulen, P., Sabates, N.R., Gallimore, G., Normative data set identifying properties of the macula across age groups: Integration of visual function and retinal structure with microperimetry and spectral-domain optical coherence tomography (2011) Retina, 31 (7), pp. 1294-1302
  33. Hatef, E., Colantuoni, E., Wang, J., Ibrahim, M., Shulman, M., Adhi, F., Sepah, Y.J., Nguyen, Q.D., The relationship between macular sensitivity and retinal thickness in eyes with diabetic macular edema (2011) Am J Ophthalmol, 152 (3), pp. 400.e2–405.e2
  34. Kiernan, D.F., Mieler, W.F., Hariprasad, S.M., Spectral-domain optical coherence tomography: A comparison of modern high-resolution retinal imaging systems (2010) Am J Ophthalmol, 149 (1), pp. 18-31
  35. Rohrschneider, K., Bultmann, S., Springer, C., Use of fundus perimetry (Microperimetry) to quantify macular sensitivity (2008) Prog Retin Eye Res, 27 (5), pp. 536-548
  36. Yohannan, J., Bittencourt, M., Sepah, Y.J., Hatef, E., Sophie, R., Moradi, A., Liu, H., Coulantuoni, E., Association of retinal sensitivity to integrity of photoreceptor inner/outer segment junction in patients with diabetic macular edema (2013) Ophthalmology, 120 (6), pp. 1254-1261
  37. Sepah, Y.J., Hatef, E., Colantuoni, E., Wang, J., Shulman, M., Adhi, F.I., Akhtar, A., Channa, R., Macular sensitivity and fixation patterns in normal eyes and eyes with uveitis with and without macular edema (2012) J Ophthalmic Inflamm Infect, 2 (2), pp. 65-73
  38. (2009) Centervue S.P.A., Rome, Italy, , http://www.centervue.com/articms/admin/upAllegati/639/1342089423.pdf
  39. Vujosevic, S., Smolek, M.K., Lebow, K.A., Notaroberto, N., Pallikaris, A., Casciano, M., Detection of macular function changes in early (AREDS 2) and intermediate (AREDS 3) age-related macular degeneration (2011) Ophthalmologica, 225 (3), pp. 155-160
  40. Alexander, P., Mushtaq, F., Osmond, C., Amoaku, W., Microperimetric changes in neovascular age-related macular degeneration treated with ranibizumab (2012) Eye (Lond), 26 (5), pp. 678-683
  41. Woods, R.L., Vera-Diaz, F.A., Lichtenstein, L., Peli, E., Spatial alignment of microperimeters (2007) Invest Ophthalmol Vis Sci, 48 (5), p. 144
  42. Michael, D., Crossland, M.-L., Seiple, W.H., Microperimetry: A review of fundus related perimetry (2012) Optometry Reports 2012
  43. 2: E2, 2. , Edited by Institute I-E, Valladolid, Spain: University of Valladolid
  44. Vujosevic, S., Smolek, M.K., Lebow, K.A., Notaroberto, N., Pallikaris, A., Casciano, M., Detection of macular function changes in early (AREDS 2) and intermediate (AREDS 3) age-related macular degeneration (2011) Ophthalmologica, 225 (3), pp. 155-160
  45. Springer, C., Bultmann, S., Volcker, H.E., Rohrschneider, K., Fundus perimetry with the Micro Perimeter 1 in normal individuals: Comparison with conventional threshold perimetry (2005) Ophthalmology, 112 (5), pp. 848-854
  46. Schmitz-Valckenberg, S., Ong, E.E., Rubin, G.S., Peto, T., Tufail, A., Egan, C.A., Bird, A.C., Fitzke, F.W., Structural and functional changes over time in MacTel patients (2009) Retina, 29 (9), pp. 1314-1320
  47. Acton, J.H., Bartlett, N.S., Greenstein, V.C., Comparing the Nidek MP-1 and Humphrey field analyzer in normal subjects (2011) Optom Vis Sci, 88 (11), pp. 1288-1297
  48. Seiple, W., Rosen, R.B., Castro-Lima, V., Garcia, P.M., The physics and psychophysics of microperimetry (2012) Optom Vis Sci, 89 (8), pp. 1182-1191
  49. Liu, H., Agbedia, O., Moradi, A., Sepah, Y.J., Ferraz, D.F., Ibrahim, M.A., Sophie, R., Nguyen, Q.D., Longitudinal changes in retinal sensitivity among patients with maculopathy (2013) ARVO Meeting, , Seattle, WA, Program number: 5026
  50. Salvatore, S., Librando, A., Esposito, M., Vingolo, E.M., The Mozart effect in biofeedback visual rehabilitation: A case report (2011) Clin Ophthalmol, 5, pp. 1269-1272
  51. Midena, E., (2007) Microperimetry and the Fundus: An Introduction to Microperimetry, , Thorofare, NJ: SLACK Inc
  52. Crossland, M.D., Rubin, G.S., The use of an infrared eyetracker to measure fixation stability (2002) Optom Vis Sci, 79 (11), pp. 735-739
  53. Kosnik, W., Fikre, J., Sekuler, R., Visual fixation stability in older adults (1986) Invest Ophthalmol Vis Sci, 27 (12), pp. 1720-1725
  54. Culham, L., Fitzke, F.W., Timberlake, G.T., Marshall, J., Assessment of fixation stability in normal subjects and patients using a scanning laser ophthalmoscope (1993) Clin Vision Sci, 8, pp. 551-561
  55. Nachmias, J., Two-dimensional motion of the retinal image during monocular fixation (1959) Journal of the Optical Society of America, 49, pp. 901-908
  56. Schuchard, R.A., Raasch, T.W., Retinal locus for fixation: Pericentral fixation targets (1992) Clin Vision Sci, 7, pp. 511-520
  57. Acosta, F., Lashkari, K., Reynaud, X., Jalkh, A.E., Van De Velde, F., Chedid, N., Characterization of functional changes in macular holes and cysts (1991) Ophthalmology, 98 (12), pp. 1820-1823
  58. (2013) NIDEK TECHNOLOGIES Srl, , http://www.nidektechnologies.it/ProductsMP1All.htm, Rome, Italy. Rev.041115
  59. Gonzalez De La Rosa, M., Pareja, A., Influence of the “fatigue effect” on the mean deviation measurement in perimetry (1997) Eur J Ophthalmol, 7, pp. 29-34
  60. Cideciyan, A.V., Swider, M., Aleman, T.S., Feuer, W.J., Schwartz, S.B., Russell, R.C., Steinberg, J.D., Jacobson, S.G., Macular function in macular degenerations: Repeatability of microperimetry as a potential outcome measure for ABCA4-associated retinopathy trials (2012) Invest Ophthalmol Vis Sci, 53 (2), pp. 841-852
  61. Schmidt-Erfurth, U.M., Elsner, H., Terai, N., Benecke, A., Dahmen, G., Michels, S.M., Effects of verteporfin therapy on central visual field function (2004) Ophthalmology, 111 (5), pp. 931-939
  62. Rohrschneider, K., Gluck, R., Blankenagel, A., Volcker, H.E., Fixation behavior in Stargardt disease (1997) Ophthalmologe, 94 (9), pp. 624-628
  63. Ota, M., Tsujikawa, A., Ojima, Y., Miyamoto, K., Murakami, T., Ogino, K., Akagi-Kurashige, Y., Yoshimura, N., Retinal sensitivity after resolution of the macular edema associated with retinal vein occlusion (2012) Graefes Arch Clin Exp Ophthalmol, 250 (5), pp. 635-644
  64. Sjaarda, R.N., Frank, D.A., Glaser, B.M., Thompson, J.T., Murphy, R.P., Resolution of an absolute scotoma and improvement of relative scotomata after successful macular hole surgery (1993) Am J Ophthalmol, 116 (2), pp. 129-139
  65. Hikichi, T., Ishiko, S., Takamiya, A., Sato, E., Mori, F., Takahashi, M., Yanagiya, N., Yoshida, A., Scanning laser ophthalmoscope correlations with biomicroscopic findings and foveal function after macular hole closure (2000) Arch Ophthalmol, 118 (2), pp. 193-197
  66. Ergun, E., Maar, N., Radner, W., Barbazetto, I., Schmidt-Erfurth, U., Stur, M., Scotoma size and reading speed in patients with subfoveal occult choroidal neovascularization in age-related macular degeneration (2003) Ophthalmology, 110 (1), pp. 65-69
  67. Richter-Mueksch, S., Vecsei-Marlovits, P.V., Sacu, S.G., Kiss, C.G., Weingessel, B., Schmidt-Erfurth, U., Functional macular mapping in patients with vitreomacular pathologic features before and after surgery (2007) Am J Ophthalmol, 144 (1), pp. 23-31
  68. Muller, S., Ehrt, O., Gundisch, O., Eckl-Titz, G., Scheider, A., Functional results after surgical extraction or photocoagulation of choroid neovascularization (CNV) in age-related macular degeneration (2000) Ophthalmologe, 97 (2), pp. 142-146
  69. Joussen, A.M., Heussen, F.M., Joeres, S., Llacer, H., Prinz, B., Rohrschneider, K., Maaijwee, K.J., Kirchhof, B., Autologous translocation of the choroid and retinal pigment epithelium in age-related macular degeneration (2006) Am J Ophthalmol, 142 (1), pp. 17-30
  70. Ozdemir, H., Karacorlu, S.A., Senturk, F., Karacorlu, M., Uysal, O., Assessment of macular function by microperimetry in unilateral resolved central serous chorioretinopathy (2008) Eye (Lond), 22 (2), pp. 204-208

Coleções
Livros e Capítulos de Livros - FM/Outros
Livros e Capítulos de Livros - LIM/33