Humphrey Field Analyzer II-
i
series User Manual 2660021145640 A
Short-Wavelength Automated Perimetry (SWAP)
9-15
SWAP References
1. Ng M, Racette L, Pascual JP, Liebmann JM, Girkin CA, Lovell SL, Zangwill LM, Weinreb RN,
Sample PA. Comparing the full-threshold and Swedish interactive thresholding algorithms for
short-wavelength automated perimetry.
Invest Ophthalmol Vis Sci
. 2009 Apr;50(4):1726-33.
2. Bengtsson B, Heijl A. Diagnostic sensitivity
of fast blue-yellow and standard automated
perimetry in early glaucoma: a comparison between different test programs.
Ophthalmology
.
2006 Jul;113(7):1092-7.
3. Han Y, Adams AJ, Bearse MA Jr, Schneck ME. Multifocal electroretinogram and
short-
wavelength automated perimetry measures in diabetic eyes with little or no retinopathy.
Arch Ophthalmol
. 2004 Dec;122(12):1809-15.
4. Sanchez-Galeana CA, Bowd C, Zangwill LM, Sample
PA, Weinreb RN. Short-wavelength
automated perimetry results are correlated with optical coherence tomography retinal nerve
fiber layer thickness measurements in glaucomatous eyes.
Ophthalmology
. 2004
Oct.;111(10):1866-72.
5. Eisner A, Austin DF, Samples JR. Short-waveleng
th automated perimetry and tamoxifen use.
Br
J Ophthalmol
. 2004 Jan.;88(1):125-30.
6. Bengtsson B, Heijl A. Normal intersubject thr
eshold variability and normal limits of the
SITA-SWAP and full threshold SWAP perimetric programs.
Invest Ophthalmol Vis Sci.
2003
Nov.;44(11):5029-34.
7. Bengtsson B. A new rapid threshold algorithm for
short-wavelength automated perimetry.
Invest Ophthalmol Vis Sci
. 2003 Mar.;44(3):1388-94.
8. Mok KH, Lee VW, So KF. Retinal nerve fiber layer measur
ement by optical coherence
tomography in glaucoma suspects with short-wavelength perimetry abnormalities.
J
Glaucoma
. 2003 Feb.;12(1):45-9.
9. Bayer AU, Erb C. Short wavelength automated perimetry
, frequency doubling technology
perimetry, and pattern electroretinography for prediction of progressive glaucomatous
standard visual field defects.
Ophthalmology
. 2002 May;109(5):1009-17.
10.Polo V, Larrosa JM, Pinilla I, Perez S, Gonzalvo F
, Honrubia FM. Predictive value of
short-wavelength automated perimetry: a 3-year follow-up study.
Ophthalmology
. 2002
Apr.;109(4):761-5.
11.Remky A, Lichtenberg K, Elsner AE, Arend O. Short-w
avelength automated perimetry in age
related maculopathy.
Br J Ophthalmol
. 2001 Dec.;85(12):1432-6.
12.Hudson C, Flanagan JG, Turner GS, Chen HC, Y
oung LB, McLeod D. Short-wavelength sensitive
visual field loss in patients with clinically significant diabetic macular oedema.
Diabetologia
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1998 Aug.;41(8):918-28.
13.Sample PA, Johnson CA, Haegerstrom-Portnoy G, Adams
AJ: The optimum parameters for
short-wavelength automated perimetry.
J Glauc
. 1996; 5:6, 375-383.
14.Johnson CA, Brandt JD, Khong AM, Adams AJ: Short-wavelength automated perimetry
in
low-, medium-, and high-risk ocular hypertensive eyes.
Arch. Ophth
. 1995 Jan.; 113:70-76.
15.Keltner JL, Johnson CA: Short-wavelength automated perimetry in
neuro-ophthalmologic
disorders.
Arch. Ophthalmol
. 1995 April; 113:475-481.
16.Sample PA, Martinez GA, Weinreb RN: Short-w
avelength automated perimetry without lens
density testing.
A. J. Ophth
, 1994 Nov.; 118(5):632-41.
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