DAFTAR LAMPIRAN

Premis 6: Optical Coherence Tomography Angiografi dapat mendeteksi perubahan mikrovaskular sampai tahap kapiler secara non invasif pada kepala

5.2 Saran

58

BAB V

SIMPULAN DAN SARAN

59

DAFTAR PUSTAKA

1. International Council of Ophthalmology. Update 2017 ICO Guidelines for Diabetic Eye Care. Int Counc Ophthalmol. 2017;1–34.

2. Flaxman SR, Bourne RR, Resnikoff S, Ackland P, Braithwaite T, Cicinelli MV, Das A, Jonas JB, Keeffe J, Kempen JH, Leasher J. Global causes of blindness and distance vision impairment 1990–2020: a systematic review and meta-analysis. The Lancet Global Health. 2017;5(12):e1221-34.

3. Didik Budijanto, Rudy Kurniawan, Kurniasih N, Khairani. InfoDatin : Hari Diabetes Sedunia tahun 2018. Kementeri Kesehat RI Pus Data Dan Inf.

2018;1–8.

4. American Academy of Ophthalmology Retina/Vitreous Panel. Preferred Practice Pattern®Guidelines. Diabetic Retinopathy. San Francisco, CA:

American Academy of Ophthalmology; 2017.

5. Sasongko MB, Widyaputri F, Agni AN, Wardhana FS, Kotha S, Gupta P, Widayanti TW, Haryanto S, Widyaningrum R, Wong TY, Kawasaki R.

Prevalence of diabetic retinopathy and blindness in Indonesian adults with type 2 diabetes. American journal of ophthalmology. 2017;181:79-87.

6. Gardner TW, Davila JR. The neurovascular unit and the pathophysiologic basis of diabetic retinopathy. Graefe’s Archive for Clinical and Experimental Ophthalmology. 2017;255(1):1-6.

7. Lechner J, O’leary OE, Stitt AW. The pathology associated with diabetic retinopathy. Vision research. 2017;139:7-14.

8. Chen X, Nie C, Gong Y, Zhang Y, Jin X, Wei S, Zhang M. Peripapillary retinal nerve fiber layer changes in preclinical diabetic retinopathy: a meta- analysis. PloS one. 2015;10(5):e0125919.

9. Liu L, Wang Y, Liu HX, Gao J. Peripapillary Region Perfusion and Retinal Nerve Fiber Layer Thickness Abnormalities in Diabetic Retinopathy Assessed by OCT Angiography. Translational vision science & technology.

2019;8(4):1-9.

10. She X, Guo J, Liu X, Zhu H, Li T, Zhou M, Wang F, Sun X. Reliability of vessel density measurements in the peripapillary retina and correlation with retinal nerve fiber layer thickness in healthy subjects using optical coherence tomography angiography. Ophthalmologica. 2018;240(4):183-90.

11. American Academy of Ophthalmology. Basic and Clinical Science Course : Retina and Vitreous. American Academy of Ophthalmology; 2016.

12. Nadia K. Waheed, Amir H. Kashani, Carlos Alexandre de Amorim Garcia Filho, Jay S. Duker, Philip J. Rosenfeld. Retinal Imaging and Diagnostics : Optical Coherence Tomography. In: Ryan’s Retina. edisi 6. China: Elsevier Inc; 2018. 77–9, 102–6.

13. Qi ZH, Li YW, Na WX, Sheng YQ, Di CZ, Chen XI, Yu ZM, Jun LD, Yang WZ, Wei CH, Feng LY. Repeatability and reproducibility of quantitative assessment of the retinal microvasculature using optical coherence tomography angiography based on optical microangiography. Biomedical and Environmental Sciences. 2018;31(6):407-12.

14. Chen CL, Bojikian KD, Xin C, Wen JC, Gupta D, Zhang Q, Mudumbai RC, Johnstone MA, Chen PP, Wang RK. Repeatability and reproducibility of optic nerve head perfusion measurements using optical coherence tomography angiography. Journal of biomedical optics. 2016;21(6):065002.

15. American Academy of Ophthalmology. Basic and Clinical Science Course : Fundamentals and Principles of Ophthalmology. American Academy of Ophthalmology; 2016.

16. American Academy of Ophthalmology. Basic and Clinical Science Course : Glaucoma. In American Academy of Ophthalmology; 2016. p. 23–4.

17. American Academy of Ophthalmology. Basic and Clinical Science Course : Neuro-Ophthalmology. American Academy of Ophthalmology; 2016.

18. Vujosevic S, Muraca A, Gatti V, Masoero L, Brambilla M, Cannillo B, Villani E, Nucci P, De Cillà S. Peripapillary microvascular and neural changes in diabetes mellitus: an OCT-Angiography study. Investigative Ophthalmology

& Visual Science. 2018;59(12):5074-81.

19. Mase T, Ishibazawa A, Nagaoka T, Yokota H, Yoshida A. Radial peripapillary capillary network visualized using wide-field montage optical coherence tomography angiography. Investigative ophthalmology & visual science.

2016;57(9):504-10.

20. Cao D, Yang D, Yu H, Xie J, Zeng Y, Wang J, Zhang L. Optic nerve head perfusion changes preceding peripapillary retinal nerve fibre layer thinning in preclinical diabetic retinopathy. Clinical & experimental ophthalmology.

2019;47(2):219-25.

21. Barber AJ. Diabetic retinopathy: recent advances towards understanding neurodegeneration and vision loss. Science China Life Sciences.

2015;58(6):541-9.

22. Victor AA. Optic Nerve Changes in Diabetic Retinopathy. IntechOpen.

2018:85-103.

23. Carmen A. Puliafito, Michael R. Hee, Joel S. Schuman, James G. Fujimoto.

Optical Coherence Tomography of Ocular Diseases. edisi 3. Slack Incorporated; 2012.

24. CIRRUS HD-OCT from ZEISS : How to read the reports. Dublin, USA: Carl Zeiss Meditec, Inc.

25. Yang HS, Woo JE, Kim M, Kim DY, Yoon YH. Co-Evaluation of Peripapillary RNFL Thickness and Retinal Thickness in Patients with Diabetic Macular Edema: RNFL Misinterpretation and Its Adjustment. Plos One.

2017;12:1–13.

26. Shi R, Guo Z, Wang F, Li R, Lin R, Zhao L. Alterations in retinal nerve fiber layer thickness in early stages of diabetic retinopathy and potential risk factors. Curr Eye Res. 2017;1–10.

27. El-Hifnawy MAM, Sabry KM, Gomaa AR, Hassan TA. Effect of diabetic retinopathy on retinal nerve fiber layer thickness. Delta J Ophthalmol.

2016;17:162–6.

28. Yu J, Gu R, Zong Y, Xu H, Wang X, Sun X, Jiang C, Xie B, Jia Y, Huang D.

Relationship between retinal perfusion and retinal thickness in healthy

subjects: an optical coherence tomography angiography study. Investigative ophthalmology & visual science. 2016;57(9):204-10.

29. Agemy SA, Scripsema NK, Shah CM, Chui T, Garcia PM, Lee JG, Gentile RC, Hsiao YS, Zhou Q, Ko T, Rosen RB. Retinal vascular perfusion density mapping using optical coherence tomography angiography in normals and diabetic retinopathy patients. Retina. 2015;35(11):2353-63.

30. Ivania Pereira, Stephanie Weber, Stephan Holzer, Georg Fischer, Clemens Vass, Hemma Resch. Compensation for Retinal Vessel Density Reduces the Variation of Circumpapillary RNFL in Healthy Subjects. Plos One. 2015;1–

10.

31. Terrance Siew. Cirrus Ver 11 : Angioplex for the Optic Nerve Head. Zeiss.

32. Mihardja L, Soetrisno U, Soegondo S. Prevalence and clinical profile of diabetes mellitus in productive aged urban Indonesians. Journal of diabetes investigation. 2014;5(5):507-12.

33. Shin YI, Nam KY, Lee SE, Lee MW, Lim HB, Jo YJ, Kim JY. Peripapillary microvasculature in patients with diabetes mellitus: an optical coherence tomography angiography study. Scientific reports. 2019;9(1):1-0.

34. Moran EP, Wang Z, Chen J, Sapieha P, Smith LE, Ma JX. Neurovascular cross talk in diabetic retinopathy: pathophysiological roles and therapeutic implications. American Journal of Physiology-Heart and Circulatory Physiology. 2016;311(3):738-49.

35. Araszkiewicz A, Zozulinska-Ziolkiewicz D. Retinal Neurodegeneration in the Course of Diabetes-Pathogenesis and Clinical Perspective. Bentham Sci Publ.

2016;14:805–9.

36. Rodrigues TM, Marques JP, Soares M, Dolan MJ, Melo P, Simão S, Teles J, Figueira J, Murta JN, Silva R. Peripapillary neurovascular coupling in the early stages of diabetic retinopathy. Retina. 2019;39(12):2292-302.

37. Li Z, Wen X, Zeng P, Liao Y, Fan S, Zhang Y, Li Y, Xiao J, Lan Y. Do microvascular changes occur preceding neural impairment in early-stage diabetic retinopathy? Evidence based on the optic nerve head using optical coherence tomography angiography. Acta diabetologica. 2019;56(5):531-9.

38. Pechauer AD, Jia Y, Liu L, Gao SS, Jiang C, Haung D. Optical Coherence Tomography Angiography of Peripapillary Retinal Blood Flow Response to Hyperoxia. Investigative ophthalmology & visual science. 2015;56(5):3287- 91.

39. Lott MEJ, Slocomb JE, Shivkumar V, Smith B, Gabbay RA, Quillen D, et al.

Comparison of retinal vasodilator and constrictor responses in type 2 diabetes.

Acta Ophthalmol (Copenh). 2012;90(6):434–41.

40. Vujosevic S, Midena E. Retinal Layers Changes in Human Preclinical and Early Clinical Diabetic Retinopathy Support Early Retinal Neuronal and Müller Cells Alterations. Hindawi Publ Corp. 2013;2013:1–8.

41. Hille W. van Dijk, Frank D. Verbraak, Pauline H. B. Kok, Marilette Stehouwer, Mona K. Garvin, Milan Sonka, et al. Early Neurodegeneration in the Retina of Type 2 Diabetic Patients. Assoc Res Vis Ophthalmol Inc.

2012;53:2715–9.

42. Mehboob MA, Amin ZA, Islam QU. Comparison of retinal nerve fiber layer thickness between normal population and patients with diabetes mellitus using optical coherence tomography. Pakistan Journal of Medical Sciences.

2019;35(1):29.

43. Hafner J, Ginner L, Karst S, Leitgeb R, Unterluggauer M, Sacu S, Mitsch C, Scholda C, Pablik E, Schmidt-Erfurth U. Regional patterns of retinal oxygen saturation and microvascular hemodynamic parameters preceding retinopathy in patients with type II diabetes. Investigative ophthalmology & visual science. 2017;58(12):5541-7.

Lampiran 1

Lampiran 2

Lampiran 3

3 OD AGT 43 L 120/90 16 130 77 131 71 102 41,8 41,2 42,3 44,9 42,6 0,402 0,386 0,406 0,422 0,405 4 OS AGT 43 L 20 130 67 130 66 98 41,8 40 42,7 44,5 42,2 0,397 0,385 0,403 0,403 0,397 5 OD LIN 45 P 120/80 18 115 74 131 67 97 45,1 42,8 45,3 44,3 44,4 0,417 0,402 0,418 0,454 0,425 6 OS LIN 45 P 15 135 78 146 58 104 44,2 42,2 46,1 44,8 44,3 0,413 0,386 0,411 0,449 0,415 7 OD UTP 47 L 120/80 18 91 59 114 62 82 42,2 41,2 45,6 44,4 43,3 0,418 0,418 0,424 0,419 0,42 8 OS UTP 47 L 19 101 57 111 56 81 44,9 39,1 46,2 45,4 43,8 0,415 0,419 0,435 0,453 0,431 9 OD TET 47 P 120/80 16 127 78 132 79 104 43,3 45,3 46,8 44,9 45 0,388 0,372 0,382 0,374 0,379 10 OS TET 47 P 20 122 81 147 65 104 45,9 43,3 44,3 50,3 46 0,402 0,405 0,407 0,429 0,412 11 OD CND 48 L 110/80 13 136 85 146 73 110 43,7 45,5 45,4 46,2 45,2 0,425 0,44 0,422 0,429 0,429 12 OS CND 48 L 14 138 85 142 70 109 47,1 45,7 44,6 49,3 46,7 0,429 0,41 0,417 0,437 0,424 13 OD INH 49 P 120/70 17 117 64 124 68 93 41,9 41,6 44,3 46,2 43,6 0,43 0,385 0,42 0,471 0,429 14 OS INH 49 P 17 122 64 120 64 93 42,8 41,2 46,6 46 44,1 0,433 0,431 0,437 0,468 0,443 15 OD RDW 50 L 110/70 11 135 71 115 77 99 43,5 42,3 44,7 46,7 44,4 0,423 0,407 0,416 0,475 0,433 16 OS RDW 50 L 9 142 63 116 70 98 43,5 42,2 44,7 44,7 43,8 0,426 0,414 0,425 0,48 0,438 17 OD BLD 51 P 110/80 12 124 71 143 66 101 42,5 44,2 44 45,8 44,3 0,4 0,412 0,414 0,456 0,425 18 OS BLD 51 P 14 128 76 140 65 102 42,5 40,3 45,7 45,7 43,7 0,428 0,421 0,427 0,478 0,441 19 OD PPN 51 P 150/90 15 121 75 155 58 103 41 43,8 43,8 47,3 44 0,428 0,415 0,426 0,462 0,434 20 OS PPN 51 P 15 133 66 131 57 97 42,9 43 44,3 47,6 44,5 0,424 0,406 0,438 0,444 0,429 21 OD NEN 53 P 120/80 19 153 97 161 62 118 42,6 45,1 45,2 50 46 0,419 0,42 0,439 0,463 0,438 22 OS NEN 53 P 20 118 78 148 72 104 43,1 42,6 43 48,6 44,3 0,438 0,418 0,419 0,459 0,434 23 OD YUD 53 P 130/80 17 114 73 137 75 100 40,9 42,3 43,9 46,5 43,5 0,404 0,404 0,412 0,443 0,417 24 OD TAT 54 P 120/80 14 101 80 135 63 95 41 43,5 45,4 47,1 44,3 0,406 0,371 0,393 0,422 0,4 25 OS TAT 54 P 12 123 88 129 64 101 44,1 45,5 44,8 49,2 46,1 0,424 0,39 0,427 0,468 0,429 26 OD IDA 55 P 120/80 13 118 79 134 58 97 43,4 42,5 48,5 44,9 44,7 0,438 0,444 0,45 0,427 0,44 27 OS IDA 55 P 13 122 72 115 69 95 47,7 44,6 47,3 44 45,8 0,442 0,48 0,444 0,417 0,446 28 OD EPN 55 p 120/70 13 116 58 125 67 92 44,5 42,4 45,3 47,7 45,1 0,422 0,377 0,418 0,464 0,423 29 OS EPN 55 P 13 114 54 114 70 88 43 37,4 43,5 45,9 42,4 0,422 0,394 0,417 0,453 0,424 30 OD DDH 56 P 120/80 16 131 75 130 68 101 43,1 44,1 43,6 47,8 44,8 0,385 0,371 0,407 0,455 0,409 31 OS DDH 56 P 14 113 59 103 65 85 44,4 42,7 41,8 46,8 44 0,4 0,369 0,392 0,413 0,394 32 OD WWN 56 l 130/80 17 100 68 116 74 90 40,1 40,9 42,3 44,8 42 0,417 0,391 0,418 0,467 0,425 33 OS WWN 56 L 17 137 67 118 66 97 39,1 42,3 41,3 45,1 42,1 0,407 0,398 0,406 0,393 0,4 34 OD HER 57 L 120/80 15 122 91 135 72 105 43,1 40,9 43,7 46,3 43,6 0,406 0,403 0,41 0,471 0,425 35 OS HER 57 L 12 141 91 126 74 108 42,6 40,6 44,1 46,9 43,5 0,425 0,419 0,415 0,476 0,435 36 OD AKE 64 L 140/90 18 135 66 129 68 100 44,3 43 42,4 48,7 44,5 0,392 0,367 0,388 0,414 0,39 37 OS AKE 64 L 17 132 62 124 68 96 42,9 43,9 46,9 48,6 45,5 0,367 0,349 0,387 0,391 0,374

iran 4pok A 68

2 OS IMS 43 P 15 142 68 132 57 100 41,6 38,4 43,8 43,9 41,9 0,423 0,411 0,434 0,483 0,439 3 OD RBU 45 P 120/80 0,1 10,8 18 110 67 111 102 98 43,5 43,8 42,2 48,4 44,5 0,365 0,388 0,404 0,383 0,384

4 OS RBU 45 P 19 111 64 138 79 98 43 44,1 44,1 47,7 44,8 0,37 0,331 0,368 0,386 0,364

5 OD EUS 46 P 120/80 2,5 9,7 19 112 72 113 69 92 41,4 42,7 42,9 47,7 43,8 0,352 0,355 0,334 0,35 0,348

6 OS EUS 46 P 18 123 73 114 65 94 45,9 45,3 44,4 47,8 45,9 0,396 0,398 0,391 0,414 0,4

7 OD YSH 47 P 120/80 6 7,6 21 140 73 121 70 101 44,9 44,5 45,3 49,6 46,2 0,399 0,364 0,402 0,44 0,405

8 OS YSH 47 P 21 148 65 138 72 106 43,8 41,3 45,9 49,6 45,2 0,416 0,382 0,425 0,485 0,431

9 OD DER 48 P 120/80 4 10 16 124 70 145 77 104 44,1 42,5 46,3 46,1 44,8 0,388 0,386 0,404 0,392 0,393

10 OS DER 48 P 12 130 63 135 72 100 42,7 43,5 45,5 45,6 44,4 0,395 0,369 0,405 0,434 0,402

11 OD RAT 48 P 150/90 5 11,2 20 105 55 127 72 90 39,5 41 44,1 42,7 41,9 0,397 0,344 0,412 0,461 0,41

12 OS RAT 48 P 18 120 64 103 89 94 37,5 38,7 39,7 44,9 40,2 0,395 0,406 0,385 0,339 0,379

13 OS AAA 50 P 130/80 5 9 18 111 71 111 76 92 38 40,3 43,1 44,3 41,5 0,382 0,339 0,405 0,392 0,379

14 OD LLH 50 P 125/70 0,3 12,4 18 119 76 124 64 96 42,8 45,4 41,7 50,1 45 0,344 0,357 0,36 0,376 0,359

15 OS LLH 50 P 17 115 68 136 63 95 40 44,7 43 49,3 44,2 0,372 0,331 0,382 0,434 0,38

16 OD GUD 52 L 150/90 3 7,1 15 53 56 74 50 58 29,8 36,5 35,2 42,4 36,3 0,357 0,345 0,385 0,413 0,379

17 OS GUD 52 L 20 80 57 59 61 64 37,4 35,6 31 43,5 36,9 0,391 0,339 0,356 0,41 0,376

18 OD ERU 54 P 120/70 4 7,5 14 131 66 138 85 105 43,3 46,7 44,7 46,4 45,3 0,395 0,358 0,372 0,363 0,371

19 OS ERU 54 P 16 130 66 137 79 103 51,1 47 52,6 44,1 48,2 0,349 0,303 0,378 0,353 0,347

20 OD ERO 54 P 120/80 5 8,9 13 100 85 128 86 100 38,6 42,5 43,2 44 42,1 0,334 0,341 0,352 0,312 0,334

21 OS ERO 54 P 12 119 76 125 80 100 39,8 42,7 45,7 45,6 43,5 0,355 0,349 0,385 0,358 0,362

22 OD ABH 54 L 130/80 3 8,6 14 120 82 130 73 101 38,5 43,5 42,3 47,2 43 0,319 0,3 0,333 0,332 0,322

23 OS ABH 54 L 16 125 76 130 74 101 42 42,2 43,9 47,1 44,1 0,425 0,391 0,421 0,466 0,431

24 OD IML 54 P 130/90 5 10,4 20 143 82 151 79 114 43,3 43,5 44,2 44,9 44,1 0,418 0,395 0,414 0,421 0,414

25 OS IML 54 P 18 154 71 115 79 105 42,7 41,3 40,4 42,7 41,9 0,415 0,417 0,404 0,378 0,402

26 OD RIN 55 P 120/80 5 9 14 127 66 125 82 100 43,3 41,9 39,2 49,1 43,5 0,382 0,39 0,395 0,397 0,392

27 OS RIN 55 P 14 142 85 135 75 109 42,8 39,2 43 49,7 43,5 0,421 0,398 0,413 0,431 0,416

28 OS AIN 55 P 120/70 8 8,8 21 165 91 165 92 128 44,5 42,2 42,1 48,2 44,5 0,452 0,459 0,458 0,47 0,461

29 OD EUK 55 P 140/80 3 7,3 15 126 75 120 77 100 44,9 46,1 42,8 46,7 45,2 0,369 0,348 0,393 0,374 0,37

30 OS EUK 55 P 14 128 68 127 74 99 43,8 42,7 42,7 46,8 44,1 0,372 0,387 0,412 0,363 0,382

31 OD SUS 56 P 120/80 4 6,3 14 131 79 151 63 106 45,8 42,8 43,5 47,4 45 0,399 0,411 0,414 0,411 0,409

32 OS SUS 56 P 13 127 84 140 65 104 45,6 45,9 44,3 48,7 46,3 0,406 0,415 0,419 0,433 0,419

33 OD CEW 57 L 120/80 5 7,9 13 132 82 113 70 99 37,1 37,5 37,6 42,4 38,8 0,364 0,33 0,382 0,381 0,365

34 OS CEW 57 L 14 132 89 122 63 101 38,4 37,8 36,7 49,4 40,7 0,368 0,342 0,356 0,397 0,368

35 OD ILA 57 P 120/80 7 11,8 19 146 74 126 83 107 44,2 47,2 44 47,2 45,7 0,433 0,439 0,428 0,44 0,435

36 OS ILA 57 P 19 152 69 143 59 106 45,9 41,7 46,1 44,9 44,5 0,435 0,44 0,451 0,492 0,457

37 OD EYU 57 P 120/80 3 6,2 13 140 86 129 68 106 43,3 43,2 40,8 48,4 44,1 0,393 0,333 0,354 0,365 0,362

38 OS EYU 57 P 14 134 79 131 64 102 41,9 39,9 42 45,1 42,3 0,41 0,382 0,418 0,442 0,415

39 OD WAS 61 L 130/80 6 6,8 17 127 75 117 75 98 43,3 46 41,5 47,3 44,6 0,314 0,309 0,34 0,348 0,329

40 OS WAS 61 L 16 132 65 113 70 95 40 42,5 44,2 45,7 43,2 0,315 0,362 0,351 0,316 0,336

41 OD MSY 63 L 120/90 16 9,3 14 91 53 98 57 75 36,5 38,6 36,7 41,9 38,6 0,36 0,307 0,345 0,377 0,349

42 OS MSY 63 L 16 100 57 82 64 76 43,7 36,4 37,7 45,3 40,8 0,354 0,321 0,35 0,353 0,345

mpok B 69

Lampiran 5

RAT

RAT

RAT

RBU

RBU

RBU

IDA

IDA

IDA

Lampiran 6

Tests of Normality

Kelompok Kolmogorov-Smirnov^a Shapiro-Wilk Statistic df Sig. Statistic df Sig.

RNFL S Quadrant Kontrol .087 37 .200^* .971 37 .422

No DR .128 42 .079 .933 42 .017

RNFL NQuadrant Kontrol .087 37 .200^* .973 37 .492

No DR .073 42 .200^* .980 42 .676

RNFL I Quadrant Kontrol .089 37 .200^* .982 37 .783

No DR .139 42 .039 .916 42 .004

RNFL T Quadrant Kontrol .082 37 .200^* .978 37 .660

No DR .091 42 .200^* .983 42 .770

RNFL Total Thickness

Kontrol .107 37 .200^* .972 37 .465

No DR .208 42 .000 .823 42 .000

*. This is a lower bound of the true significance.

a. Lilliefors Significance Correction

Nonparametric Tests