HIGHLIGHTS
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Thin and ultrathin DSAEKs (T/UT-DSAEKs) were developed to increase the visual outcomes of DSAEK, retaining their technical accessibility.
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Conducting a systematic review and meta-analysis on postoperative outcomes of T/UT-DSAEK stratified by graft thickness (<80 μm, 80-100 μm, and 100-130 μm), we included 47 articles (2141 eyes from 2040 patients).
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We showed that T/UT-DSAEK globally improved postoperative outcomes, without difference depending on graft thickness.
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Performing the first meta-analysis on T/UT-DSAEK, we showed that visual acuity, pachymetry, endothelial cell count, and rejection and rebubbling rates were similar regardless of graft thickness.
Purpose
To conduct a systematic review and meta-analysis on the efficacy of thin and ultrathin Descemet stripping automated endothelial keratoplasty (T-DSAEK and UT-DSAEK, with graft thickness <130 and <100 µm, respectively), depending on graft thickness.
Design
Systematic review and meta-analysis.
Method
PubMed, Cochrane Library, Embase, ClinicalTrials.gov, and ScienceDirect databases were searched until October 1, 2021. We computed random-effect meta-analysis on postoperative outcomes of T/UT-DSAEK, stratified by graft thickness (<80 μm, 80-100 μm, and 100-130 μm). The main postoperative outcome was visual acuity (logarithm of the minimum angle of resolution [logMAR]). Secondary outcomes were pachymetry (μm), endothelial cell count (cell/mm 2 ), spherical equivalent (diopter [D]), rebubbling rate (%), and rejection rate (%). Meta-regressions compared postoperative outcomes depending on graft thickness and search for putative confusion factors.
Results
We included 47 articles for a total of 2141 eyes of 2040 patients. T/UT-DSAEK globally improved visual acuity (effect size = −0.38 logMAR [95% confidence interval {CI} −0.46 to −0.30 logMAR]), without difference depending on graft thickness. Overall, pachymetry improved (−60.6 µm [95% CI −101 to −19.7 µm]), endothelial cell count decreased (−1039 cells/mm 2 [95% CI −1209 to −868 cells/mm 2 ), spherical equivalent resulted in a hyperopic shift (0.74 D [95% CI −0.50 to 1.97 D), the graft rejection rate was 0.2% (95% CI −0.1% to 0.4%), and the rebubbling rate was 8.7% (95% CI 6.8%-10.5%). Grafts >100 μm induced a hyperopic shift. Metaregressions did not demonstrate differences between the 3 groups (<80 μm, 80-100 μm, or 100-130 μm) in any outcomes.
Conclusion
All T/UT-DSAEK thickness groups provided similar visual acuity, pachymetry, endothelial cell count, rejection rate, and rebubbling rate regardless of graft thickness. A hyperopic shift was induced by grafts >100 μm.
E ndothelial keratoplasty (EK) is becoming the criterion standard surgery for the treatment of endothelial corneal failure, replacing penetrating keratoplasty. Descemet stripping automated EK (DSAEK), with corneal endothelium and Descemet membrane being grafted with a thin layer of donor stroma, , currently remains the most performed EK in both the United States and Europe. , Recently, interesting results highlighted that DSAEK with grafts thinner than 130 µm could involve better postoperative visual acuity, suggesting relationships between graft thickness and visual outcomes. Thereby, thin and ultrathin DSAEK (T/UT-DSAEK) (ie, DSAEK with graft thickness <130 µm 7 ) were developed to increase the visual outcomes of DSAEK and to maintain their technical accessibility. , Further studies supported these findings while showing a similar complication rate and endothelial cell loss to DSAEK. , However, the link between graft thickness and visual outcomes is not consistent, which could therefore question the pertinence of T/UT-DSAEK. Most of the published results relate to grafts generally >100 µm. , , Currently, no data are available for grafts <100 µm. Thus, to assess the influence of graft thickness within T/UT-DSAEK grafts, we conducted a systematic review and meta-analysis on the efficacy of T/UT-DSAEK on postoperative outcomes (ie, visual acuity, pachymetry, cell count, spherical equivalent, and rebubbling and rejection rates), depending on the graft thickness.
METHODS
LITERATURE SEARCH
We searched for articles in PubMed, Cochrane Library, ScienceDirect, Embase, and ClinicalTrial.gov databases until October 1, 2021 with the following keywords: Descemet*
OR endothelial keratoplasty OR DSAEK OR DSEK AND thickness OR thin OR ultrathin OR
UT-DSAEK (details of search strategy used within each database are presented in Appendix 1). The search was not limited to specific years. No language restrictions were applied. We imposed no limitation on sample size or regional origin. To be included, articles had to report clinical outcomes (ie, visual acuity, pachymetry, endothelial cell count, spherical equivalent, or rebubbling or rejection rates) of T/UT DSAEK, defined as DSAEK with preoperative graft thicknesses <130 µm and <100 µm, respectively. Animal studies were excluded. In addition, references of all publications meeting the inclusion criteria were manually searched to identify any further studies. The search strategy is presented in Figure 1 . Two authors (L.B., V.N.) conducted literature searches, collated and separately reviewed the abstracts and, based on the selection criteria, decided the suitability of the articles for inclusion. A third author (F.D.) was asked to review the articles where consensus on suitability was debated. We followed the Preferred Reporting Items for Systematic Reviews and Meta-Analyses guidelines (Appendix 2).
DATA COLLECTION
The data collected included first author’s name, publication year, country, study design, aims, outcomes of included articles, inclusion and exclusion criteria, sample size, number of eyes, age, percentage of males, endothelial disease, graft cutting technique, type of surgery (simple or triple EK), characteristics of donors (age, sex), measurement time, central graft thickness, central corneal thickness, spherical equivalent, best spectacle-corrected visual acuity, endothelial cell count, graft rejection rate, and rebubbling rate.
OUTCOMES
The primary outcome was best spectacle-corrected visual acuity (logMAR). Secondary outcomes were pachymetry as central corneal thickness (µm), endothelial cell count (cells per square millimeter), spherical equivalent (diopters [D]), graft rejection rate (%), and rebubbling rate (%).
QUALITY OF ASSESSMENT
We used the Scottish Intercollegiate Guidelines Network (SIGN) criteria to assess the methodological quality of the included articles, both for randomized clinical trials and cohort studies, with the dedicated evaluation grids. SIGN Controlled Trials and SIGN Cohort Studies checklists consisting of respectively 10 and 14 items. We presented an overall quality score for each included study, based on the main causes of bias evaluated in section 1 of the checklist through 4 possibilities of answers (yes, no, can’t say, or not applicable).
STATISTICAL CONSIDERATIONS
Statistical analyses were conducted using Stata software (StataCorp). Characteristics of subjects and parameters evaluated were reported for each study sample as mean ± standard deviation (SD) and number (%) for continuous and categorical variables, respectively. We computed random-effects meta-analysis (DerSimonian and Laird approach) on changes between after the intervention and baseline measures, for each efficacy outcome: best spectacle-corrected visual acuity in logMAR, central corneal thickness in µm, endothelial cell count from donor in cell/mm 2 , and SE in D. For graft rejection and rebubbling, meta-analysis was expressed in rates (%). When a study presented several time measurements, the last follow-up time was retained for the main analysis. When visual acuity was evaluated with a Snellen chart or a decimal scale, it was converted to logMAR using the formula: logMAR visual acuity = −log10 (decimal visual acuity). Changes were calculated using the method from Borenstein and associates. This approach has the advantage to express results—ie, effect sizes (ESs) as natural values (logMAR, µm, cell/mm 2 , and D, respectively—but suffers from statistical issues because the number of eyes is only taken into account from SD, and by choosing an arbitrary correlation coefficient of 0.5. Therefore, to be statistically accurate, we further computed aforementioned meta-analysis using standardized mean differences (SMD) by comparing measures of efficacy after the intervention to baseline measures (before the intervention). SMD with their 95% CIs were represented graphically on forest plots. A SMD was defined as an unitless measure of the effects of T/UT-DSAEK on outcomes. A SMD centered at 0 reflects the absence of effect, 0.2 a small effect, 0.5 a moderate effect, and 0.8 a large effect. We stratified our meta-analyses on the thickness of corneal grafts in T/UT-DSAEK (<80 μm, 80-100 μm, and 100-130 μm), according to the preoperative thickness (or the earliest postoperative graft thickness). Lastly, we performed several sensitivity analyses to verify the strength of our results. First, we repeated meta-analyses with all measurement times. Then, as recovery from surgery is likely to be achieved over the long term, we computed previous meta-analyses using only studies with a follow-up >1 year. As the most common surgery is the microkeratome technique for Fuchs endothelial dystrophy, we also computed sensitivity meta-analyses on those studies. Heterogeneity in our results was evaluated by examining forest plots, 95% CIs, and the I 2 statistic. Heterogeneity between studies is considered low for 0% < I 2 <25%, modest for 25% < I 2 < 50%, and high for 50% < I 2 < 100%. For rigor, funnel plots (metafunnels) of meta-analyses were used to search for publication bias, and meta-analyses were conducted excluding studies not evenly distributed around the base of the funnel. When possible (sufficient sample size), metaregressions were proposed to study the relationship between clinical outcomes and clinically relevant parameters such as characteristics of subjects and donors (age, sex), pathology causing endothelial failure, time, and characteristics of surgery. Results of meta-regressions were expressed as regression coefficients and 95% CIs. P values < .05 were considered statistically significant.
RESULTS
An initial search produced 2926 possibly corresponding articles ( Figure 1 ). After removal of the duplicates and applying selection criteria, we included 47 articles , , , published between 2009 and 2021 ( Table 1 ). All articles were written in English, except for 2 in French, , 1 in Russian, and 1 in German.
| Study | Country | Study design | Eyes, n (No. of Patients) | Mean Age, Years | Sex (% Male) | Pathology | Triple EK (%) | Graft Dissection | Mean CGT, µm (Range) | CGT Assessment, Months | Outcomes | Follow-Up, Months | |||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| BSCVA | CCT | ECC | SE | Rejection | Rebubbling | ||||||||||||
| Asif and associates, 2021 | India | Retrospective | 39 | 9.9 | 45 | CHED | 3 | Microkeratome (single pass) | 119.4 | Immediately after dissection | X | X | 17.3 | ||||
| Bertino and associates, 2020 | Brazil | Retrospective | 15 | — | 53 | FED, PBK, regraft | 13 | Manual | 94.6 | 6 | X | X | 12 | ||||
| Bhandari and associates, 2015 | India | Retrospective case series | 30 | 55.1 | 60 | FED | 0 | Microkeratome (single pass) | 91.1 | Immediately after dissection | X | X | X | X | X | 12 | |
| Bielefeld and associates, 2020 | France | Retrospective | 79 (75) | 72 | — | FED, PBK, regraft, other | — | Microkeratome | 91 | Immediately after dissection | X | X | X | X | X | 12 | |
| Bonissent and associates, 2016 | France | Retrospective | 70 | 68.1 | 38.6 | FED, PBK, regraft, HSV, ICE | — | Manual + Excimer laser | 84.1 | 1 | X | X | X | X | 12 | ||
| Busin and associates, 2013 | Italy | Prospective case series | 285 (250) | 67.9 | 38.4 | FED, PBK, regraft, HSV, PPD, ICE, congenital glaucoma | 33.7 | Microkeratome (double pass) | 78.3 | 3 | X | X | X | 24 | |||
| Castellucci and associates, 2021 | Italy | Retrospective cohort | 26 (13) | 67.6 | 46 | FED | 58 | Microkeratome (single pass) | 99.3 | Immediately after dissection | X | X | 19.6 | ||||
| Chamberlain and associates, 2019 | USA | RCT | 25 (19) | 68 | 36 | FED, PBK | 68 | Microkeratome | 73 | Immediately after dissection | X | X | X | X | X | 12 | |
| Dickman and associates, 2016 | Netherlands | RCT | 34 | 73 | — | FED | 29 | Microkeratome (single pass) | 101 | Immediately after dissection | X | X | X | X | 12 | ||
| Dimitry and associates, 2017 | UK | Prospective case series | 12 | 65 | 16.7 | FED, PBK | 67 | Microkeratome (single pass) | 78.9 | Immediately after dissection | X | 12 | |||||
| Dunker and associates, 2020 | Netherlands | RCT | 25 | 71 | — | FED | 0 | Microkeratome (single pass) | 101 | Immediately after dissection | X | X | X | X | X | 12 | |
| El Hadad and associates, 2016 | Italy | RCT | 51 | 70.7 | — | FED, PBK, regraft, PPD | 49 | Microkeratome (double pass) | 89.3 | 1 | X | X | X | 12 | |||
| Gormsen and associates, 2019 | Denmark | Retrospective registry study | 89 | 71 | 40 | — | — | Microkeratome (single pass) | 86 | Immediately after dissection | X | X | 12 | ||||
| Graffi and associates, 2018 | Italy | Retrospective case series | 21 | 69.2 | 48 | Regraft | 5 | Microkeratome | 82 | 6 | X | X | X | 12 | |||
| Guerra and associates, 2011 | USA | Retrospective case series | 15 | 67 | 40 | FED | 0 | Microkeratome (single pass) | aim to 120 | – | X | X | 12 | ||||
| Jansen and Zetterberg, 2021 | Sweden | Retrospective | 116 | 75.1 | 38.8 | FED, PBK, regraft | 12 | Microkeratome (single pass) | (100 – 130) | Immediately after dissection | X | X | X | 24 | |||
| Jun and associates, 2009 | USA | Retrospective case series | 28 | 67 | 39.3 | FED, PBK | 39.3 | — | 106.9 | Immediately after dissection | X | X | 4.7 | ||||
| Kurji and associates, 2018 | USA | Prospective case series | 28 (26) | 67.1 | 39.3 | FED | 64.3 | — | 41 | Immediately after dissection | X | X | X | 12 | |||
| Lanza and associates, 2021 | Italy | Retrospective | 111 (96) | 70.3 | 45.8 | FED, PBK | 48.6 | — | 90.3 | Immediately after dissection | X | X | X | X | X | 8.5 | |
| Liarakos and associates, 2013 | Netherlands | Retrospective case series | 7 | 72.4 | 57.1 | PBK | 0 | Manual | 107 | Immediately after dissection | X | X | X | X | 12 | ||
| Matsou and associates, 2020 | UK | RCT | 28 | 72 | 50 | FED | 71 | Microkeratome (single pass) | 63 | Immediately after dissection | X | X | X | X | X | 12 | |
| McKee and Jhanji, 2015 | Australia | Case series | 5 | 80.2 | 40 | FED, PBK, regraft | — | Femtosecond laser | 82.8 | 6 | X | 6 | |||||
| Mencucci and associates, 2020 | Italy | Retrospective | 18 | 73.5 | 11 | FED | 0 | Microkeratome (single pass) | 80.3 | Immediately after dissection | X | X | X | X | X | 12 | |
| Mimouni and associates, 2021 | Austria | Retrospective | 28 | 73.9 | 25 | FED, PBK | — | — | 88.5 | Immediately after dissection | X | – | |||||
| Muijzer and associates, 2019 | Netherlands | Prospective cohort | 21 | 68 | 39 | FED, regraft | 47.6 | Microkeratome (single pass) or manual | 105 | Immediately after dissection | X | X | X | X | 12 | ||
| Muijzer and associates, 2019 | Netherlands | Prospective cohort | 53 | 68 | 39 | FED, PBK, regraft | 39.6 | Microkeratome (single pass) or manual | 106 | Immediately after dissection | X | X | X | X | 12 | ||
| Nahum and associates, 2015 | Italy | Retrospective | 42 | — | — | FED, PBK, regraft | — | Microkeratome (single) pass | 63 | 3 | X | 3 | |||||
| Parekh and associates, 2019 | UK | Retrospective cohort | 39 | — | — | — | 33.3 | Microkeratome (single) pass | 83.5 | Immediately after dissection | X | X | 8.5 | ||||
| Roberts and associates, 2015 | UK | Prospective cohort | 130 (114) | 72 | 50 | FED, other | 53 | Microkeratome (single) pass | 95 | Immediately after dissection | X | X | X | X | 12 | ||
| Romano and associates, 2017 | UK | Case series | 10 | — | — | — | — | Microkeratome (single) pass | 83.2 | Immediately after dissection | X | 3 | |||||
| Romano and associates, 2020 | UK | Retrospective case series | 31 | 69.3 | 42.9 | FED, PBK | 35.5 | — | 75.3 | Immediately after dissection | X | X | 12 | ||||
| Rosa and associates, 2013 | Portugal | Prospective | 25 | 65 | 32 | FED, PBK | 32 | Microkeratome + Femtosecond laser | 83.1 | 1 | X | X | X | 6 | |||
| Ruzza and associates, 2015 | Italy | Prospective case series | 14 | — | — | FED, PBK, regraft, PPD | — | Microkeratome (single pass) | 102 | Immediately after dissection | X | 6 | |||||
| Ruzza and associates, 2021 | Italy | Retrospective case series | 9 | — | — | FED, PBK | 22.2 | — | 83 | 8.5 | X | X | X | 8.5 | |||
| Saunier and associates, 2016 | France | Prospective | 49 | 67.5 | 40.8 | FED, PBK, other | 36.7 | Microkeratome (single pass) | 116.5 | Immediately after dissection | X | X | 6 | ||||
| Schaub and associates, 2016 | Germany | Retrospective case series | 5 | 60 | 60 | — | — | Microkeratome (single pass) | 64.5 | Immediately after dissection | X | X | X | X | 3 | ||
| Tereshchenko and associates, 2017 | Russia | 5 | 72 | 0 | PBK | 0 | Femtosecond laser | 52 | 6 | X | X | 6 | |||||
| Terry and associates, 2012 | USA | Retrospective case series | 45 | 64.8 | 31 | FED | — | Microkeratome (single pass) | (80 – 124) | Immediately after dissection | X | 6 | |||||
| Thannhäuser and associates, 2014 | Germany | Prospective | 18 | 76 | — | FED, PBK, other | — | Microkeratome + Excimer laser | 111 | Immediately after dissection | X | X | X | 6 | |||
| Tomida and associates, 2015 | Japan | 21 | 70 | 62 | FED, PBK, other | — | Femtosecond laser | Aim to 120 | — | X | X | X | 6 | ||||
| Torras-Sanvicens and associates, 2021 | Spain | Retrospective case series | 10 | 75.4 | 40 | FED | 20 | – | 91.1 | Immediately after dissection | X | X | 45.5 | ||||
| Tourkmani and associates, 2019 | UK | Retrospective | 29 | — | — | FED, PBK, regraft, HSV | 17.2 | Manual | 106 | 2 | X | 2 | |||||
| Tsatsos and associates, 2014 | UK | Prospective | 10 | — | — | FED, PBK | 0 | Manual | 90.7 | 1 | X | 1 | |||||
| Vajpayee and associates, 2013 | Australia | Case series | 15 | — | — | FED, PBK, regraft, CHED | 20 | Microkeratome (single pass) | 111 | 6 | X | X | 6 | ||||
| Villarrubia and Cano-Ortiz, 2015 | Spain | Prospective case series | 60 (51) | — | — | — | — | Microkeratome (single or double pass) | 99.3 | 1 | X | 1 | |||||
| Walter and associates, 2020 | USA | Retrospective cohort | 170 | 72 | 30 | FED, PBK | — | — | (70 – 110) | Immediately after dissection | X | 48 | |||||
| Wang and associates, 2021 | China | Prospective | 85 (84) | 58 | 52.4 | FED, PBK, regraft, HSV, ICE, other | 27.1 | Femtosecond laser | 113 | 3 | X | X | X | X | 24 | ||
| Woo and associates, 2019 | Singapore | Retrospective cohort | 60 | 68.6 | 46.7 | FED, PBK | — | Microkeratome | 80.6 | Immediately after dissection | X | 60 | |||||
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