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SMILE术后角膜体积的变化及其与角膜生物力学特性的相关性

Correlation of the changes in corneal volume with the corneal biomechanical parameters after small incision lenticule extraction

来源期刊: 眼科学报 | 2022年8月 第37卷 第8期 609-619 发布时间: 收稿时间:2022/11/23 10:10:59 阅读量:3874
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角膜生物力学参数Corvis ST角膜体积飞秒激光小切口角膜基质透镜取出术近视
corneal biomechanical parameters Corvis? ST corneal volume femtosecond laser small incision corneal stromal lens extraction myopia
DOI:
10.3978/j.issn.1000-4432.2022.08.01
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目的:基于新一代Corvis® ST分析成人近视患者经飞秒激光小切口角膜透镜取出术(small incision corneal lens extraction,SMILE)后角膜体(corneal volumn,CV)的变化与角膜生物力学变化的相关性,进一步证明C V对于评估SMILE术后角膜生物力学特性以及预测屈光手术结果的价值。方法:采用前瞻性病例观察研究方法,纳入2021年1月至8月在佛山市第二人民医院拟行SMILE的成人近视患者72例(72眼)。为避免双眼相关性,纳入患者的一个合适眼(右眼或者左眼),根据术前中央角膜厚度,将厚度470~<530 μm分为低角膜厚度组,530~<560 μm为中角膜厚度组 , ≥560μm为高角膜厚度组。应用新一代 Corvis® ST 于术前和术后3个月测量非接触生物力学校正眼压(biomechanical intraocular pressure,bIOP)、2 mm处变形幅度的比值[DA ratiomax(2 mm),DA2ratio]、综合半径(integrated inverse concave radius,IR)、水平方向Ambr?sio相关厚度,最薄点厚度/厚度变化率(Ambrósio’s relational thickness,ARTh)、第1次压平时角膜硬度参数(stiffness parameter applanation 1,SP-A1)、Corvis生物力学指数(Corvis biomechanical index,CBI)和应力和应变参数(stress-strain index,SSI)7项角膜生物力学参数。应用Pentacam眼前节分析系统测量中央角膜厚度(central corneal thickness,CCT)和不同区域的CV(CV3mm、CV5mm、CV7mm和CV10mm)。对比SMILE术前与术后3个月的CV、角膜生物力学参数的变化,并分析角膜生物力学参数与CV的相关性。数据采用配对、独立样本t检验分析差异性;单因素方差分析不同角膜厚度组的差异性;Spearman相关性分析和偏最小二乘回归(partial least squares linear regression,PLSLR)分析相关性。结果:SMILE术后3个月,CV3mm、CV5mm、CV7mm和CV10mm均较术前显著下降(均P<0.001);bIOP、ARTh、SP-A1和SSI较术前明显下降(P<0.05);DA2ratio、IR和CBI较术前明显升高(P<0.05)。术前和术后3个月不同角膜厚度组的ARTh、SP-A1DA2ratio、IR和CBI差异均有统计学意义(均P<0.05),低中角膜厚度组SSI术前后变化不大(P>0.05)。术前DA2ratio与CV3mm、CV5mm呈负相关,与CV10mm呈正相关;ARTh与CV3mm、CV5mm呈正相关,与CV10mm呈负相关;bIOP与CV10mm呈正相关;IR与CV3mm、CV5mm呈负相关,与CV10mm呈正相关;SP-A1与CV3mm、CV5mm呈正相关,与CV10mm呈负相关;CBI与CV3mm、CV5mm和CV10mm呈负相关,SSI与CV3mm呈正相关,与CV10mm呈负相关。SMILE术后3个月,ARTh与CV3mm、CV5mm呈正相关,与CV10mm呈负相关;CBI与CV3mm负相关、CV10mm呈正相关(均P<0.05)。SMILE术后3个月变化量中,ARTh与CV3mm、CV5mm呈正相关,与CV10mm负相关;CBI与CV3mm呈负相关,与CV10mm呈正相关(均P<0.05)。结论:成人SMILE术后3个月CV3mm、CV5mm、CV7mm、CV10mm、眼压和CCT较术前均显著降低;越往周边区域CV减少量越多。SMILE术后3个月的新一代Corvis® ST角膜生物力学新型参数较术前有显著变化;不同区域CV与角膜生物力学参数存在一定的相关性,预期SMILE术后不同区域的CV可以表征术后部分角膜生物力学特性的改变,CV可能成为表征预测角膜扩张发展的参数因素。
Objective: To evaluate the changes in corneal volume (CV) and the correlation of corneal biomechanics in adult myopic patients after small incision corneal lens extraction (SMILE) based on the new generation of Corvis® ST.This paper further demonstrates the value of CV in evaluating corneal biomechanical properties after SMILE and predicting the outcome of refractive surgery. Methods: A total of 72 cases (72 eyes) of adult myopia who were scheduled for SMILE in The Second People’s Hospital of Foshan from January to August 2021 were included in this prospective observational case study. To avoid binocular correlation, a suitable eye for each person was selected for inclusion. Based on the preoperative central corneal thickness (CCT), the cases were divided into a low corneal thickness group (470–<530 μm), a medium corneal thickness group (530–<560 μm), and a high corneal thickness group (≥560 μm). The biomechanical intraocular pressure (bIOP), DA ratiomax (2 mm) (DA2ratio), integrated inverse concave radius (IR), Ambrósio’s relational thickness (ARTh), stiffness parameter applanation 1 (SP-A1),corvis biomechanical index (CBI) and stress-strain index (SSI) were measured by Corvis® ST. The Pentacam anterior segment analysis system was used to measure partial CV and total CV with a diameter of 3, 5, and 7 mm from the top of the cornea, with an assumed diameter of 10 mm. The changes in corneal biomechanical parameters and CV before SMILE and 3 months after SMILE were compared. The correlation between corneal biomechanical parameters and CV was studied. Data were analyzed by paired and independent sample t-tests. One-way analysis of variance (ANOVA) was used to assess the differences between the corneal thickness groups. Spearman correlation analysis and partial least squares linear regression (PLSLR) were used for correlation analyses. Results: Three months after SMILE, the CV in different areas (CV3mm, CV5mm, CV7mm, and CV10mm) were significantly lower than those before SMILE, and the differences were statistically significant (all P<0.001). The corneal biomechanical parameters bIOP, ARTh, SP-A1, and SSI were significantly decreased compared with those before the operation (P<0.05). In contrast, the DA2 ratio, IR, and CBI were significantly higher than those before the operation (P<0.05). A comparison of the corneal biomechanical parameters ARTh, SP-A1, DA2 ratio, IR, and CBI in the different corneal thickness groups before and after SMILE showed overall differences among the groups (P<0.05).However, there was no significant change in the SSI between the low and medium corneal thickness groups. The correlation of the preoperative baseline DA2ratio was negatively correlated with CV3mm and CV5mm, and positively correlated with CV10mm; Conversely, ARTh was positively correlated with CV3mm and CV5mm, and negatively correlated with CV10mm; BIOP was positively correlated with CV10mm; IR was negatively correlated with CV3mm and CV5mm, and positively correlated with CV10mm; SP-A1 was positively correlated with CV3mm and CV5mm, and negatively correlated with CV10mm; CBI was negatively correlated with CV3mm, CV5mm, and CV10mm, while SSI was positively correlated with CV3mm and negatively correlated with CV10mm (all P<0.05). At 3 months after SMILE, ARTh was positively correlated with CV3mm and CV5mm, and negatively correlated with CV10mm; CBI was negatively correlated with CV3mm, and positively correlated with CV10mm (all P<0.05). Conclusion: This study demonstrated that at 3 months after SMILE, CV3mm, CV5mm, CV7mm, CV10mm, intraocular pressure, and CCT in the central and peripheral areas decreased significantly compared with to those before the operation, and the more peripheral the area, the more the CV decreased. Three months after SMILE, the new corneal biomechanical parameters of the new generation Corvis® ST changed significantly compared to those before the operation, and there was a certain correlation between CV in different regions and corneal biomechanical parameters. It is expected that CV in different regions after SMILE can characterize some changes in corneal biomechanical properties after SMILE, and CV may become a parameter factor for characterizing and predicting the development of corneal dilatation.
    近年来的飞秒激光小切口角膜基质透镜取出术(femtosecond laser small incision lenticule extraction,SMILE)是目前主要的角膜屈光手术之一。有研究[1-2]表明因角膜组织的切除伴随着角膜体积(corneal volume,CV)的改变,同时引起一定程度的角膜生物力学特性的改变。Pentacam(Pentacam HR,Oculus,Wetzlar,Germany)三维眼前节分析系统可以提供有足够的重复性、可靠性和重现性的表征角膜结构及形态的CV[3]。新一代可视化角膜生物力学分析仪(corneal visualization Scheimpflug technology,Corvis® ST)提供量化角膜生物力学状态的各项角膜生物力学参数[4-5]。现研究发现CV的改变以及角膜形态的改变与角膜生物力学改变有一定的相关性,CV的变化可能是角膜扩张症发展的预测因素[2-3,6]。本研究分析SMILE术前后CV的改变与新一代Corvis® ST提供的新型角膜生物力学参数之间的相关性,预期CV对于评估SMILE术后角膜生物力学特性以及预测屈光手术的结果方面是有价值的;旨在进一步证明SMILE术后不同区域的CV的变化除了表征术后角膜组织结构变化外,还可以表征术后部分角膜生物力学特性的改变 ,CV可能成为表征角膜屈光术后角膜扩张发展的预测因素。

1 对象与方法

1.1 对象

    采用前瞻性病例观察研究。收集2021年1月至 8 月在佛山市第二人民医院视光学中心拟行SMILE角膜屈光手术的近视及近视散光患者。随访跟踪术前和术后3个月的数据。为避免双眼相关性,选择纳入患者的一个合适眼(右眼或者左眼)。纳入标准:1)年龄18~35岁;2)角膜透明形态正常,无云翳或斑翳;3)2年内屈光稳定或者每年屈光度变化量≤0.5 D;4)停戴软性角膜接触镜≥2周,停戴硬性角膜接触镜≥1个月,停戴角膜塑形镜≥3个月;5 )中央角膜厚度(central corneal thickness,CCT)>470 μm,眼压范围13~20 mmHg(1 mmHg=0.133 kPa)。排除标准:1 )圆锥角膜及疑似圆锥角膜者;2 )有眼部手术外伤史或者手术史;3 )有眼部活动性疾病;4 )有角膜营养不良、青光眼、糖尿病、全身结缔组织疾病或者自身免疫性疾病;5 )瘢痕体质;6 )扫描质量差、术中并发症和数据缺失的受试者。本研究遵守赫尔辛基宣言,并获得佛山市第二人民医院医学伦理委员会的论证和同意,所有患者签署手术知情同意书。根据术前CCT将患者分为3组 ,470~<530 μ m为低角膜厚度组(22眼),530~<560 μm为中角膜厚度组(25眼),≥560 μm为高角膜厚度组(25眼)。

1.2 方法

    所有患者行常规术前眼科检查,包括裸眼视力检查、复方托吡卡胺散瞳验光和综合验光确定屈光度、角膜测厚度、眼前节检查、非接触眼压计眼压测量、眼底检查。手术方式是SMILE,采用德国蔡司公司VisuMAX飞秒激光系统进行术眼角膜扫描切割,激光频率为500 kHz,能量为110 nJ,角膜帽厚度为120 μm,直径为7.3 mm,透镜直径为6.5 μm,切口位于颞上方,切口宽度为3 mm。术前3 d常规使用玻璃酸钠滴眼液及抗生素滴眼液;手术均由同一位主任医师操作,手术过程顺利;术后常规抗生素及糖皮质激素滴眼液使用,术后常规1 d、1周、1个月和3个月复查,复查情况良好,未出现感染、弥漫性层间角膜炎等术后并发症。

1.3 观察指标

    1.3.1 新一代 Corvis® ST 测量角膜生物力学参数
    Corvis® ST是一种使用高强度空气脉冲使角膜发生形变,并且使用高速Scheimpflug相机实时动态地记录其角膜形变的整个过程的活体测量新设备。选择测量显示“OK”的数据。重复测量3次,取平均值,间隔2~5 min进行。新型整合参数包括非接触生物力学校正眼压(biomechanical intraocular pressure,bIOP)、2 mm处变形幅度的比值[DA ratiomax(2 mm),D A2 ratio]、综合半径(Integrated inverse concave radius,IR)、水平方向Ambr?sio相关厚度,最薄点厚度/厚度变化率(Ambrósio’s relational thickness,ARTh)、第一次压平时角膜硬度参数(stiffness parameter applanation 1,SP-A1 )、Corvis生物力学指数(Corvis biomechanical index,CBI)和应力和应变参数(stress-strain index,SSI)。
    1.3.2 Pentacam 测量眼前段形态参数
    Pentacam 眼前节分析系统使用旋转的Scheimpflug原理,以非侵入性方式获取眼前节的三维立体图图像,评估眼前段生物测量值,重复测量3次,取平均值,间隔2~5 min进行。参数包括CCT、角膜曲率及CV。距角膜顶端直径3 mm、5 mm部分为角膜中心区域(CV3mm、CV5mm),7 mm的区域(CV7mm)、假设直径为10 mm的总角膜体积(CV10mm)定义为角膜周边区域。以上检查由同一位有经验的技术人员完成。

1.4 统计学处理

    采用IBM-SPSS 26.0统计学软件分析数据。对本研究参数值均进行描述性检验统计和采用Kolmogorov-Smirnov检验正态性;应用成对样本 t 检验或 Wilcoxon 符号秩检验来分析 SMILE术前后各项参数的变化;单因素方差分析及LSD-T检验事后多重分析不同角膜厚度组的差异性;由于观察参数变量之间存在多重共线性且样本量小,通过预测误差均方根(root mean square error of prediction,RMSEP)确认主成分数量后进行偏最小二乘回归(partial least square linear regression,PLSLR)和Spearman相关性有效性检验分析相关性。以P < 0.05为差异有统计学意义。

2 结果

2.1 基本资料

    纳入患者72例(72眼);其中男27例,女45例,年龄17~37(25.28±0.67)岁;等效球镜度(spherical equivalent,SE)为?2.125~?10.375(?4.84±0.21) D;眼轴(axial length,AL)为(25.66 ± 0.10) mm;CCT为476~623(545.50±3.70) μm;眼压为12~24(16.81±0.33) mmHg。3组术前屈光度、年龄、AL及曲率比较差异无统计学意义(均P≥0.05,表1)。

2.2 SMILE 手术前后不同区域的 CV 等形态及结构参数的变化

    SMILE术 后3个月,眼压、CCT、CV3mm、CV 5mm、 CV 7mm和 CV 10mm均较术前显著降低(P<0.05,表2,图1)。C V变化量从小到大依次为CV 3mm、CV 5mm、CV 7mm、CV 10mm;越往周边区域CV减少量增加。不同角膜厚度组的术前CV3mm、CV5mm差异具有统计学意义(P<0.05),但术后CV差异无统计学意义(P>0.05,表3)。

2.3 角膜生物力学新型整合参数

    SMILE术后3个月,bIOP、ARTh、SP-A1和SSI较术前基线明显下降;DA2ratio、IR和CBI较术前明显升高,差异均有统计学意义(均P<0.05)。术前和术后3个月ARTh、SP-A1、DA2ratio、I R和CBI组间差异均有统计学意义( P < 0.05);bIOP、SSI组间差异无统计学意义( P > 0.05)。与手术前比较,术后高角膜厚度组 ARTh 、SP-A1、DA2ratio、IR、CBI和SSI差异有统计学意 义( P < 0.05);与手术前比较,术后低中角膜厚度组ARTh、SP-A1、DA2ratio、I R和CBI差 异有统计学意义 ( P < 0.05) ; SSI 术后无显著变化(P>0.05;表4,5)。

表1 不同厚度组的术前基线资料
Table 1 Preoperative baseline data and cutting depth for difffferent thickness groups

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表2 SMILE手术前后CV、CCT和眼压的变化
Table 2 Changes of CV, CCT and intraocular pressure before and after SMILE

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图1 SMILE术前及术后3个月C V3mm、C V5mm、C V7mm
CV10mm
Figure 1 CV3mm, CV5mm, CV7mm, and CV10mm at preoperation and
3 months after SMILE

    对比低角膜厚度组16例术前和高角膜厚度16例术后的角膜生物力学参数和角膜厚度、眼压,结果显示两组ARThIRCBI参数差异具有统计学意义(P<0.01,表6)

2.4 角膜生物力学参数与 CV 相关性分析

    经Spearman相关性分析,再通过RMSEP选择主成分数量为3进 行PLSLR分析。在PLSLR分 析中,应考虑角膜厚度和眼压等对角膜生物力学参数的显著相关会掩盖其他参数的相关性研究,因此去除眼压和角膜厚度后进行PLSLR分析相关性研究(表7~9)。
    2.4.1 SMILE 术前角膜生物力学参数与术前 CV 等形态及结构参数的相关性
    术前 bIOP 、 DA 2 ratio 、 I R 、 ARTh 、SP-A 1和 CBI 与眼压均有相关性 ( P < 0.05) ,DA2ratio、I R、ARTh、SP-A 1和CBI与CCT显著相关( P < 0.05),bIOP和SSI与CCT无相关性(P>0.05),SSI与眼压无相关性(P>0.05);DA2ratio与CV 3mm、CV 5mm呈负相关( r =?0.512、?0.362,P < 0.05) , 与 C V 10mm呈正相关 ( r = 0.679 ,P < 0.05) ; ARTh 与 CV 3mm、 CV 5mm呈正相关( r =0.324、0.241,P <0.05),与C V10mm呈负相关
    2.4.2 SMILE 术后 3 个月角膜生物力学参数与 CV等形态及结构参数的相关性
    SMILE术后3个月bIOP、DA2ratio、IR、ARTh、SP-A1、CBI和SSI与眼压均有相关性(P <0.05),DA2ratio、IR、ARTh、SP-A1和CBI与CCT显著相关(P<0.05),SSI与CCT无相关性(P>0.05);ARTh与CV3mm、CV5mm呈正相关(r=0.376、0.203,P<0.05),与CV10mm呈负相关(r=?0.417,P<0.05);CBI与CV3mm呈负相关( r =?0.214,P <0.05)、C V10mm呈正相关(r=0.290,P<0.05,表8)。

表3 不同厚度组的不同区域CV比较
Table 3 Comparison of CV in difffferent areas of difffferent thickness

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表4 SMILE术前和术后3个月角膜生物力学新型整合参数的变化
Table 4 Changes in corneal biomechanical parameters before and 3 months after SMILE

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表5 不同厚度组SMILE术前和术后3个月角膜生物力学新型整合参数的比较
Table 5 Comparison of new corneal biomechanical integration parameters for SMILE of difffferent thickness groups before and 3
months after SMILE

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表6 16例低角膜厚度组术前角膜生物力学参数和16例高角膜厚度组术后的角膜生物力学参数对比
Table 6 Comparison of corneal biomechanical parameters between 16 patients with low corneal thickness before SMILE and 16
patients with high corneal thickness after SMILE

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表7 SMILE术前角膜生物力学参数与术前角膜体积等形态及结构参数的相关性
Table 7 Correlation between corneal biomechanical parameters before SMILE and preoperative morphological and structural
parameters before SMILE

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表8 SMILE术后3个月角膜生物力学参数与形态及结构参数的相关性
Table 8 Correlation of corneal biomechanical parameters with morphological and structural parameters 3 months after SMILE

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表9 SMILE术后3个月角膜生物力学参数变化量与形态及结构参数变化量的相关性
Table 9 Correlation of changes of corneal biomechanical parameters with changes of morphological and structural parameters 3
months after SMILE

20230209113450_4224.png
    2.4.3 SMILE 术后角膜生物力学参数变化量与 CV等形态及结构参数变化量的相关性
    SMILE手术前后bIOP、DA2ratio、IR、SP-A1和 CBI 变化量均与眼压变化量呈显著相关 ( 均P<0.05),DA2ratio、IR、ARTh、SP-A1和CBI变化量与CCT变化量显著相关(均P <0.05);ARTh变化量与CV3mm、CV5mm变化量呈正相关(r =0.392、0.453 , P < 0.05) , 与 CV10mm变化量呈负相关(r=?1.047,P<0.05);bIOP变化量与CV3mm、CV5mm变化量呈负相关(r=?0.272、?0.311,P<0.05),与CV10mm变化量呈正相关(r=0.822,P<0.05);IR变化量与CV10mm变化量呈负相关(r=?0.487,P<0.05);SP-A1变化量与C V5mm变化量呈负相关(r=?0.229,P <0.05),与CV10mm变化量呈正相关( r =?0.549,P<0.05);CBI变化量与CV3mm、CV5mm变化量负相关(r=?0.224、?0.263,P<0.05),与CV10mm变化量呈正相关(r=0.468,P<0.05,表9)。

3 讨论

    在近年来的角膜屈光手术研究领域中,CV是表征角膜结构和影响角膜生物力学特性的重要的角膜结构参数之一,研究也表明角膜组织量的区域空间分布特征对角膜屈光手术适应证的筛选和术后随访都极其重要[3,7]。本研究旨在探讨成人SMILE术后早期不同区域的C V的变化,应用新一代Corvis® ST提供的角膜生物力学参数分析SMILE术后早期角膜生物力学特性的变化,并探讨之间的相关性,进一步证明CV对于评估SMILE术后角膜生物力学特性以及预测屈光手术的结果方面的价值。
    以往研究[3]表 明CV和角膜厚度都是反应角膜结构和角膜组织量的重要指标。本研究应用Pentacam眼前节分析系统测量CV3mm、CV5mm、CV7mm、CV10mm和CCT,分析了SMILE术后3个月不同区域CV的变化情况,结果显示SMILE术后3个月CV3mm、C V5mm、CV7mm、C V10mm和CCT均较术前明显减少。有研究[3,8-9]提出CV是角膜屈光手术术后评估的重要指标,可以成为表征预测角膜扩张发展的因素。Wei等[7]认为SMILE术后CV和角膜厚度的减少与角膜手术切削角膜组织量和术后反应等相关,研究FS-LASIK和SMILE术后不同区域CV的变化并进行对比,发现SMILE术后3个月不同区域的CV减少,使得角膜胶原纤维数量减少和角膜外基质成分减少,进而引起角膜生物力学的改变。Sedaghat等[10]也提到C V与角膜生物力学参数角膜滞后量和阻力因子量相关。本研究也发现CV术前后变化量从小到大依次为CV3mm、CV5mm、CV7mm、CV10mm,越往周边区域CV减少量增加,考虑可能的原因与Reinstein等[11]提到的SMILE在基质层制作透镜后胶原纤维被切断,所在区域两侧的胶原纤维回缩,层间黏合力下降,从而中央区域的基质贴合较周边松弛有关,因此周边区域CV偏大。
    本研究中新一代Corvis® ST提供的角膜生物力学参数与CCT和眼压显著相关,角膜生物力学参数变化与不同区域CV变化存在有一定的相关性。Wei等[7]认为角膜基质胶原纤维呈异向性排列,相互交联,从角膜中央区到周边变得更明显,这样有助于角膜缘维持抗张力。角膜结构及组织量的稳定有助于角膜生物力学的稳定,SMILE术后由于角膜组织量切削导致CV减少,角膜所含的胶原纤维和细胞外基质成分减少,提供维持机械强度的胶原纤维减少,使得角膜机械强度下降。有趣的是,本研究对比了低角膜厚度组16例术前和高角膜厚度16例术后的角膜生物力学参数和角膜厚度、眼压,结果显示尽管这两组的角膜厚度(CCT)和眼压无明显差异,ARTh、IR、CBI这3项角膜生物力学参数仍然显示明显差异。ARTh指最薄点的角膜厚度与角膜厚度变化率的比值,值越小说明CCT薄或角膜厚度由内到外变化大,而角膜厚度测量的是角膜中央或者某个区域的厚度,本研究中ARTh的差异性也进一步提示角膜厚度不能全面反映角膜屈光术后角膜组织量的变化;IR指反向凹面半径曲线下的面积,反应角膜的整体硬度,值越大说明角膜抵抗形变的能力越弱,角膜硬度越低;CBI指基于角膜厚度分布及变形特点的参数,由6个不同的Corvis® ST角膜生物力学参数通过逻辑回归公式计算得来,在logistic回归分析的基础上,考虑了角膜变形反应指数和角膜厚度信息[12]。Wei等[7]和Han等[13]提到CCT的变化并不能全面反映角膜组织的实际变化,CV可以表征整体的变化量,并以单一值表征角膜形态变化[7,13]。因此,本研究探讨SMILE术后C V的变化对角膜生物力学特性的影响;在CV的改变可以表征部分角膜生物力学特性的改变方面提出了假设,今后的研究也可以延长随访时间,更合理地设计加大样本量,来进一步证实观点。
    本研究SMILE术后3个月的角膜生物力学参数中bIOP、ARTh、SP-A1和SSI较术前基线明显下降;DA2ratio、IR和CBI较术前明显升高。以往的研究[1,5,14]应用角眼反应分析仪和Corvis® ST研究角膜屈光术后生物力学特性的变化,提出角膜屈光手术均显著改变了角膜的生物力学特性。Yu等[15]和Spadea等[16]指出角膜生物力学变化在临床上可以表现为角膜的形态改变,角膜形态改变引起的生物力学反应改变,并且角膜生物力学特性在很大程度上是比较复杂并且随时间有变化的;Fernández等[17]应用Corvis® ST动态图像分析仪提供的新参数对小切口皮孔摘除术后的生物力学变化进行了研究,发现术后1个月角膜生物力学参数变化显著。Cao等[18]提到角膜生物力学的改变只发生在SMILE术后的早期,与透镜移除和重建新的生物力学平衡有一定的关系。Chen等[19]提到bIOP是根据角膜形态、角膜厚度及生物组织特性,矫正生物力学参数,反映受检者实际眼压,独立于CCT的参数;同时也可能受到测量的时间和其他因素的影响。以往的研究[20]表明角膜生物力学参数与角膜厚度和眼压显著相关,SSI参数几乎独立于bIOP和角膜厚度,角膜生物组织的应力应变是非线性,角膜在不同的压力负荷下表现出生物力学特性的变化[12,21];本研究中显示低角膜厚度组术前后SSI变化不大,较为稳定,高度角膜厚度组术前后SSI变化显著,可能解释有两个方面,一是与Zhang等[22]提到的角膜生物力学的代偿效应有关,角膜厚度越薄的患者在SMILE术后SSI越需要将角膜材料性刚度维持相对稳定,为维持术后角膜生物力学稳定而呈现出的一种代偿效应。第二种解释是SSI参数设计的模型针对正常的角膜,而近视激光术后或者扩张性疾病的角膜可能超出模型假设的限制,有研究[23-24]提出现扩张性疾病进展或者经治疗后SSI会发生改变。目前的研究[25]也有提到Corvis® ST测量的角膜生物力学参数受到很多混杂因素的影响,SMILE术后3个月角膜处在伤口愈合期,所测量的角膜生物力学参数表征术后伤口愈合期的角膜生物力学反应,这些变化可以解释为术后早期产生一个更复杂的生物力学稳定结构。在应用新一代Corvis® ST测量的生物力学参数解释生物力学特性的改变时应谨慎,或者需要更全面、更长期的研究数据支持。
    综上所述,成人SMILE术后3个月中央和周边区域的CV、眼压、CCT较术前均显著降低;并且越往周边区域CV减少量增加。SMILE术后3个月角膜生物力学新型参数较术前发生了显著的变化。不同区域CV与新一代Corvis® ST角膜生物力学新型参数存在一定的相关性,预期SMILE术后不同区域的CV可以表征术后部分角膜生物力学特性的改变,CV可能成为表征预测角膜扩张发展的因素,为临床提供科学依据。

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1、Abd El-Fattah EA, El Dorghamy AA, Ghoneim AM, et al. Comparison of corneal biomechanical changes after LASIK and F-SMILE with CorVis ST[ J]. Eur J Ophthalmol, 2021, 31(4): 1762-1770.Abd El-Fattah EA, El Dorghamy AA, Ghoneim AM, et al. Comparison of corneal biomechanical changes after LASIK and F-SMILE with CorVis ST[ J]. Eur J Ophthalmol, 2021, 31(4): 1762-1770.
2、Schuh A, Kolb CM, Mayer WJ, et al. Comparison of changes in corneal volume and corneal thickness after myopia correction between LASIK and SMILE[ J]. PLoS One, 2021, 16(5): e0250700.Schuh A, Kolb CM, Mayer WJ, et al. Comparison of changes in corneal volume and corneal thickness after myopia correction between LASIK and SMILE[ J]. PLoS One, 2021, 16(5): e0250700.
3、Viswanathan D, Kumar NL, Males JJ, et al. Relationship of structural characteristics to biomechanical profile in normal, Keratoconic, and crosslinked eyes[ J]. Cornea, 2015, 34(7): 791-796.Viswanathan D, Kumar NL, Males JJ, et al. Relationship of structural characteristics to biomechanical profile in normal, Keratoconic, and crosslinked eyes[ J]. Cornea, 2015, 34(7): 791-796.
4、Esporcatte LPG, Salom?o MQ, Lopes BT, et al. Biomechanical diagnostics of the cornea[ J]. Eye Vis (Lond), 2020, 7: 9.Esporcatte LPG, Salom?o MQ, Lopes BT, et al. Biomechanical diagnostics of the cornea[ J]. Eye Vis (Lond), 2020, 7: 9.
5、Herber, R, Terai, N, Pillunat, KR, et al. Dynamic Scheimpflug Analyzer (Corvis ST) for measurement of corneal biomechanical parameters : A praxis-related overview[ J]. Ophthalmologe, 2018, 115(8): 635-643.Herber, R, Terai, N, Pillunat, KR, et al. Dynamic Scheimpflug Analyzer (Corvis ST) for measurement of corneal biomechanical parameters : A praxis-related overview[ J]. Ophthalmologe, 2018, 115(8): 635-643.
6、?evik SG, K?van? SA, Akova-Budak B, et al. Relationship among corneal biomechanics, anterior segment parameters, and geometric corneal parameters[ J]. J Ophthalmol, 2016, 2016: 8418613.?evik SG, K?van? SA, Akova-Budak B, et al. Relationship among corneal biomechanics, anterior segment parameters, and geometric corneal parameters[ J]. J Ophthalmol, 2016, 2016: 8418613.
7、Wei P, Cheng GP, Zhang J, et al. Changes in corneal volume at different areas and its correlation with corneal biomechanics after SMILE and FS-LASIK surgery[ J]. J Ophthalmol, 2020, 2020: 1713979.Wei P, Cheng GP, Zhang J, et al. Changes in corneal volume at different areas and its correlation with corneal biomechanics after SMILE and FS-LASIK surgery[ J]. J Ophthalmol, 2020, 2020: 1713979.
8、Diniz CM, Hazarbassanov RM, Yamazaki E, et al. Pentacam Scheimpflug evaluation of corneal volume after LASIK[ J]. J Refract Surg, 2010, 26(8): 600-604.Diniz CM, Hazarbassanov RM, Yamazaki E, et al. Pentacam Scheimpflug evaluation of corneal volume after LASIK[ J]. J Refract Surg, 2010, 26(8): 600-604.
9、Cer v i?o A , Gonzalez -Meijome JM, Ferrer-Blasco T, et al. Determination of corneal volume from anterior topography and topographic pachymetry: application to healthy and keratoconic eyes[ J]. Ophthalmic Physiol Opt, 2009, 29(6): 652-660.Cer v i?o A , Gonzalez -Meijome JM, Ferrer-Blasco T, et al. Determination of corneal volume from anterior topography and topographic pachymetry: application to healthy and keratoconic eyes[ J]. Ophthalmic Physiol Opt, 2009, 29(6): 652-660.
10、Sedaghat MR, Sharepoor M, Hassanzadeh S, et al. The corneal volume and biomechanical corneal factors: Is there any orrelation?[ J]. J Res Med Sci, 2012, 17(1): 32-39.Sedaghat MR, Sharepoor M, Hassanzadeh S, et al. The corneal volume and biomechanical corneal factors: Is there any orrelation?[ J]. J Res Med Sci, 2012, 17(1): 32-39.
11、Reinstein, DZ, Archer, TJ, Gobbe, M, et al. Lenticule thickness readout for small incision lenticule extraction compared to artemis three-dimensional very high-frequency digital ultrasound stromal measurements[ J]. J Refract Surg, 2014, 30(5): 304-309.Reinstein, DZ, Archer, TJ, Gobbe, M, et al. Lenticule thickness readout for small incision lenticule extraction compared to artemis three-dimensional very high-frequency digital ultrasound stromal measurements[ J]. J Refract Surg, 2014, 30(5): 304-309.
12、任胜卫, 杨凯丽, 徐丽妍. Corvis ST测量近视患者新型角膜生物力学参数的重复性及其影响因素[ J]. 中华实验眼科杂志, 2019, 37(12): 990-994.
REN Shengwei, YANG Kaili, XU Liyan. The reproducibility and influencing factors of corneal biomechanical parameters measured by Corvis ST in myopia[ J]. Chinese Journal of Experimental Ophthalmology, 2019, 37(12): 990-994.
任胜卫, 杨凯丽, 徐丽妍. Corvis ST测量近视患者新型角膜生物力学参数的重复性及其影响因素[ J]. 中华实验眼科杂志, 2019, 37(12): 990-994.
REN Shengwei, YANG Kaili, XU Liyan. The reproducibility and influencing factors of corneal biomechanical parameters measured by Corvis ST in myopia[ J]. Chinese Journal of Experimental Ophthalmology, 2019, 37(12): 990-994.
13、Han, F, Li, M, Wei, P, et al. Effect of biomechanical properties on myopia: a study of new corneal biomechanical parameters[ J]. BMC Ophthalmol, 2020, 20(1): 459.Han, F, Li, M, Wei, P, et al. Effect of biomechanical properties on myopia: a study of new corneal biomechanical parameters[ J]. BMC Ophthalmol, 2020, 20(1): 459.
14、Sefat SM, Wiltfang R, Bechmann M, et al. Evaluation of changes in human corneas after femtosecond laser-assisted LASIK and small-incision lenticule extraction (SMILE) using Non-Contact Tonometry and Ultra-High-Speed Camera (Corvis ST)[J]. Curr Eye Res, 2016, 41(7): 917-922.Sefat SM, Wiltfang R, Bechmann M, et al. Evaluation of changes in human corneas after femtosecond laser-assisted LASIK and small-incision lenticule extraction (SMILE) using Non-Contact Tonometry and Ultra-High-Speed Camera (Corvis ST)[J]. Curr Eye Res, 2016, 41(7): 917-922.
15、Yu M, Chen M, Dai J. Comparison of the posterior corneal elevation and biomechanics after SMILE and LASEK for myopia: a short- and long-term observation[ J]. Graefes Arch Clin Exp Ophthalmol, 2019,257(3): 601-606.Yu M, Chen M, Dai J. Comparison of the posterior corneal elevation and biomechanics after SMILE and LASEK for myopia: a short- and long-term observation[ J]. Graefes Arch Clin Exp Ophthalmol, 2019,257(3): 601-606.
16、Spadea L, Giammaria D, Trabucco P. Corneal wound healing after laser vision correction[ J]. Br J Ophthalmol, 2016, 100(1): 28-33.Spadea L, Giammaria D, Trabucco P. Corneal wound healing after laser vision correction[ J]. Br J Ophthalmol, 2016, 100(1): 28-33.
17、 Fernández J, Rodríguez-Vallejo M, Martínez J, et al. New parameters for evaluating corneal biomechanics and intraocular pressure after small-incision lenticule extraction by Scheimpflug-based dynamic tonometry[ J]. J Cataract Refract Surg, 2017, 43(6): 803-811. Fernández J, Rodríguez-Vallejo M, Martínez J, et al. New parameters for evaluating corneal biomechanics and intraocular pressure after small-incision lenticule extraction by Scheimpflug-based dynamic tonometry[ J]. J Cataract Refract Surg, 2017, 43(6): 803-811.
18、Cao K, Liu L, Yu T, et al. Changes in corneal biomechanics during small-incision lenticule extraction (SMILE) and femtosecond-assisted laser in situ keratomileusis (FS-LASIK)[ J]. Lasers Med Sci, 2020,35(3): 599-609.Cao K, Liu L, Yu T, et al. Changes in corneal biomechanics during small-incision lenticule extraction (SMILE) and femtosecond-assisted laser in situ keratomileusis (FS-LASIK)[ J]. Lasers Med Sci, 2020,35(3): 599-609.
19、Chen, KJ, Joda, A, Vinciguerra, R, et al. Clinical evaluation of a new correction algorithm for dynamic Scheimpflug analyzer tonometry before and after laser in situ keratomileusis and small-incision lenticule extraction[ J]. J Cataract Refr Surg, 2018, 44(5): 581-588.Chen, KJ, Joda, A, Vinciguerra, R, et al. Clinical evaluation of a new correction algorithm for dynamic Scheimpflug analyzer tonometry before and after laser in situ keratomileusis and small-incision lenticule extraction[ J]. J Cataract Refr Surg, 2018, 44(5): 581-588.
20、Vinciguerra, R, Elsheikh, A, Roberts, CJ, et al. Influence of pachymetry and intraocular pressure on dynamic corneal response parameters in healthy patients[ J]. J Refract Surg, 2016, 32(8): 550-561.Vinciguerra, R, Elsheikh, A, Roberts, CJ, et al. Influence of pachymetry and intraocular pressure on dynamic corneal response parameters in healthy patients[ J]. J Refract Surg, 2016, 32(8): 550-561.
21、 Eliasy A, Chen KJ, Vinciguerra R, et al. Determination of corneal biomechanical behavior in-vivo for healthy eyes using CorVis ST Tonometry: stress-strain index[ J]. Front Bioeng Biotechnol, 2019,7: 105. Eliasy A, Chen KJ, Vinciguerra R, et al. Determination of corneal biomechanical behavior in-vivo for healthy eyes using CorVis ST Tonometry: stress-strain index[ J]. Front Bioeng Biotechnol, 2019,7: 105.
22、Zhang Y, Wang Y, Li L, et al. Corneal stiffness and its relationship with other corneal biomechanical and nonbiomechanical parameters in myopic eyes of chinese patients[ J]. Cornea, 2018, 37(7): 881-885.Zhang Y, Wang Y, Li L, et al. Corneal stiffness and its relationship with other corneal biomechanical and nonbiomechanical parameters in myopic eyes of chinese patients[ J]. Cornea, 2018, 37(7): 881-885.
23、 Lu NJ, Hafezi F, Rozema JJ, et al. Repeatability of Corvis ST to measure biomechanical parameters before and after myopic refractive surgery[ J]. J Cataract Refr Surg, 2022. [Epub ahead of print]. doi: 10.1097/j.jcrs.0000000000000909. Lu NJ, Hafezi F, Rozema JJ, et al. Repeatability of Corvis ST to measure biomechanical parameters before and after myopic refractive surgery[ J]. J Cataract Refr Surg, 2022. [Epub ahead of print]. doi: 10.1097/j.jcrs.0000000000000909.
24、Padmanabhan, P, Lopes, BT, Eliasy, A, et al. Evaluation of corneal biomechanical behavior in-vivo for healthy and keratoconic eyes using the stress-strain index[ J]. J Cataract Refract Surg, 2022. [Epub ahead of print]. doi: 10.1097/j.jcrs.0000000000000945.Padmanabhan, P, Lopes, BT, Eliasy, A, et al. Evaluation of corneal biomechanical behavior in-vivo for healthy and keratoconic eyes using the stress-strain index[ J]. J Cataract Refract Surg, 2022. [Epub ahead of print]. doi: 10.1097/j.jcrs.0000000000000945.
25、Fernández J, Rodríguez-Vallejo M, Martínez J, et al. Corneal thickness after SMILE affects Scheimpflug-based dynamic tonometry[ J]. J Refract Surg, 2016, 32(12): 821-828.Fernández J, Rodríguez-Vallejo M, Martínez J, et al. Corneal thickness after SMILE affects Scheimpflug-based dynamic tonometry[ J]. J Refract Surg, 2016, 32(12): 821-828.
1、佛山市科技创新项目医学类科技攻关项目 (2020001005825)。This work was supported by the Foshan Science and Technology Innovation Project Medical Science and Technology Project, China (2020001005825)()
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