Ulug Pinar, Powell Janet T, Martinez Melissa Ashley-Marie, Ballard David J, Filardo Giovanni
Vascular Surgery Research Group, Imperial College London, London, UK.
Department of Neurology, University of Arizona, Phoenix, AZ, USA.
Cochrane Database Syst Rev. 2020 Jul 1;7(7):CD001835. doi: 10.1002/14651858.CD001835.pub5.
An abdominal aortic aneurysm (AAA) is an abnormal ballooning of the major abdominal artery. Some AAAs present as emergencies and require surgery; others remain asymptomatic. Treatment of asymptomatic AAAs depends on many factors, but the size of the aneurysm is important, as risk of rupture increases with aneurysm size. Large asymptomatic AAAs (greater than 5.5 cm in diameter) are usually repaired surgically; very small AAAs (less than 4.0 cm diameter) are monitored with ultrasonography. Debate continues over the roles of early repair versus surveillance with repair on subsequent enlargement in people with asymptomatic AAAs of 4.0 cm to 5.5 cm diameter. This is the fourth update of the review first published in 1999.
To compare mortality and costs, as well as quality of life and aneurysm rupture as secondary outcomes, following early surgical repair versus routine ultrasound surveillance in people with asymptomatic AAAs between 4.0 cm and 5.5 cm in diameter.
The Cochrane Vascular Information Specialist searched the Cochrane Vascular Specialised Register, CENTRAL, MEDLINE, two other databases, and two trials registers to 10 July 2019. We handsearched conference proceedings and checked reference lists of relevant studies.
We included randomised controlled trials where people with asymptomatic AAAs of 4.0 cm to 5.5 cm were randomly allocated to early repair or imaging-based surveillance at least every six months. Outcomes had to include mortality or survival.
Three review authors independently extracted data, which were cross-checked by other team members. Outcomes were mortality, costs, quality of life, and aneurysm rupture. For mortality, we estimated risk ratios (RR) (endovascular aneurysm repair only), hazard ratios (HR) (open repair only), and 95% confidence intervals (CI) based on Mantel-Haenszel Chi statistics at one and six years (open repair only) following randomisation.
We found no new studies for this update. Four trials with 3314 participants fulfilled the inclusion criteria. Two trials compared early open repair with surveillance and two trials compared early endovascular repair (EVAR) with surveillance. We used GRADE to access the certainty of the evidence for mortality and cost, which ranged from high to low. We downgraded the certainty in the evidence from high to moderate and low due to risk of bias concerns and imprecision (some outcomes were only reported by one study). All four trials showed an early survival benefit in the surveillance group (due to 30-day operative mortality with repair) but no evidence of differences in long-term survival. One study compared early open repair with surveillance with an adjusted HR of 0.88 (95% CI 0.75 to 1.02, mean follow-up 10 years; HR 1.21, 95% CI 0.95 to 1.54, mean follow-up 4.9 years). Pooled analysis of participant-level data from the two trials comparing early open repair with surveillance (maximum follow-up seven to eight years) showed no evidence of a difference in survival (propensity score-adjusted HR 0.99, 95% CI 0.83 to 1.18; 2226 participants; high-certainty evidence). This lack of treatment effect did not vary to three years by AAA diameter (P = 0.39), participant age (P = 0.61), or for women (HR 0.84, 95% CI 0.62 to 1.11). Two studies compared EVAR with surveillance and there was no evidence of a survival benefit for early EVAR at 12 months (RR 1.92, 95% CI 0.73 to 5.06; 846 participants; low-certainty evidence). Two trials reported costs. The mean UK health service costs per participant over the first 18 months after randomisation were higher in the open repair surgery than the surveillance group (GBP 4978 in the repair group versus GBP 3914 in the surveillance group; mean difference (MD) GBP 1064, 95% CI 796 to 1332; 1090 participants; moderate-certainty evidence). There was a similar difference after 12 years. The mean USA hospital costs for participants at six months after randomisation were higher in the EVAR group than in the surveillance group (USD 33,471 with repair versus USD 5520 with surveillance; MD USD 27,951, 95% CI 25,156 to 30,746; 614 participants; low-certainty evidence). After four years, there was no evidence of a difference in total medical costs between groups (USD 48,669 with repair versus USD 46,112 with surveillance; MD USD 2557, 95% CI -8043 to 13,156; 614 participants; low-certainty evidence). All studies reported quality of life but used different assessment measurements and results were conflicting. All four studies reported aneurysm rupture. There were very few ruptures reported in the trials of EVAR versus surveillance up to three years. In the trials of open surgery versus surveillance, there were ruptures to at least six years and there were more ruptures in the surveillance group, but most of these ruptures occurred in aneurysms that had exceeded the threshold for surgical repair.
AUTHORS' CONCLUSIONS: There was no evidence of an advantage to early repair for small AAA (4.0 cm to 5.5 cm), regardless of whether open repair or EVAR is used and, at least for open repair, regardless of patient age and AAA diameter. Thus, neither early open nor early EVAR of small AAAs is supported by currently available evidence. Long-term data from the two trials investigating EVAR are not available, so, we can only draw firm conclusions regarding outcomes after the first few years for open repair. Research regarding the risks related to and management of small AAAs in ethnic minorities and women is urgently needed, as data regarding these populations are lacking.
腹主动脉瘤(AAA)是主要腹主动脉的异常扩张。一些腹主动脉瘤表现为急症,需要手术治疗;另一些则无症状。无症状腹主动脉瘤的治疗取决于多种因素,但动脉瘤大小很重要,因为破裂风险随动脉瘤大小增加。大型无症状腹主动脉瘤(直径大于5.5厘米)通常进行手术修复;非常小的腹主动脉瘤(直径小于4.0厘米)通过超声监测。对于直径4.0厘米至5.5厘米的无症状腹主动脉瘤患者,早期修复与监测并在随后扩大时进行修复的作用仍存在争议。这是该综述的第四次更新,首次发表于1999年。
比较直径4.0厘米至5.5厘米的无症状腹主动脉瘤患者早期手术修复与常规超声监测后的死亡率、成本,以及作为次要结果的生活质量和动脉瘤破裂情况。
Cochrane血管信息专家检索了Cochrane血管专业注册库、CENTRAL、MEDLINE、另外两个数据库以及两个试验注册库,检索截至2019年7月10日。我们手工检索了会议论文集并检查了相关研究的参考文献列表。
我们纳入了随机对照试验,其中直径4.0厘米至5.5厘米的无症状腹主动脉瘤患者被随机分配至早期修复或至少每六个月进行一次基于影像学的监测。结局必须包括死亡率或生存率。
三位综述作者独立提取数据,其他团队成员进行交叉核对。结局指标为死亡率、成本、生活质量和动脉瘤破裂。对于死亡率,我们根据随机分组后1年和6年(仅开放修复)的Mantel-Haenszel卡方统计量估计风险比(RR)(仅血管内动脉瘤修复)、风险比(HR)(仅开放修复)和95%置信区间(CI)。
本次更新未发现新的研究。四项试验共3314名参与者符合纳入标准。两项试验比较了早期开放修复与监测,两项试验比较了早期血管内修复(EVAR)与监测。我们使用GRADE评估死亡率和成本证据的确定性,范围从高到低。由于存在偏倚风险和不精确性(一些结局仅由一项研究报告),我们将证据的确定性从高降至中低。所有四项试验均显示监测组有早期生存获益(由于修复手术的30天手术死亡率),但无长期生存差异的证据。一项研究比较了早期开放修复与监测,调整后的HR为0.88(95%CI 0.75至1.02,平均随访10年;HR 1.21,95%CI 0.95至1.54,平均随访4.9年)。对两项比较早期开放修复与监测的试验(最长随访7至8年)的参与者水平数据进行汇总分析,未显示生存差异的证据(倾向评分调整后的HR为0.99,95%CI 0.83至1.18;2226名参与者;高确定性证据)。这种治疗效果的缺乏在三年时不因腹主动脉瘤直径(P = 0.39)、参与者年龄(P = 0.61)或女性(HR 0.84,95%CI 0.62至1.11)而有所不同。两项研究比较了EVAR与监测,在12个月时未发现早期EVAR有生存获益的证据(RR 1.92,95%CI 0.73至5.06;846名参与者;低确定性证据)。两项试验报告了成本。随机分组后前18个月,开放修复手术组每位参与者的英国医疗服务平均成本高于监测组(修复组为4978英镑,监测组为3914英镑;平均差异(MD)为1064英镑,95%CI 796至1332;1090名参与者;中等确定性证据)。12年后也有类似差异。随机分组后6个月,EVAR组参与者的美国医院平均成本高于监测组(修复为33,471美元,监测为5520美元;MD为27,951美元,95%CI 25,156至30,746;614名参与者;低确定性证据)。四年后,两组之间总医疗成本无差异的证据(修复为48,669美元而监测为46,112美元;MD为2557美元,95%CI -8043至13,156;614名参与者;低确定性证据)。所有研究均报告了生活质量,但使用了不同的评估方法,结果相互矛盾。所有四项研究均报告了动脉瘤破裂情况。在EVAR与监测的试验中,截至三年报告的破裂情况很少。在开放手术与监测的试验中,至少六年有破裂情况,且监测组破裂更多,但这些破裂大多发生在已超过手术修复阈值的动脉瘤中。
对于小的腹主动脉瘤(4.0厘米至5.5厘米),无论采用开放修复还是EVAR,早期修复均无优势,至少对于开放修复而言,无论患者年龄和腹主动脉瘤直径如何。因此,目前可得证据不支持对小的腹主动脉瘤进行早期开放或早期EVAR。两项研究EVAR的试验缺乏长期数据,所以,我们只能就开放修复头几年后的结局得出确切结论。由于缺乏这些人群的数据,迫切需要开展关于少数族裔和女性小的腹主动脉瘤相关风险及管理的研究。
