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第三代可吸收镁支架降解动力学的临床前评价。

Preclinical evaluation of the degradation kinetics of third-generation resorbable magnesium scaffolds.

机构信息

Klinik für Herz- und Kreislauferkrankungen, Deutsches Herzzentrum München, Technical University Munich, Munich, Germany.

BIOTRONIK AG, Bülach, Switzerland.

出版信息

EuroIntervention. 2023 Jun 5;19(2):e167-e175. doi: 10.4244/EIJ-D-22-00718.

DOI:10.4244/EIJ-D-22-00718
PMID:36636768
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10240728/
Abstract

BACKGROUND

The novel sirolimus-eluting resorbable scaffold DREAMS 3G was designed as a third-generation development of its predecessor, the Magmaris scaffold.

AIMS

This preclinical study aimed to examine the qualitative and temporal course of the degradation of the DREAMS 3G relative to the Magmaris scaffold.

METHODS

Forty-nine DREAMS 3G and 24 Magmaris scaffolds were implanted into 48 mini swine for degradation kinetics analysis. Another DREAMS 3G was implanted into one mini swine for crystallinity analysis of the degradation end product after 730 days. Degradation kinetics were determined at 28, 90, 120, 180, and 365 days.

RESULTS

Discontinuity density in DREAMS 3G was significantly lower than that in Magmaris scaffolds for the follow-up timepoints of 90 and 120 days. Planimetric analysis indicated 99.6% backbone degradation for DREAMS 3G at 12 months. Compared to the Magmaris scaffold, individual strut degradation in DREAMS 3G showed less variability and the remaining backbone core was more homogeneous. The degradation end product of DREAMS 3G manifested as calcium phosphate with a minor share of aluminium phosphate.

CONCLUSIONS

DREAMS 3G showed almost complete degradation after one year, with amorphous calcium and aluminium phosphate as the end products of degradation. Despite its thinner struts, scaffold discontinuity was significantly lower in the DREAMS 3G than in the Magmaris scaffold, likely providing a longer scaffolding time.

摘要

背景

新型西罗莫司洗脱可吸收支架 DREAMS 3G 是在前驱体 Magmaris 支架的基础上进行第三代开发的。

目的

本临床前研究旨在检测 DREAMS 3G 相对于 Magmaris 支架的定性和时间降解过程。

方法

将 49 个 DREAMS 3G 和 24 个 Magmaris 支架植入 48 头小型猪体内进行降解动力学分析。另一根 DREAMS 3G 植入一头小型猪体内,在 730 天后对降解终产物的结晶度进行分析。在 28、90、120、180 和 365 天分别进行降解动力学检测。

结果

在 90 和 120 天的随访时间点,DREAMS 3G 的不连续性密度明显低于 Magmaris 支架。平面分析显示,DREAMS 3G 在 12 个月时的支架降解率为 99.6%。与 Magmaris 支架相比,DREAMS 3G 中单个支架的降解具有更小的变异性,并且剩余的支架核心更加均匀。DREAMS 3G 的降解终产物表现为钙磷,含有少量的铝磷。

结论

DREAMS 3G 在一年后几乎完全降解,降解终产物为无定形的钙和铝磷。尽管 DREAMS 3G 的支架更薄,但与 Magmaris 支架相比,其不连续性明显更低,这可能提供了更长的支架支撑时间。

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