Surface alterations and chondrocyte activity in articular cartilage after monopolar radiofrequency treatment.

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The Journal of hand surgery, European volume Pub Date : 2026-05-06 DOI:10.1177/17531934261445820

Thomas Schmid, Max von Schmeling, Sebastian Gehmert, Lukas Prantl, Marc Ruewe, Michaela Huber

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Abstract

Introduction: Osteoarthritis is characterized by progressive degeneration of articular cartilage and impaired joint function. Arthroscopic monopolar radiofrequency energy chondroplasty enables minimally invasive smoothing of damaged cartilage surfaces, but there are concerns about chondrocyte viability under thermal stress, which is particularly critical in the wrist because of the thin cartilage layers and complex joint anatomy.

Methods: In this in vitro study, porcine tibial plateau cartilage with simulated Outerbridge grade III degeneration was treated using six monopolar radiofrequency energy application protocols, including continuous or pulsed modes with single or double passes. Subchondral temperature was recorded, surface roughness was quantified by confocal laser scanning microscopy using the root-mean-square parameter and chondrocyte viability was assessed using live/dead and caspase 3/7 assays.

Results: Subchondral temperatures remained below physiological core body temperature in all treatment groups. All radiofrequency energy protocols resulted in a clear reduction of surface roughness compared with degenerated control cartilage. The greatest smoothing effect was observed following a single pulsed application with longer activation intervals, although this also caused extensive chondrocyte death. Shorter pulsed application intervals produced moderate surface smoothing while preserving comparatively higher chondrocyte viability.

Conclusion: Monopolar radiofrequency energy chondroplasty effectively reduces cartilage surface roughness but is associated with substantial chondrocyte loss regardless of the application protocol. Among the tested approaches, pulsed energy delivery with short activation intervals provided the most favourable balance between surface smoothing and cell preservation. However, the in vivo safety of this approach remains uncertain, particularly when applied to thin cartilage layers such as those in the wrist.

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单极射频治疗后关节软骨的表面改变和软骨细胞活性。

骨关节炎的特点是关节软骨进行性变性和关节功能受损。关节镜下单极射频能量软骨成形术可以微创平滑受损软骨表面，但存在热应力下软骨细胞活力的问题，由于腕部软骨层薄且关节解剖复杂，热应力对软骨细胞活力尤其重要。方法：在这项体外研究中，采用六种单极射频能量应用方案治疗猪胫骨平台软骨模拟Outerbridge III级退变，包括连续或脉冲模式，单次或双次通过。记录软骨下温度，用共聚焦激光扫描显微镜用均方根参数量化表面粗糙度，用活/死和caspase 3/7测定软骨细胞活力。结果：各治疗组软骨下温度均低于生理核心体温。与退化的对照软骨相比，所有的射频能量方案都明显降低了表面粗糙度。在激活间隔较长的单脉冲应用后观察到最大的平滑效果，尽管这也引起广泛的软骨细胞死亡。较短的脉冲应用间隔产生适度的表面平滑，同时保持相对较高的软骨细胞活力。结论：单极射频能量软骨成形术有效地降低了软骨表面粗糙度，但无论应用方案如何，都与大量软骨细胞损失有关。在测试的方法中，短激活间隔的脉冲能量传递在表面平滑和细胞保存之间提供了最有利的平衡。然而，这种方法的体内安全性仍然不确定，特别是当应用于薄软骨层时，如手腕软骨层。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Journal of hand surgery, European volume

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