Gao Rongkang, Xu Hao, Liu Liangjian, Zhang Ying, Yin Ting, Zhou Huichao, Sun Mingjian, Chen Ningbo, Ren Yaguang, Chen Tao, Pan Yinhao, Zheng Mingbin, Ohulchanskyy Tymish Y, Zheng Rongqin, Cai Lintao, Song Liang, Qu Junle, Liu Chengbo
Research Laboratory for Biomedical Optics and Molecular Imaging, CAS Key Laboratory of Health Informatics, Shenzhen Institutes of Advanced Technology, Chinese Academy of Sciences, Shenzhen 518055, China.
These authors contributed equally to this work.
Biomed Opt Express. 2020 Jul 10;11(8):4203-4223. doi: 10.1364/BOE.395562. eCollection 2020 Aug 1.
This study investigates the fluence rate effect, an essential modulating mechanism of photodynamic therapy (PDT), by using photoacoustic imaging method. To the best of our knowledge, this is the first time that the fluence rate dependence is investigated at a microscopic scale, as opposed to previous studies that are based on tumor growth/necrosis or animal surviving rate. This micro-scale examination enables subtle biological responses, including the vascular damage and the self-healing response, to be studied. Our results reveal the correlations between fluence rate and PDT efficacy/self-healing magnitude, indicating that vascular injuries induced by high fluence rates are more likely to recover and by low fluence rates (≤126 mW/cm) are more likely to be permanent. There exists a turning point of fluence rate (314 mW/cm), above which PDT practically produces no permanent therapeutic effect and damaged vessels can fully recover. These findings have practical significance in clinical setting. For cancer-related diseases, the 'effective fluence rate' is useful to provoke permanent destruction of tumor vasculature. Likewise, the 'non effective range' can be applied when PDT is used in applications such as opening the blood brain barrier to avoid permanent brain damage.
本研究采用光声成像方法研究光动力疗法(PDT)的一个重要调节机制——fluence率效应。据我们所知,这是首次在微观尺度上研究fluence率依赖性,与以往基于肿瘤生长/坏死或动物存活率的研究不同。这种微观尺度的检查能够研究细微的生物学反应,包括血管损伤和自我修复反应。我们的结果揭示了fluence率与PDT疗效/自我修复程度之间的相关性,表明高fluence率诱导的血管损伤更有可能恢复,而低fluence率(≤126 mW/cm)诱导的血管损伤更有可能是永久性的。存在一个fluence率转折点(314 mW/cm),高于此点,PDT实际上不会产生永久性治疗效果,受损血管可以完全恢复。这些发现在临床环境中具有实际意义。对于癌症相关疾病,“有效fluence率”有助于引发肿瘤血管的永久性破坏。同样地,当PDT用于诸如打开血脑屏障等应用以避免永久性脑损伤时,可以应用“无效范围”。