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声带小结和水肿可能是由振动引起的毛细血管压力升高所致。

Vocal nodules and edema may be due to vibration-induced rises in capillary pressure.

作者信息

Czerwonka Lukasz, Jiang Jack J, Tao Chao

机构信息

Department of Surgery, Division of Otolaryngology Head and Neck Surgery, University of Wisconsin School of Medicine and Public Health, Madison, Wisconsin 53706, USA.

出版信息

Laryngoscope. 2008 Apr;118(4):748-52. doi: 10.1097/MLG.0b013e31815fdeee.

DOI:10.1097/MLG.0b013e31815fdeee
PMID:18300711
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6622176/
Abstract

HYPOTHESIS

Vocal fold vibration may physically raise intravascular pressure to levels high enough to damage capillaries and result in leakage of erythrocytes. This type of injury is commonly seen in benign vocal fold lesions and is not well explained.

STUDY DESIGN

Theoretical, retrospective.

METHODS

The relationship of intravascular pressure to vibration frequency and amplitude is derived and confirmed with a physical blood vessel model, then applied to published human measurements to estimate human intravascular pressures.

RESULTS

Vocal fold intravascular pressure is predicted to have a quadratic dependence on both frequency and amplitude. During speaking, the pressure may rise to over 20 cmH2O, and may reach levels far higher for screaming and singing. Such pressure magnitudes are known to trigger inflammatory cascades and can lead to fluid leakage. They also have the potential for pharmacologic control with beta-agonists.

CONCLUSIONS

Intravascular pressure likely rises significantly during vocal fold vibration and may lead to the type of injury seen in benign vocal fold lesions. The results support voice therapy aimed at reducing vibratory amplitude. More vibratory amplitude measurements need to be performed in a wider range of subjects before the full range of human vocal fold vascular pressures can be estimated.

摘要

假说

声带振动可能会使血管内压力升高到足以损伤毛细血管并导致红细胞渗漏的水平。这种损伤在良性声带病变中很常见,但目前尚未得到很好的解释。

研究设计

理论性、回顾性研究。

方法

推导血管内压力与振动频率和振幅之间的关系,并通过物理血管模型进行验证,然后将其应用于已发表的人体测量数据,以估算人体血管内压力。

结果

预计声带血管内压力对频率和振幅均呈二次方依赖关系。在说话时,压力可能会升至超过20 cmH₂O,而在尖叫和唱歌时可能会达到更高的水平。已知这样的压力大小会引发炎症级联反应并导致液体渗漏。它们也有可能通过β受体激动剂进行药物控制。

结论

声带振动期间血管内压力可能会显著升高,并可能导致良性声带病变中出现的那种损伤。研究结果支持旨在降低振动幅度的嗓音治疗。在能够估算出完整的人类声带血管压力范围之前,需要在更广泛的受试者中进行更多的振动幅度测量。

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