Improved Spectral Inversion of Blood Oxygenation due to Reduced Tissue Scattering: Towards NIR-II Photoacoustic Imaging

Vinoin Devpaul Vincely, Carolyn L Bayer
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Abstract

Significance: Conventional spectral photoacoustic imaging (sPAI) to assess tissue oxygenation (sO2) uses optical wavelengths in the first near infrared window (NIR-I). This limits the maximum imaging depth (~1 cm) due to high spectral coloring of biological tissues. Aim: Second near infrared or short-wave infrared (NIR-II or SWIR) wavelengths (950-1400 nm) show potential for deep tissue sPAI due to the exponentially reduced tissue scattering and higher maximum exposure threshold (MPE) in this wavelength range. However, to date, a systematic assessment of NIR-II wavelengths for sPAI of tissue sO2 has yet to be performed. Approach: The NIR-II PA spectra of oxygenated and deoxygenated hemoglobin was first characterized using a phantom. Optimal wavelengths to minimize spectral coloring were identified. The resulting NIR-II PA imaging methods were then validated in vivo by measuring renal sO2 in adult female rats. Results: sPAI of whole blood under a phantom and of circulating renal blood in vivo, demonstrated PA spectra proportional to wavelength-dependent optical absorption. NIR-II wavelengths had a ~50% decrease in error of spectrally unmixed blood sO2 compared to conventional NIR-I wavelengths. In vivo measurements of renal sO2 validated these findings and demonstrated a ~30% decrease in error of estimated renal sO2 when using NIR-II wavelengths for spectral unmixing in comparison to NIR-I wavelengths. Conclusions: sPAI using NIR-II wavelengths improved the accuracy of tissue sO2 measurements. This is likely due to the overall reduced spectral coloring in this wavelength range. Combined with the increased safe skin exposure fluence limits in this wavelength range, demonstrate the potential to use NIR-II wavelengths for quantitative sPAI of sO2 from deep heterogeneous tissues.
减少组织散射,改善血液含氧量的光谱反演:实现近红外-II 光声成像
意义重大:用于评估组织氧饱和度(sO2)的传统光谱光声成像(sPAI)使用的是第一近红外窗口(NIR-I)的光波长。由于生物组织的光谱着色较高,这限制了最大成像深度(约 1 厘米)。目的:第二近红外或短波红外(NIR-II 或 SWIR)波长(950-1400 nm)显示了深部组织 sPAI 的潜力,因为在此波长范围内,组织散射呈指数减少,最大曝光阈值(MPE)较高。然而,迄今为止,尚未对 NIR-II 波长用于组织 sO2 的 sPAI 进行系统评估。方法:首先使用一个模型对含氧和脱氧血红蛋白的近红外-II PA 光谱进行表征。确定了使光谱着色最小化的最佳波长。然后,通过测量成年雌性大鼠的肾脏 sO2,在体内验证了由此产生的 NIR-II PA 成像方法。结果:模型下的全血和体内循环肾脏血液的 sPAI 显示 PA 光谱与依赖波长的光吸收成正比。与传统的近红外 I 波长相比,近红外 II 波长的光谱不混血 sO2 误差减少了约 50%。肾脏 sO2 的活体测量验证了这些发现,与 NIR-I 波长相比,使用 NIR-II 波长进行光谱解混合时,估计的肾脏 sO2 误差降低了约 30%。结论:使用 NIR-II 波长的 sPAI 提高了组织 sO2 测量的准确性。这可能是由于该波长范围内的光谱着色总体上有所减少。再加上该波长范围内皮肤安全暴露通量限制的提高,证明了使用 NIR-II 波长对深部异质组织的 sO2 进行定量 sPAI 的潜力。
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