166Ho聚l -乳酸微球放射栓塞剂量学研究：死区时间对预测能力的影响。

IF 3 2区医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

EJNMMI Physics Pub Date : 2025-07-03 DOI:10.1186/s40658-025-00779-8

Bartolomeo Cassano, Ludovica Miseo, Sara Ungania, Marco D'Andrea, Federica Murtas, Massimiliano Pacilio, Marta Bottero, Daria Maccora, Rosa Sciuto, Giulio Eugenio Vallati, Antonella Soriani, Giuseppe Iaccarino

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The mean absorbed dose (AD) and distribution were calculated using the Local Energy Deposition (LED) method for liver, healthy liver (HL) and tumor contours. Three methods were compared for TA AD estimation: no DT correction (M1), whole-image DT correction (M2), and DT correction only for tumor ROI counts (M3). Linear correlation and percentage differences (ΔD%) between SA and TA AD were analyzed. AD distributions in SA and TA were rigidly registered for gamma index analysis (Dose Difference of 10% and Distance to Agreement of 10 mm).Results: DT effects were significant for activity above 250 MBq (> 11.5%). Strong linear correlations between mean AD values in SA and TA were observed across methods. ΔD% between SA and TA for the liver contour was - 8.6% (M1), 21.5% (M2), and 8.2% (M3). For the HL contour, ΔD% was 8.1% (M1) and 39.0% (M2), while for the tumor contour, it was - 20.1% (M1) and 0.0% (M2). 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引用次数: 0

摘要

背景：与90Y相比，166ho -聚l -乳酸微球（166Ho-PLLA）在放射栓塞治疗中使用相同的微球（SA和TA）具有优势。本研究旨在量化和纠正剂量估计中的死区时间（DT）效应，并评估SA对TA的预测能力。方法：将1.9 GBq的166Ho-PLLA活动源置于CIRS幻象中，并在一周内成像，直到活动达到83 MBq，评估DT效果。15例单肝病变患者分别在两周内接受了SA和TA检查，并进行了SPECT/CT成像。采用局部能量沉积（LED）法计算肝脏、健康肝脏（HL）和肿瘤轮廓的平均吸收剂量（AD）和分布。比较了三种TA AD估计方法：不进行DT校正（M1）、整幅图像DT校正（M2）和仅对肿瘤ROI计数进行DT校正（M3）。分析SA与TA AD的线性相关及百分比差异（ΔD%）。SA和TA的AD分布严格登记用于伽马指数分析（剂量差为10%，一致距离为10 mm）。结果：活性在250 MBq以上时，DT效应显著（> 11.5%）。在不同的方法中，SA和TA的平均AD值之间存在很强的线性相关性。ΔD肝廓线SA与TA的比值分别为- 8.6% （M1）、21.5% （M2）和8.2% （M3）。对于HL轮廓，ΔD%为8.1% （M1）和39.0% (M2)，而对于肿瘤轮廓，ΔD%为- 20.1% （M1）和0.0% （M2）。肝脏轮廓γ指数合格率分别为76% （M1）、89% （M2）和92% (M3)；HL轮廓为80% （M1）和75% (M2)；肿瘤轮廓为70% （M1）和87% （M2）。结论：DT显著影响TA剂量估计，尤其是肿瘤。适当的DT校正提高了166Ho-PLLA对肝脏和转移瘤中TA的剂量学评估的准确性，得到的剂量值更接近于SA中获得的剂量值，尽管后者没有进行DT校正。

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Dosimetric study on radioembolization with 166Ho poly L-lactic acid microspheres: dead time effects on prediction power.

Background: ¹⁶⁶Ho-poly-L-lactic acid microspheres (¹⁶⁶Ho-PLLA) offer the advantage of using the same microspheres for both Scout and Therapeutic Administrations (SA and TA) in radioembolization compared to ⁹⁰Y. This study aimed to quantify and correct dead time (DT) effects in dose estimation and assess the predictive power of SA on TA.

Methods: A 1.9 GBq ¹⁶⁶Ho-PLLA activity source was placed in a CIRS phantom and imaged over a week until activity reached 83 MBq, assessing DT effects. Fifteen patients with a single hepatic lesion underwent SA and TA two weeks apart with following SPECT/CT imaging. The mean absorbed dose (AD) and distribution were calculated using the Local Energy Deposition (LED) method for liver, healthy liver (HL) and tumor contours. Three methods were compared for TA AD estimation: no DT correction (M1), whole-image DT correction (M2), and DT correction only for tumor ROI counts (M3). Linear correlation and percentage differences (ΔD%) between SA and TA AD were analyzed. AD distributions in SA and TA were rigidly registered for gamma index analysis (Dose Difference of 10% and Distance to Agreement of 10 mm).

Results: DT effects were significant for activity above 250 MBq (> 11.5%). Strong linear correlations between mean AD values in SA and TA were observed across methods. ΔD% between SA and TA for the liver contour was - 8.6% (M1), 21.5% (M2), and 8.2% (M3). For the HL contour, ΔD% was 8.1% (M1) and 39.0% (M2), while for the tumor contour, it was - 20.1% (M1) and 0.0% (M2). Gamma index pass rates for the liver contour were 76% (M1), 89% (M2), and 92% (M3); for the HL contour, 80% (M1) and 75% (M2); and for the tumor contour, 70% (M1) and 87% (M2).

Conclusion: DT significantly affects TA dose estimation, particularly in tumors. Proper DT correction improves the accuracy of dosimetric evaluation of ¹⁶⁶Ho-PLLA for TA in liver and metastases, yielding dose values closer to those obtained in SA, despite the latter not being corrected for DT.

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来源期刊

EJNMMI Physics Physics and Astronomy-Radiation

CiteScore

6.70

自引率

10.00%

发文量

审稿时长

13 weeks

期刊介绍： EJNMMI Physics is an international platform for scientists, users and adopters of nuclear medicine with a particular interest in physics matters. As a companion journal to the European Journal of Nuclear Medicine and Molecular Imaging, this journal has a multi-disciplinary approach and welcomes original materials and studies with a focus on applied physics and mathematics as well as imaging systems engineering and prototyping in nuclear medicine. This includes physics-driven approaches or algorithms supported by physics that foster early clinical adoption of nuclear medicine imaging and therapy.