In-target production of [11C]CH4 from a nitrogen/hydrogen gas target as a function of beam current, irradiation time, and target temperature

IF 4.4 Q1 CHEMISTRY, INORGANIC & NUCLEAR

EJNMMI Radiopharmacy and Chemistry Pub Date : 2024-03-25 DOI:10.1186/s41181-024-00255-1

Semi Helin, Johan Rajander, Jussi Aromaa, Eveliina Arponen, Jatta S. Helin, Olof Solin

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引用次数: 0

Abstract

Background

Production of [¹¹C]CH₄ from gas targets is notorious for weak performance with respect to yield, especially when using high beam currents. Post-target conversion of [¹¹C]CO₂ to [¹¹C]CH₄ is a widely used roundabout method in ¹¹C-radiochemistry, but the added complexity increase the challenge to control carrier carbon. Thus in-target-produced [¹¹C]CH₄ is superior with respect to molar activity. We studied the in-target production of [¹¹C]CO₂ and [¹¹C]CH₄ from nitrogen gas targets as a function of beam current, irradiation time, and target temperature.

Results

[¹¹C]CO₂ production was practically unchanged across the range of varied parameters, but the [¹¹C]CH₄ yield, presented in terms of saturation yield Y_SAT(¹¹CH₄), had a negative correlation with beam current and a positive correlation with target chamber temperature. A formulated model equation indicates behavior where the [¹¹C]CH₄ formation follows a parabolic graph as a function of beam current. The negative square term, i.e., the yield loss, is postulated to arise from Haber–Bosch-like NH₃ formation: N₂ + 3H₂ → 2NH₃. The studied conditions suggest that the NH₃ (liq.) would be condensed on the target chamber walls, thus depleting the hydrogen reserve needed for the conversion of nascent ¹¹C to [¹¹C]CH₄.

Conclusions

[¹¹C]CH₄ production can be improved by increasing the target chamber temperature, which is presented in a mathematical formula. Our observations have implications for targetry design (geometry, gas volume and composition, pressure) and irradiation conditions, providing specific knowledge to enhance [¹¹C]CH₄ production at high beam currents. Increased [¹¹C]CH₄ radioactivity is an obvious benefit in radiosynthesis in terms of product yield and molar radioactivity.

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氮氢气靶靶内产生的[11C]CH4与束流、辐照时间和靶温的函数关系

背景从气体靶材中制备[11C]CH4因其产率低而臭名昭著，尤其是在使用高束流时。目标后将 [11C]CO2 转化为[11C]CH4 是 11C 放射化学中广泛使用的迂回方法，但增加的复杂性增加了控制载碳的挑战。因此，靶内产生的[11C]CH4 在摩尔活性方面更具优势。我们研究了氮气靶的靶内产[11C]CO2 和[11C]CH4 与束流、辐照时间和靶温度的函数关系。结果[11C]CO2 的产量在不同参数范围内几乎没有变化，但以饱和产量 YSAT(11CH4) 表示的[11C]CH4 产量与束流呈负相关，与靶室温度呈正相关。所建立的模型方程表明，[11C]CH4 的形成与束流的函数关系呈抛物线形。据推测，负平方项（即产量损失）是由类似哈伯-博什的 NH3 形成引起的：N2 + 3H2 → 2NH3。研究条件表明，NH3（液态）会凝结在靶室壁上，从而耗尽新生 11C 转化为[11C]CH4 所需的氢储备。我们的观察结果对靶室设计（几何形状、气体体积和成分、压力）和辐照条件都有影响，为在高束流条件下提高[11C]CH4产量提供了具体的知识。提高[11C]CH4的放射性在放射合成中对产品产量和摩尔放射性都有明显的好处。

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来源期刊

EJNMMI Radiopharmacy and Chemistry Multiple-

CiteScore

7.20

自引率

8.70%

发文量

审稿时长

5 weeks