TY - JOUR
T1 - In-target production of [11C]CH4 from a nitrogen/hydrogen gas target as a function of beam current, irradiation time, and target temperature
AU - Helin, Semi
AU - Rajander, Johan
AU - Aromaa, Jussi
AU - Arponen, Eveliina
AU - Helin, Jatta S.
AU - Solin, Olof
PY - 2024/3/25
Y1 - 2024/3/25
N2 - Background: Production of [
11C]CH
4 from gas targets is notorious for weak performance with respect to yield, especially when using high beam currents. Post-target conversion of [
11C]CO
2 to [
11C]CH
4 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]CH
4 is superior with respect to molar activity. We studied the in-target production of [
11C]CO
2 and [
11C]CH
4 from nitrogen gas targets as a function of beam current, irradiation time, and target temperature. Results: [
11C]CO
2 production was practically unchanged across the range of varied parameters, but the [
11C]CH
4 yield, presented in terms of saturation yield Y
SAT(
11CH
4), had a negative correlation with beam current and a positive correlation with target chamber temperature. A formulated model equation indicates behavior where the [
11C]CH
4 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 NH
3 formation: N
2 + 3H
2 → 2NH
3. The studied conditions suggest that the NH
3 (liq.) would be condensed on the target chamber walls, thus depleting the hydrogen reserve needed for the conversion of nascent
11C to [
11C]CH
4. Conclusions: [
11C]CH
4 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]CH
4 production at high beam currents. Increased [
11C]CH
4 radioactivity is an obvious benefit in radiosynthesis in terms of product yield and molar radioactivity.
AB - Background: Production of [
11C]CH
4 from gas targets is notorious for weak performance with respect to yield, especially when using high beam currents. Post-target conversion of [
11C]CO
2 to [
11C]CH
4 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]CH
4 is superior with respect to molar activity. We studied the in-target production of [
11C]CO
2 and [
11C]CH
4 from nitrogen gas targets as a function of beam current, irradiation time, and target temperature. Results: [
11C]CO
2 production was practically unchanged across the range of varied parameters, but the [
11C]CH
4 yield, presented in terms of saturation yield Y
SAT(
11CH
4), had a negative correlation with beam current and a positive correlation with target chamber temperature. A formulated model equation indicates behavior where the [
11C]CH
4 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 NH
3 formation: N
2 + 3H
2 → 2NH
3. The studied conditions suggest that the NH
3 (liq.) would be condensed on the target chamber walls, thus depleting the hydrogen reserve needed for the conversion of nascent
11C to [
11C]CH
4. Conclusions: [
11C]CH
4 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]CH
4 production at high beam currents. Increased [
11C]CH
4 radioactivity is an obvious benefit in radiosynthesis in terms of product yield and molar radioactivity.
KW - Carbon-11
KW - Haber-Bosch
KW - Pet
KW - Targetry
KW - [C-11]methane
UR - https://www.webofscience.com/api/gateway?GWVersion=2&SrcApp=aboakademi&SrcAuth=WosAPI&KeyUT=WOS:001190943200001&DestLinkType=FullRecord&DestApp=WOS_CPL
U2 - 10.1186/s41181-024-00255-1
DO - 10.1186/s41181-024-00255-1
M3 - Article
C2 - 38526746
SN - 2365-421X
VL - 9
JO - EJNMMI Radiopharmacy and Chemistry
JF - EJNMMI Radiopharmacy and Chemistry
IS - 1
M1 - 24
ER -