論文雑誌「Analyst」のカバーピクチャーを制作しました[理化学研究所]
弊社で制作しました理化学研究所 神隆様のカバーアートが
イギリスの王立化学会発行の学術雑誌 Analyst 2022年10月号に選ばれました。
Client
国立研究開発法人理化学研究所
生命機能科学研究センター
神隆様
生命機能科学研究センター
神隆様
Journal
Analyst
07 October 2022, Issue 19 Link
07 October 2022, Issue 19 Link
A near-infrared fluorescent long-chain fatty acid toward optical imaging of cardiac metabolism in living mice
Mahadeva M. M. Swamy, Mohamad Zarif Mohd Zubir, Mutmainah, Setsuko Tsuboi, Yuta Murai, Kenji Monde, Ken-ichi Hirano and Takashi Jin
Non-invasive fatty acid (FA) metabolic imaging is crucial for the evaluation of cardiac function in the heart. Currently, single-photon emission computed tomography (SPECT) and positron emission tomography (PET) are widely employed for cardiac metabolic imaging both in pre-clinical and clinical studies. Although SPECT and PET enable highly sensitive cardiac metabolic imaging, there are several disadvantages such as the high cost of instruments and radioactive tracer synthesis. In contrast, near-infrared (NIR) optical imaging using fluorescent FAs provides a simple and useful platform for in vivo imaging of cardiac metabolism. In this work, we synthesized a NIR fluorescence labelled long-chain fatty acid (LCFA) for real-time imaging of cardiac metabolism in vivo. A NIR fluorescence labelled LCFA was designed as an analogue of β-methyl [123I] iodophenyl-pentanedecanoic acid (123I-BMIPP), which is widely used for the diagnosis of heart diseases in clinical practice. As a NIR fluorescent label, we used an Alexa 680 fluorophore that emits over 700 nm. By conjugation of Alexa 680 to Amino-BMPP (15-(4-(3-aminopropyl)phenyl)-3-methylpentadecanoic acid), we prepared a NIR fluorescent BMIPP analogue, Alexa680-BMPP. NIR fluorescence imaging showed that Alexa680-BMPP is taken up by the mouse heart tissue after intravenous injection, showing that Alexa680-BMPP can act as a fluorescent LCFA analogue. Among Alexa680 conjugated FA analogues including short and middle chain NIR fluorescent FAs, Alexa680-BMPP was most efficiently taken up by heart tissues. For fasted and fed mice, the difference in the degree of the uptake of Alexa680-BMPP in their heart tissues was clearly observed by in vivo and ex vivo NIR fluorescence imaging. Herein, we present the synthesis of a NIR fluorescent LCFA, Alexa680-BMPP, and its capability for real-time optical imaging of cardiac metabolism in living mice.
Link
Mahadeva M. M. Swamy, Mohamad Zarif Mohd Zubir, Mutmainah, Setsuko Tsuboi, Yuta Murai, Kenji Monde, Ken-ichi Hirano and Takashi Jin
Non-invasive fatty acid (FA) metabolic imaging is crucial for the evaluation of cardiac function in the heart. Currently, single-photon emission computed tomography (SPECT) and positron emission tomography (PET) are widely employed for cardiac metabolic imaging both in pre-clinical and clinical studies. Although SPECT and PET enable highly sensitive cardiac metabolic imaging, there are several disadvantages such as the high cost of instruments and radioactive tracer synthesis. In contrast, near-infrared (NIR) optical imaging using fluorescent FAs provides a simple and useful platform for in vivo imaging of cardiac metabolism. In this work, we synthesized a NIR fluorescence labelled long-chain fatty acid (LCFA) for real-time imaging of cardiac metabolism in vivo. A NIR fluorescence labelled LCFA was designed as an analogue of β-methyl [123I] iodophenyl-pentanedecanoic acid (123I-BMIPP), which is widely used for the diagnosis of heart diseases in clinical practice. As a NIR fluorescent label, we used an Alexa 680 fluorophore that emits over 700 nm. By conjugation of Alexa 680 to Amino-BMPP (15-(4-(3-aminopropyl)phenyl)-3-methylpentadecanoic acid), we prepared a NIR fluorescent BMIPP analogue, Alexa680-BMPP. NIR fluorescence imaging showed that Alexa680-BMPP is taken up by the mouse heart tissue after intravenous injection, showing that Alexa680-BMPP can act as a fluorescent LCFA analogue. Among Alexa680 conjugated FA analogues including short and middle chain NIR fluorescent FAs, Alexa680-BMPP was most efficiently taken up by heart tissues. For fasted and fed mice, the difference in the degree of the uptake of Alexa680-BMPP in their heart tissues was clearly observed by in vivo and ex vivo NIR fluorescence imaging. Herein, we present the synthesis of a NIR fluorescent LCFA, Alexa680-BMPP, and its capability for real-time optical imaging of cardiac metabolism in living mice.
Link
