Title :
Palm NMR and 1-Chip NMR
Author :
Sun, Nan ; Yoon, Tae-Jong ; Lee, Hakho ; Andress, William ; Weissleder, Ralph ; Ham, Donhee
Author_Institution :
Sch. of Eng. & Appl. Sci., Harvard Univ., Cambridge, MA, USA
Abstract :
In our earlier work, we developed a 2-kg NMR system, which was 60 X lighter, 40× smaller, yet 60× more spin-mass sensitive than a 120-kg state-of-the-art commercial benchtop system. Here we report on two new nuclear magnetic resonance (NMR) systems that represent further orders-of-magnitude size reduction and lab-on-a-chip capability. The first system, which weighs 0.1 kg and can be held in the palm of a hand, is the smallest NMR system ever built, and is 1200× lighter, 1200× smaller, yet 150× more spin-mass sensitive than the commercial system. It is enabled by combining the physics of NMR with a CMOS RF transceiver. The second system, which even integrates a sample coil, directly interfaces the CMOS chip with a sample for lab-on-a-chip operation. The two systems detect biological objects such as avidin, human chorionic gonadotropin, and human bladder cancer cells.
Keywords :
CMOS integrated circuits; biomagnetism; biomedical equipment; cancer; cellular biophysics; lab-on-a-chip; nuclear magnetic resonance; transceivers; 1-chip NMR; CMOS RF transceiver; CMOS chip; avidin; human bladder cancer cells; human chorionic gonadotropin; lab-on-a-chip capability; lab-on-a-chip operation; mass 0.1 kg; nuclear magnetic resonance system; orders-of-magnitude size reduction; palm NMR; spin-mass sensitive; CMOS integrated circuits; Coils; Magnetic separation; Nuclear magnetic resonance; Radio frequency; Transceivers; Biosensors; CMOS; lab on a chip; nuclear magnetic resonance (NMR); radio-frequency integrated circuits(RFICs);
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2010.2074630
