A whole-body NMR imaging machine

Abstract

A nuclear magnetic resonance (NMR) machine capable of producing tomographic sections of the whole human body in vivo has been constructed. This system is based on a four coil, air-core electromagnet producing a field of 0.04 T which corresponds to a proton NMR frequency of 1.7 MHz. The images are produced line by line using a selective excitation technique. Magnetic field gradients up to about 5 mT/m are employed. Electronic subsystems are described here including a radiofrequency (RF) amplitude feedback circuit, an RF power amplifier, a transmit/receive switch, a receiver pre-amplifier and gradient coil drivers. For a single scan through a 10³ mm³ sample of human muscle tissue in vivo, the measured proton density uncertainty is 24% and the spin-lattice relaxation time (T₁) uncertainty is 74%. Phantom images using CuSO₄ solution and in vivo sections through human chest, thighs and head are presented. T₁ measurements of human muscle, liver and brain tissue in vivo give results which agree well with T₁ values for corresponding rabbit tissues measured in vitro.