Clinical 1H magnetic resonance spectroscopy of brain metastases at 1.5T and 3T.

PURPOSE: To investigate whether improvements in signal-to-noise ratio (SNR) and spectral resolution are found in spectra from patients with brain metastases obtained at higher magnetic field strengths using standard clinical instrumentation. MATERIAL AND METHODS: Six patients with brain metastases, 13 healthy volunteers, and a phantom containing brain metabolites were examined using two clinical MR instruments operating at 1.5T (Siemens) and 3T (Philips) with standard clinical head coils. Spectra were obtained using a point resolved spectroscopy pulse sequence, echo times (TE) 32 ms and 144 ms, and repetition time 2000 ms from a volume-of-interest (VOI) of size 15 x 15 x 15 mm3. SNR and spectral resolution of the metabolites N-acetylaspartate, choline, and creatine compounds in spectra from 3T were compared to the 1.5T spectra. RESULTS: In general, spectral resolution was improved by 25-30% at higher magnetic field strength. Only minor improvements in SNR were obtained at 3T using short echo time and 20-50% at long echo time. CONCLUSION: SNR and spectral resolution were improved at higher magnetic field strength, especially with TE 144 ms, including spectra from patients with heterogeneous brain tumors. However, differences in the defined effective VOI, particularly at short echo time, reduced the expected effect of increased magnetic field strength on the measured SNR.

External standard method for the in vivo quantification of choline-containing compounds in breast tumors by proton MR spectroscopy at 1.5 Tesla.

Quantification of choline-containing compounds observed with (1)H MRS of breast tumors is of interest since such compounds have been linked to malignancy. Experiments were performed at 1.5 T with an external standard containing phosphocholine for calibration. In phantom studies, good precision was achieved after correction for T(1)/T(2) effects. T(2) values for choline were estimated for two breast cancer patients. A choline concentration of 2.0 mM was calculated for a third patient, a result comparable to in vitro findings. Magn Reson Med 46:189-192, 2001.

Effects of hyperthermia on bioenergetic status and phosphorus T1S in human melanoma xenografts monitored by 31P-MRS.

Conventional hyperthermia enhances tumor response to radiotherapy through thermal cell inactivation and vascular shut-down, whereas mild hyperthermia potentiates the effect of radiotherapy by improving tumor oxygenation. The work reported here was aimed at investigating whether 31P-magnetic resonance spectroscopy (31P-MRS) measurements of tumor bioenergetic status; i.e., the (PCr + NTPbeta)/Pi resonance ratio, and/or the spin lattice relaxation times, T1s, of the Pi and NTPbeta resonances can be used to distinguish between the effects of conventional and mild hyperthermia. BEX-t human melanoma xenografts were treated at 43.0 degrees C for 15 or 60 min, and bioenergetic status and T1s were measured as function-of-time after treatment. Hyperthermia-induced effects on tumor blood flow was measured by using the 86Rb uptake method. The morphology of the capillary network in treated and untreated tumors was studied by histologic examination. Tumors treated for 15 min showed increased blood flow and dilated capillaries, whereas tumors treated for 60 min showed decreased blood flow and capillary occlusions; i.e., 43.0 degrees C for 15 min was a treatment consistent with mild hyperthermia and 43.0 degrees C for 60 min was consistent with conventional hyperthermia treatment of BEX-t tumors. Bioenergetic status increased after treatment at 43.0 degrees C for 15 min, and decreased after treatment at 43.0 degrees C for 60 min, similar to the blood flow. Likewise, the T1 of the Pi resonance increased after treatment at 43.0 degrees C for 15 min, and decreased after treatment at 43.0 degrees C for 60 min. The T1 of the NTPbeta resonance showed a similar change as the T1 of the Pi resonance, but less pronounced. Consequently, 31P-MRS measurements of tumor bioenergetic status and the T1 of the Pi resonance may perhaps be utilized to distinguish between vascular effects of mild and conventional hyperthermia.

In vivo 1H MRS of normal breast and breast tumors using a dedicated double breast coil.

Image-guided localized proton MR spectroscopy (MRS) of normal breasts and breast tumors (ductal and undifferentiated carcinomas) was performed using a dedicated double breast coil. In vivo 1H MR spectra from 10 normal volunteers showed signals from water and lipids only, even in breasts with small contribution of fatty breast tissue. In the spectra from 6 of the 12 examined patients, an intense signal assigned to choline compounds was detected. The signal was also detected at lower levels in the remaining patients. This study shows that in vivo 1H MRI/MRS examinations of breast tumors can be performed within an examination time of 45 to 60 minutes. Signals from breast tumor metabolites may be detected using in vivo 1H MRS.