This page is read only. You can view the source, but not change it. Ask your administrator if you think this is wrong. =====Specific Absorption Rate==== ====What is Specific Absorption Rate?==== Specific Absorption Rate, often shortened to SAR, is an estimate of the the RF energy (watts/kilogram) deposited into the patient while scanning that may result in body temperature rise. SAR is not an exact 'amount' of RF, nor a specific level of heating, but an estimate based on patient weight, orientation, pulse sequence, acquisition parameters, and scan time. Each MR vendor utilizes different modeling for estimating SAR, so there may not be a 1-to-1 comparison between scanners, but broadly several things regarding SAR are constant: * SAR will increase with field strength * SAR will be higher with pulse sequences that use a lot of strong RF pulses * SAR will be higher if strong RF pulses are closely spaced * SAR will be higher as the number of slices increases * SAR will be higher with many consecutive pulse sequences ====SAR and Scanning==== On even relatively older scanners, SAR is tracked throughout the scan, typically in 15 minute intervals. If the scanner senses SAR limits being exceeded, scanning will be prohibited and a 'cool down' time will have to elapse before scanning can resume. When scanning veterinary patients, body weights are typically far lower than the SAR model was meant to be used with, leading to inaccurate estimates and SAR errors preventing scanning unnecessarily. Additionally, animals under anesthesia do not have the same thermoregulatory capacity as when they're awake, often leading to patients being too cold despite what the scanner SAR level reads. Generally, the best approach is to maintain adequate patient temperature with blankets and warmers, and mitigate SAR errors so they don't prolong anesthesia time. ====Reducing SAR==== The first part of knowing how to reduce SAR errors is knowing where and when they are likely to occur: * Small animals; <10kgs * RF heavy pulse sequences: Fast spin echo, HASTE/ SS-FSE, FIESTA/TruFISP, IR-FSE * T1 weighting, due to the short [[time_to_repeat|TR]] FSE's * Large axial stacks of T1's * Post contrast imaging: lots of T1's back to back * Very high bandwidth sequences; results in shorter spacing between RF pulses SAR reduction strategies are pretty straightforward: reduce the amount, frequency, and strength of RF pulses! * Increase TR (but stay within contrast ranges!) * Reduce the number of slices * **Reduce the refocus flip angle for FSE's** * Use a GRE instead of an FSE * Choose Low SAR RF mode * Space out T1 FSE with T2's or GRE's While not explicitly a 'safe' thing to do, it is possible to trick the scanner with very very small patients by inputting a weight of 10kg or above.