@15:48 The student ask how to measure T1. It becomes apparent that this question was inserted in post editing as the audio is different and there is a student missing from the table. Most importantly, this section is confusing and I did not understand it because the instructor is using terms and processes that have not been yet described in previous videos (TR and TE).

best ever series of lectures i have ever watched

6:20 In principle loss of coherence (transverse relaxation) can happen without loss of energy. 8:30 Mistake: NO it is not a logarithm grow it is 1-e(-t/T1). 18:51 He has not yet defined TE or TR but he uses both in explaining how to measure T1.

Hello fellow struggling MRI learners, don't worry if you don't understand the very last bit of the video about how to measure T1. It makes a lot more sense if you watch the rest of the series first. Best of luck!

I skipped back to hear how TE came in and was like "THAT'S THE FOURTH TIME YOUR PHONE HAS GONE OFF PUT IT ON VIBRATE!!" Valid criticisms here I guess, consider them for the course, but excellent public good here, thank you.

Dr. Lipton is one my inspirational teachers, even I don´t know him in person.

63% comes from 1 - 1/e.

Great explanation!

Thanks for the awesome lecture Dr. Michael. My question is how are we detecting T1 relaxation from receiver coil, won't any coil in longitudinal direction will get overloaded with current induced by strong magnetic field. With Regards, Akshaykumar, Resident Radiology, Delhi

I have a question I can't seem to find anywhere, to anyone who can answer me (I'm Italian, so italian answers are also welcome). I understand that T1 and T2 are two different properties, the first one based on re-gaining of longitudinal magnetization (so, re-gaining of antiparallel precessing protons, taking B0 as the reference direction) and the latter based on losing of trasversal magentization (so, losing of phase coherence in the precession). But as different entities, how is there such a RF pulse that tilt by 90° the magnetization vector, so that the resulting transversal magnetization depends on the beginning longitudinal magnetization? Maximum longitudinal magnetization happens in resting condition, by the tiny difference in parallel and antiparallel precessing protons (6/10.000, as he says), while maximum transversal magnetization happens (i suppose) when the totality of the protons are in phase of precession. After a 90° RF pulse, parallel/antiparallel = 1 (so, parallel - antiparallel = 0, meaning that 6 protons over 10.000 swapped their verse) but I imagine that phase coherence involves much more than 6/10.000 protons. Why, if we apply another 90° RF pulse when longitudinal magnetizion has not totally recovered, the resulting transversal magnetization is also lower (meaning that not all the protons initially capable of gaining phase coherence gained it back)? Thanks to anyone who will answer (or at least, try to), it may be that some of my assumptions are wrong, correct me please if it is the case

Part of the video is missing

Can anyone explain what TR and TE is

Since the stronger magnets affect T1 by making it longer and minimize differences-- Q: Why bother with stronger magnetic field above 3T if it has affects that seems (as I understand) to minimize contrast? I really enjoy these videos! Thank you!

Must have missed something in the break :( TR? TE? Hopefully becomes clearer later.

Is regain of longitudinal magnetization and decay of transverse magnetization a simultaneous process with respect to a single proton?

Thanks dr

If T1 and T2 are happening at the same time, how cannot they be symmetric, I found it confusing

Good