Faculty
of Medicine and Health Sciences
Department of Circulation and medical imaging
Strain rate imaging.
Myocardial deformation mechanics.
Revised edition 2023
by
Asbjørn
Støylen, Professor, Dr. Med
asbjorn.stoylen@ntnu.no
@strain_rate.bsky.social
Portal to deformation imaging and myocardial mechanics for
the novice researcher and curious clinician
- Imaging measures shortening, not contraction, nor
contractility. There is not a direct correspondence between contraction
(tension) / relaxation (tension devolution) and shortening / lengthening.
- Strain and strain rate are measures related to
relative volume changes (EF), and are thus functions of tension vs. load,
and not measures of contraction ( tension) nor contractility.
- Length and velocity are both related to volume changes,
and are the resultant of tension vs. load.
- MAPSE is proportional
to stroke volume, and the ratio of MAPSE to SV is constant across both
BSA and Age.
- Both E and e' are
related to tension vs load, and e' is not the cause of early pressure
changes.
- The concept that the
E/e' ratio is due to the fact that e' is the cause of pressures, while
flow is the result, is erroneous. The discrepancy is due to the fact
that while flow velocity is related to pressure gradients, tissue
velocity is related to volume flow, and thus to early compliance.
Summary on global longitudinal strain GLS
Welcome to the
revised strain rate website
Animations will still be in *.GIF format, so they will run on web browsers, and
can be embedded in presentations. Pictures and animations are still free to
use, with due credit.
Strain and strain rate are the concepts of myocardial deformation. My basic
views are still that
- Any imaging method deals with myocyte shortening,
myocyte shortening is always a function of tension versus load, and thus any imaging method and measure is load dependent,
including deformation and deformation derived measures.
- The three strain components are only coordinates of
the total three dimensional deformation of one object - the myocardium,
and thus interdependent, but also meaning that longitudinal strain carries
most of the information
- Longitudinal strain is method dependent, so there
is no gold standard
- Gradient of longitudinal layer strain, is just an
artefact of speckle tracking, tracking the inward motion, which increases
towards the endocardium.
- Gradient of circumferential and transmural strain
are just a function of inward expansion into a progressively smaller space
toward the center of the left ventricle, i.e. geometry, not differential
layer function.
- For global function, annular motion (displacement and velocity are
basically as useful as global strain and strain rate,
- Except in the right ventricle where deformation is superior,
- But when there is regional dysfunction, annular motion is not enough, deformation imaging
is necessary, but as an adjunct method to B-mode.
- Peak values are less
useful, qualitative and semi-qualitative information is more important:
curve shapes or colour M-mode, the typical acute ischemic segmental
pattern is:
- Delayed onset of
shortening
- Reduced rate and
amount of shortening
- post systolic shortening
Website index:
Basic ultrasound
This section replaces the sections on
- Basic ultrasound
- Doppler
- Strain ultrasound
- Problems and pitfalls
Basic concepts of motion and deformation
This section replaces the two old sections:
- Basic concepts of motion and deformation
- Basic concepts in myocardial strain and strain rate
Basic physiology
This section deals with the basic physiology as seen with various echo methods,
and replaces most of
- Basic physiological concepts in strain and strain rate
- What does strain and strain rate actually measure?
- Global systolic functional imaging
- Regional systolic functional imaging.
- Diastolic functional imaging
In the physiological aspects, as these were largely
overlapping anyway.
References
have been updated, but will still be revised, especially for
the basic ultrasound section.