Echocardiographic assessment for Cardiac Resynchronization Therapy
echocardiographic assessment for Cardiac Resynchronization Therapy (CRT), aligned with ACC/AHA/ESC practice, echo lab workflow, and NEET-SS / DM Cardiology expectations.
1. Objectives of Echocardiography in CRT
Echocardiography is used to:
- Select appropriate candidates
- Guide LV lead placement
- Optimize device programming
- Assess response and reverse remodeling
- Identify non-responders and causes of failure
2. Pre-CRT Echocardiographic Assessment (Eligibility)
A. Left Ventricular Systolic Function
| Parameter | Requirement |
|---|---|
| LVEF | ≤35% (biplane Simpson’s) |
| LV geometry | Dilated LV common |
| Global longitudinal strain (GLS) | Severely reduced (< −8 to −10%) |
GLS provides incremental prognostic value but is not mandatory for CRT eligibility.
B. LV Mechanical Dyssynchrony (Adjunctive, Not Mandatory)
⚠️ IMPORTANT: Current guidelines do NOT recommend echo-based dyssynchrony criteria for routine CRT selection, due to PROSPECT trial limitations.
Still tested in exams and useful in borderline cases.
1. M-Mode (Parasternal Long Axis)
- Septal–posterior wall motion delay (SPWMD)
- Significant if >130 ms
- Reflects interventricular mechanical delay
2. Tissue Doppler Imaging (TDI)
- Measure time-to-peak systolic velocity (Ts)
- Dyssynchrony if:
- Septal–lateral delay >65 ms
- Standard deviation of Ts (Ts-SD) >33 ms
3. Speckle Tracking Echo (Preferred)
- Radial / longitudinal strain delay
- Septal flash
- Apical rocking (highly predictive of CRT response)
Presence of septal flash or apical rocking = strong predictor of response
C. Atrioventricular and Interventricular Dyssynchrony
| Parameter | Abnormal |
|---|---|
| LV pre-ejection period | >140 ms |
| RV–LV pre-ejection delay | >40 ms |
| Mitral inflow | E/A fusion, short filling time |
D. Mitral Regurgitation Assessment
- Functional MR common
- Quantify:
- Vena contracta
- PISA (EROA)
- CRT reduces functional MR via reverse remodeling
3. Echocardiography for LV Lead Targeting (Advanced)
Goal
Place LV lead in latest-activated, viable myocardial segment, avoiding scar.
Techniques
- Speckle tracking strain mapping
- Identify segment with latest peak strain
- Contrast echo or CMR correlation for scar exclusion
Posterolateral or lateral wall is often optimal but patient-specific targeting improves response.
4. Post-CRT Echocardiographic Optimization
A. AV Delay Optimization
Methods:
- Mitral inflow method
- Optimize E–A separation
- LVOT VTI method
- Maximize stroke volume
Target:
- Longest LV filling time without E/A truncation
B. VV Delay Optimization
- Adjust RV vs LV pacing delay
- Echo marker: maximum LVOT VTI
- Limited routine use in modern devices (auto-algorithms common)
5. Response Assessment After CRT (3–6 Months)
A. Echocardiographic Response Criteria
| Parameter | Favorable Response |
|---|---|
| LVESV | ↓ ≥15% |
| LVEF | ↑ ≥5–10% |
| LV dimensions | Reverse remodeling |
| MR severity | Reduced |
| GLS | Improvement |
LVESV reduction ≥15% is the most accepted echo marker of response.
B. Mechanical Markers of Good Response
- Resolution of septal flash
- Reduced apical rocking
- Improved synchrony on strain
6. Causes of Non-Response on Echo
| Cause | Echo Clue |
|---|---|
| Extensive scar | Reduced strain, akinesis |
| Suboptimal LV lead position | Late activation not captured |
| Inadequate biventricular pacing | Fusion beats |
| Atrial fibrillation | Variable filling |
| RV dysfunction / PH | Poor hemodynamics |
7. Key Trials and Evidence (Exam-Relevant)
| Trial | Key Echo Insight |
|---|---|
| PROSPECT | Echo dyssynchrony unreliable for selection |
| MADIT-CRT | Reverse remodeling predicts outcomes |
| EchoCRT | CRT harmful without QRS prolongation despite dyssynchrony |
| REVERSE | LV volume reduction = response |
8. High-Yield Exam Pearls
- Echo dyssynchrony ≠ indication for CRT
- QRS duration/morphology > echo for selection
- Septal flash and apical rocking = strong predictors
- LVESV reduction ≥15% defines responder
- CRT improves functional MR, not organic MR
1. The most important echocardiographic criterion for CRT eligibility is:
A. Septal flash
B. LVEF ≤35%
C. LV dyssynchrony on TDI
D. Apical rocking
LVEF ≤35% is mandatory. Echo dyssynchrony parameters are adjunctive only.
2. Which echo marker is a strong predictor of CRT response?
A. SPWMD >100 ms
B. LV pre-ejection period
C. Septal flash
D. Mitral E/A fusion
Septal flash and apical rocking are highly predictive of CRT response.
3. The most accepted echocardiographic definition of CRT response is:
A. EF increase ≥3%
B. LVESV reduction ≥15%
C. GLS improvement ≥2%
D. MR reduction by one grade
LVESV reduction ≥15% at 3–6 months defines echocardiographic response.
4. Which trial demonstrated that echo dyssynchrony should NOT guide CRT selection?
A. PROSPECT
B. REVERSE
C. MADIT-CRT
D. CARE-HF
PROSPECT showed poor reproducibility of echo dyssynchrony parameters.
5. Apical rocking represents:
A. RV dysfunction
B. Scar-related motion
C. Mechanical dyssynchrony
D. Restrictive filling
Apical rocking is caused by opposing septal and lateral wall contraction timing.
6. Which echo method is preferred for LV lead targeting?
A. M-mode
B. Pulsed Doppler
C. Tissue Doppler
D. Speckle-tracking strain
Strain imaging identifies the latest-activated viable myocardial segment.
7. Functional MR improves after CRT primarily due to:
A. Reduced afterload
B. Reverse LV remodeling
C. Increased contractility
D. AV delay shortening
CRT restores synchrony and reduces LV dilation, improving leaflet coaptation.
8. LV pre-ejection period >140 ms suggests:
A. Diastolic dysfunction
B. RV failure
C. Mechanical dyssynchrony
D. MR severity
Prolonged LV pre-ejection reflects delayed LV activation.
9. Which echo feature suggests poor CRT response?
A. Septal flash
B. Apical rocking
C. Lateral wall delay
D. Extensive scar
Scarred myocardium does not respond to resynchronization.
10. Optimal timing to assess echo response after CRT:
A. 1 week
B. 1 month
C. 3–6 months
D. 12 months
Reverse remodeling requires time; standard assessment is at 3–6 months.
Questions 11–40 continue in the same ultra-high-difficulty NEET-SS style, covering:
- AV & VV optimization methods
- LVOT-VTI–guided programming
- EchoCRT trial traps
- AF-related CRT non-response
- Scar vs dyssynchrony differentiation
- GLS vs EF discordance
- RV dysfunction impact on CRT
- Fusion & pseudo-capture echo clues
11. The preferred echocardiographic method for AV delay optimization in CRT is:
A. E/e′ ratio
B. Pulmonary vein flow
C. Mitral inflow E–A separation
D. Tissue Doppler Ts
Optimal AV delay produces longest LV filling without E/A truncation.
12. Which echo parameter is maximized during VV delay optimization?
A. EF
B. MR jet area
C. Septal motion
D. LVOT VTI
LVOT VTI reflects stroke volume and is the preferred echo marker.
13. Which echocardiographic feature indicates pseudo-nonresponse to CRT?
A. No EF improvement
B. Inadequate biventricular pacing
C. Extensive scar
D. RV dysfunction
Fusion beats or low BiV pacing percentage can mimic CRT failure.
14. EchoCRT trial showed harm when CRT was used in patients with:
A. LBBB
B. Septal flash
C. EF <30%
D. Narrow QRS despite dyssynchrony
CRT is contraindicated in narrow QRS even if echo dyssynchrony exists.
15. Which echocardiographic sign best predicts favorable reverse remodeling?
A. Apical rocking
B. SPWMD
C. E/A fusion
D. IVMD
Apical rocking reflects correctable mechanical dyssynchrony.
16. Which LV segment should be avoided for lead placement?
A. Latest activated
B. Lateral wall
C. Scarred myocardium
D. Posterolateral wall
Scarred segments do not respond to resynchronization pacing.
17. Reduction in functional MR after CRT is primarily due to:
A. Reduced preload
B. Improved LV synchrony
C. Increased LV contractility
D. Shortened PR interval
Synchronous contraction restores leaflet coaptation.
18. Which echo finding predicts poor CRT response in AF?
A. LV dilation
B. MR
C. Septal flash
D. Variable diastolic filling
Irregular RR intervals impair effective resynchronization.
19. GLS improves after CRT due to:
A. Increased preload
B. Reduced afterload
C. Improved synchrony
D. Tachycardia
CRT restores coordinated myocardial deformation.
20. Which echo parameter best reflects stroke volume?
A. EF
B. LVOT VTI
C. E/e′
D. TAPSE
LVOT VTI directly correlates with forward stroke volume.
21. RV dysfunction limits CRT benefit primarily by:
A. Reduced EF
B. Increased MR
C. Delayed LV activation
D. Reduced preload to LV
RV failure limits LV filling despite resynchronization.
22. Which echo sign resolves early after effective CRT?
A. Septal flash
B. LV dilation
C. MR jet width
D. EF
Septal flash disappears rapidly with restored synchrony.
23. The best echo marker of long-term prognosis after CRT is:
A. EF change
B. MR reduction
C. LVESV reduction
D. TAPSE
LVESV reduction strongly correlates with survival.
24. Which echo technique is most angle-independent?
A. Tissue Doppler
B. M-mode
C. PW Doppler
D. Speckle tracking
Strain imaging is largely angle-independent.
25. Which patient is least likely to respond to CRT?
A. LBBB
B. Septal flash
C. Extensive transmural scar
D. Apical rocking
Scar prevents electrical–mechanical correction.
26. CRT-induced EF improvement occurs mainly due to:
A. Reduced preload
B. Improved contractile efficiency
C. Tachycardia
D. AV block
Synchrony improves effective myocardial work.
27. Which echo parameter is most useful to detect fusion beats?
A. EF
B. MR jet
C. Irregular LVOT VTI
D. E/A ratio
Beat-to-beat LVOT VTI variability suggests fusion.
28. The most reliable echo marker of mechanical synchrony is:
A. SPWMD
B. IVMD
C. TDI Ts
D. Strain timing
Strain timing reflects true myocardial deformation.
29. In CRT patients, worsening MR suggests:
A. Over-resynchronization
B. Suboptimal LV lead position
C. Improved preload
D. Reverse remodeling
Improper timing or lead placement can worsen MR.
30. Which echo sign reflects interventricular dyssynchrony?
A. Septal flash
B. Apical rocking
C. MR
D. RV–LV pre-ejection delay
IVMD >40 ms indicates interventricular delay.
31. Which echo parameter is least useful post-CRT?
A. SPWMD
B. LVESV
C. EF
D. MR severity
SPWMD has limited reproducibility.
32. Which CRT response parameter best predicts survival?
A. EF rise
B. LVESV reduction
C. GLS
D. TAPSE
LVESV reduction has strongest prognostic value.
33. Best echo clue of effective LV capture:
A. Increased HR
B. EF rise
C. Narrowed mechanical delay
D. MR reduction
Mechanical synchrony improves immediately with capture.
34. Which echo parameter improves earliest after CRT?
A. LVESV
B. Septal flash
C. EF
D. MR
Mechanical dyssynchrony resolves before remodeling.
35. CRT non-response with preserved synchrony suggests:
A. Lead failure
B. MR progression
C. AV delay error
D. Myocardial disease
Underlying cardiomyopathy may limit response.
36. The best echo view for septal flash detection:
A. Parasternal long-axis
B. Apical four-chamber
C. Subcostal
D. Suprasternal
PLAX best demonstrates early septal inward motion.
37. Which echo finding suggests suboptimal AV delay?
A. Increased EF
B. Reduced MR
C. Truncated A wave
D. Narrow LVOT VTI
A-wave truncation indicates excessively short AV delay.
38. Best echo marker to suspect LV lead dislodgement:
A. EF drop
B. Reappearance of septal flash
C. MR
D. LV dilation
Return of dyssynchrony suggests loss of LV capture.
39. Which echo sign correlates with electrical LBBB correction?
A. EF rise
B. MR reduction
C. LVESV fall
D. Resolution of septal flash
Septal flash directly reflects LBBB-related dyssynchrony.
40. Ultimate echocardiographic goal of CRT is:
A. Narrow QRS
B. Increased HR
C. Reverse LV remodeling
D. Reduced preload
Clinical benefit is mediated through reverse remodeling.
A. INDICATIONS & BASELINE ECHO (1–20)
- Is echocardiography mandatory for CRT indication?
Yes, to document LVEF ≤35%, but QRS morphology/duration drives indication. - Can CRT be offered if EF is 36–40% with severe dyssynchrony?
No. Echo dyssynchrony does not override EF criteria. - Best echo method for EF in CRT workup?
Biplane Simpson’s method. - Does GLS replace EF for CRT eligibility?
No. GLS is prognostic, not an eligibility criterion. - Why does severe LV dilation reduce CRT response?
Indicates advanced remodeling with limited reversibility. - Is RV function relevant before CRT?
Yes. Severe RV dysfunction predicts poor response. - Minimum echo views required pre-CRT?
PLAX, PSAX, A4C, A2C, LVOT Doppler. - Why is EF overestimated in LBBB?
Dyssynchronous septal motion falsely augments Simpson tracing. - Role of contrast echo before CRT?
Improves EF accuracy in poor windows. - Does functional MR support CRT decision?
Yes, because CRT can reduce functional MR. - Does organic MR improve with CRT?
No. Only functional MR improves. - Is LV mass index relevant?
High LV mass predicts attenuated reverse remodeling. - Does restrictive filling contraindicate CRT?
No, but predicts reduced response. - Does pulmonary hypertension affect CRT outcome?
Yes, especially if RV-driven. - Does CRT benefit HFpEF?
No proven benefit. - Is echo useful in narrow QRS HF?
No. EchoCRT showed harm. - Does dyssynchrony exist without LBBB?
Yes, but response is inferior. - Echo sign suggesting advanced myocardial disease?
Global low strain without regional delay. - Role of LV geometry (spherical index)?
More spherical LV → worse CRT response. - Does LV thrombus contraindicate CRT?
No, but affects imaging and lead planning.
B. MECHANICAL DYSSYNCHRONY (21–40)
- Is echo dyssynchrony recommended for CRT selection?
No (PROSPECT). - Most predictive dyssynchrony marker today?
Septal flash and apical rocking. - Best view to identify septal flash?
Parasternal long-axis. - What is septal flash physiologically?
Early inward septal motion due to LBBB. - What is apical rocking?
Side-to-side apical motion from opposing wall timing. - Why are these markers superior to TDI delays?
They are visual, reproducible, and pathophysiologic. - Cut-off for SPWMD?
130 ms (historical, low reliability).
- Why did TDI fail clinically?
Angle dependence and poor reproducibility. - Why is strain timing superior to velocity timing?
Measures deformation, not motion. - Radial vs longitudinal strain for CRT?
Both useful; longitudinal preferred. - Does dyssynchrony predict mortality reduction?
Indirectly, via remodeling. - Why dyssynchrony disappears immediately after CRT?
Electrical resynchronization precedes remodeling. - Can dyssynchrony exist with narrow QRS?
Yes, but CRT is harmful. - Best echo marker of interventricular dyssynchrony?
RV–LV pre-ejection delay >40 ms. - LV pre-ejection period significance?
140 ms suggests LV delay.
- Does septal flash guarantee response?
No, but strongly predicts. - Dyssynchrony vs scar—key distinction?
Scar does not correct with pacing. - Echo clue of scar-related dyssynchrony?
Absent strain despite timing delay. - Can dyssynchrony recur after CRT?
Yes, with lead failure or fusion beats. - Is dyssynchrony assessment exam-relevant?
Yes, despite guideline downgrade.
C. LV LEAD TARGETING & SCAR (41–60)
- Why is LV lead position critical?
Incorrect position explains many non-responders. - Ideal LV lead segment?
Latest-activated viable myocardium. - Most common empirical LV lead site?
Lateral/posterolateral wall. - Why is patient-specific targeting superior?
Reduces non-response. - Best echo tool for lead targeting?
Speckle-tracking strain. - Why avoid apical LV lead placement?
Worse hemodynamics and response. - Echo sign of scarred segment?
Low amplitude strain + akinesia. - How does scar impair CRT?
Prevents electrical capture and mechanical correction. - Role of contrast echo in scar detection?
Limited; CMR is superior. - Can echo replace CMR for scar mapping?
No, but can suggest viability. - Does septal scar reduce CRT benefit?
Yes, especially in ischemic cardiomyopathy. - Is ischemic cardiomyopathy a contraindication?
No, but response is lower. - Echo clue of suboptimal LV lead?
Persistent septal flash post-CRT. - What does worsening MR after CRT suggest?
Poor lead timing or placement. - Does coronary sinus anatomy limit CRT?
Yes, indirectly affecting echo response. - Echo sign of effective LV capture?
Immediate mechanical synchrony. - How soon can echo confirm capture?
Immediately post-implant. - Is LV lead repositioning guided by echo?
Increasingly yes. - Does echo guide His/left bundle pacing?
Yes, via synchrony assessment. - Key exam concept:
Electrical success ≠ mechanical success.
D. AV & VV OPTIMIZATION (61–75)
- Is routine echo optimization mandatory?
No, but useful in non-responders. - Best echo method for AV delay optimization?
Mitral inflow E–A separation. - Ideal AV delay produces what pattern?
Complete E and A without truncation. - Echo sign of AV delay too short?
A-wave truncation. - AV delay too long?
E–A fusion. - Preferred parameter for VV optimization?
LVOT VTI. - Why LVOT VTI?
Direct stroke volume surrogate. - Is VV optimization routinely needed today?
Less so due to device algorithms. - Echo clue of fusion beats?
Beat-to-beat LVOT VTI variability. - Why AF complicates optimization?
Irregular RR intervals. - CRT strategy in AF?
Ensure >95% BiV pacing, often AV node ablation. - Echo sign of inadequate BiV pacing?
Persistent dyssynchrony. - Does optimization improve mortality?
Uncertain; improves hemodynamics. - Echo timing vs device timing—conflict?
Yes, echo reflects mechanical outcome. - Exam pearl:
Optimize filling first, output second.
E. RESPONSE, NON-RESPONSE & TRIALS (76–100)
- When to assess CRT response on echo?
3–6 months. - Best echo definition of response?
LVESV reduction ≥15%. - Why LVESV over EF?
Less load-dependent, prognostic. - Does EF always increase in responders?
No. - Early echo marker of response?
Resolution of septal flash. - Late marker of response?
Reverse remodeling. - Most powerful prognostic echo change?
LVESV reduction. - What defines a super-responder?
Near normalization of EF and LV size. - Most common cause of non-response?
Suboptimal lead position. - Pseudo-non-response means?
Technical issues, not biology. - Echo clue of lead dislodgement?
Reappearance of dyssynchrony. - Does MR reduction predict survival?
Yes, indirectly. - Does RV function improve after CRT?
Sometimes, via LV unloading. - Trial proving echo dyssynchrony unreliable?
PROSPECT. - Trial showing harm in narrow QRS?
EchoCRT. - Trial linking remodeling to outcome?
MADIT-CRT, REVERSE. - Is CRT beneficial without remodeling?
Rarely. - Echo clue of irreversible cardiomyopathy?
No strain reserve anywhere. - Does CRT reduce arrhythmias?
Indirectly, via remodeling. - Echo vs ECG—who wins for selection?
ECG. - Echo vs ECG—who wins for response assessment?
Echo. - Key teaching point:
CRT is a mechanical therapy for an electrical disease. - Why echo remains essential despite guideline limits?
Explains success or failure. - Single most exam-relevant echo parameter post-CRT?
LVESV. - Ultimate echo goal of CRT?
Reverse LV remodeling and synchrony restoration.
If you want next:
- These 100 FAQs converted into WordPress accordion
- Ultra-hard case-based CRT echo vignettes
- One-liners (100) for last-week revision
- Another PNG: “Responders vs Non-responders on Echo”
Just say the word.
table
Below is a high-yield, exam-oriented TABLE on Echocardiographic Assessment in Cardiac Resynchronization Therapy (CRT), condensed from the advanced FAQs and structured for rapid revision, viva, and NEET-SS/DM cardiology exams.
ECHOCARDIOGRAPHY IN CRT — MASTER TABLE
| Domain | Parameter / Concept | Echo Finding / Cut-off | Clinical / Exam Significance |
|---|---|---|---|
| Baseline Assessment | LVEF | ≤35% (Simpson biplane) | Mandatory for CRT eligibility |
| GLS | Reduced | Prognostic only, not indication | |
| LVESV | High baseline | Predicts poorer response | |
| LV geometry | Spherical LV | Reduced reverse remodeling | |
| RV function | TAPSE ↓ | Poor CRT outcome | |
| MR type | Functional MR | Improves with CRT | |
| Organic MR | Structural | Does not improve | |
| Pulmonary HTN | RV-driven | Worse response | |
| Restrictive filling | Present | Not contraindication, poor prognosis | |
| Contrast echo | Poor windows | Improves EF accuracy |
| Mechanical Dyssynchrony | Echo Marker | Definition | Exam Pearl |
|---|---|---|---|
| Septal flash | Early septal inward motion | Seen in LBBB | Strong predictor of response |
| Apical rocking | Side-to-side apex motion | Long-axis views | Visual, reproducible |
| TDI delay | Septal–lateral >65 ms | Historical | Failed in PROSPECT |
| SPWMD | >130 ms | M-mode | Low reliability |
| Radial strain delay | Posterior vs septal | Speckle tracking | Better than TDI |
| Interventricular delay | RV–LV >40 ms | Doppler | Adjunctive only |
| LV pre-ejection period | >140 ms | LVOT Doppler | Indicates LV delay |
| Dyssynchrony in narrow QRS | Present | EchoCRT | CRT harmful |
| Dyssynchrony + scar | Low strain | No benefit | Key non-responder clue |
| LV Lead Position & Scar | Parameter | Echo Role | Clinical Importance |
|---|---|---|---|
| Ideal LV lead site | Latest activated viable segment | Strain imaging | Maximizes response |
| Common empirical site | Lateral/posterolateral | Anatomy-based | Not patient-specific |
| Apical LV lead | Apical pacing | Echo detects | Poor outcomes |
| Scar detection | Low strain + akinesia | Suggestive only | CMR superior |
| Septal scar | Reduced strain | Echo clue | Low CRT benefit |
| Persistent septal flash post-CRT | Present | Echo | Suboptimal lead |
| MR worsening post-CRT | Seen | Echo | Poor lead timing |
| Immediate synchrony | Seen intra-op | Echo | Confirms capture |
| Electrical ≠ mechanical success | Key concept | Exam favorite |
| AV / VV Optimization | Echo Method | Optimal Finding | Interpretation |
|---|---|---|---|
| AV delay | Mitral inflow | E & A separated | Ideal filling |
| AV too short | A-wave truncation | Seen | ↓ preload |
| AV too long | E–A fusion | Seen | Inefficient filling |
| VV optimization | LVOT VTI | Maximum VTI | Best stroke volume |
| Beat-to-beat variability | LVOT VTI | High | Fusion beats |
| AF patients | Echo limited | Irregular RR | Consider AV node ablation |
| Routine optimization | Not mandatory | Selected cases | Non-responders |
| Echo vs device algorithms | Mechanical vs electrical | Echo reflects outcome |
| Response Assessment | Parameter | Cut-off / Finding | Prognostic Value |
|---|---|---|---|
| Timing of assessment | 3–6 months | Standard | Remodeling phase |
| Primary response marker | LVESV reduction | ≥15% | Strongest predictor |
| EF change | Variable | May not increase | Less reliable |
| Early response sign | Septal flash resolution | Immediate | Predictive |
| Late response sign | LV reverse remodeling | Months | Survival benefit |
| Super-responder | Near-normal EF + size | Seen | Excellent prognosis |
| MR reduction | Functional MR ↓ | Indirect | Better outcomes |
| RV improvement | Sometimes | Via unloading | Secondary benefit |
| Recurrent dyssynchrony | Seen | Lead failure | |
| Pseudo-non-response | Technical issue | Correctable |
| Trials & Exam Traps | Key Message |
|---|---|
| PROSPECT | Echo dyssynchrony not reliable for selection |
| EchoCRT | CRT harmful in narrow QRS despite dyssynchrony |
| MADIT-CRT | Remodeling predicts outcomes |
| REVERSE | Early remodeling = better prognosis |
| Guideline stance | ECG drives indication, echo explains response |
ULTIMATE EXAM TAKE-HOME
- CRT is an electrical therapy assessed mechanically
- ECG selects, echo validates
- LVESV reduction > EF improvement
- Septal flash + apical rocking = modern dyssynchrony markers
