Cardiac Catheterization & Electrical Therapies

Objectives 2.1 / 3.1 — Understand cardiac catheterization indications and procedure, diagnostic and therapeutic interventions, radionuclide studies, synchronized cardioversion, and pacemaker/ICD function and interrogation.

Unit 2: Cardiac Catheterization

Overview

Cardiac catheterization is a procedure to examine the heart by passing a catheter through an artery — usually the femoral artery — to examine structures of the heart.

Considered primarily a diagnostic study, though therapeutic interventions may be performed during the same procedure
The most common indication is identification of CAD and assessment of its extent and severity

Catheters

Different catheters are selected based on the type of disease process expected, guided by prior assessments (echocardiography, CMRI)
Each catheter is introduced via a guidewire
The guidewire remains in place to allow rapid exchange of catheters by technicians as needed

Equipment

Equipment	Purpose
Fluoroscopy (C-Arm)	Real-time radiographic imaging system
Physiologic monitoring	ECG, invasive and noninvasive blood pressure
Sterile table supplies	Catheters, sheath insertion device, sterile drapes and towels, heparinized saline
Imaging for vascular access	Ultrasound guidance
Emergency cart & defibrillator	Emergency preparedness

Procedure — Judkins Technique

The patient is placed on a flat table with a fluoroscope capable of a 360° view of the heart, projected on a screen visible to all clinicians.

Judkins Technique — Percutaneous entry into the femoral artery:

Palpate for the inguinal ligament
Measure 1–3 cm (one or two fingers) below the inguinal ligament
Make a small nick in the skin above the vessel
Puncture the femoral artery and introduce the catheter via guidewire

Femoral arterial access is the most common route for cardiac catheterization.

Diagnostic Studies

Coronary Angiography

Coronary angiography is the gold standard for evaluating the anatomy of the coronary artery tree and diagnosing CAD.

Normally a same-day procedure
Most widely used invasive procedure in cardiovascular medicine
Can be performed via the femoral or radial arteries

Access Route	Notes
Femoral	Slightly longer recovery period
Radial	Shorter total recovery time; limits catheter size

How It Works

Direct injection of radiopaque contrast agent into the coronary arteries
Contrast enhances x-ray absorption, producing sharp visualization of arterial anatomy
Catheter is inserted and guided up the aorta to the coronary artery ostium
Contrast is injected and images are captured on high-resolution digital radiographic systems

Indications

Category	Indication
Primary	Stable ischemic CAD
Primary	Unstable angina / NSTEMI
Primary	Post-revascularization ischemia
Primary	Post-STEMI
Other	Initial diagnostic test for stable ischemic heart disease
Other	Survived sudden cardiac death or lethal arrhythmia
Other	CHF with worsening symptoms (LV dysfunction > 50%)
Other	Exercise testing showing ST-segment changes, angina, or wall dysfunction on non-invasive echo

Contraindications

There are no absolute contraindications to coronary angiography.

Relative risk factors requiring risk/benefit analysis:

Active bleeding
Abnormal coagulopathy (elevated INR)
Fever
(And others)

Catheter Types

Catheter	Use
Judkins Right (JR)	Shaped to access the right coronary artery
Judkins Left (JL)	Shaped to access the left coronary artery
Pigtail	Allows larger volumes of contrast; placed in the left ventricle to evaluate wall motion and cardiac output

Judkins catheters between 5F and 6F are standard for diagnostic arteriography.

Patient Preparation

Conscious sedation:
- Fentanyl
- Midazolam (Versed)
Heparin anticoagulation
Nitroglycerin — used to dilate vessels in patients with an active or recent coronary event

Contrast Agents

Injected into coronary arteries to enhance x-ray absorption and produce sharp contrast with surrounding tissue
Typically contain iodine — which may cause an allergic reaction in some patients

Assessing the Lesion

The composition, distribution, and location of atherosclerotic plaque are unique to each patient. Because every patient has a unique coronary tree, the lesion's location may complicate stenting or atherectomy.

Cardiac Electrophysiology (EPS)

Invasive electrophysiology studies (EPS) use a multi-lead catheter with electrodes to record or stimulate cardiac electrical activity.

Performed by an electrophysiologist (a subspecialty cardiologist)
Has both diagnostic and therapeutic functions
Effective at initiating VT and SVT when these tachyarrhythmias have occurred spontaneously

Diagnostic EPS

By stimulating specific portions of the electrical pathway, the technician can:

Measure specific electrical dysfunctions (e.g., third-degree AV block)
Initiate arrhythmias (SVT, tachycardia) for characterization
Help determine if a patient requires a pacemaker or cardioversion device

Cardiac Mapping

Cardiac mapping records electrical potentials from the heart and depicts them spatially as activation times and electrical amplitudes of myocardial tissue.

A computer algorithm detects the electrical potential of the myocardium and how quickly muscle tissue is stimulated
Displayed as a color chart
Effective at identifying:
- Foci causing SVT
- Wolff-Parkinson-White (WPW) syndrome
- Scar tissue

Therapeutic Interventions

Percutaneous Coronary Intervention (PCI)

PCI provides relief of ischemic CAD symptoms and reduces the risk of mortality and subsequent myocardial infarctions.

Mortality rate: < 1%
Complications include:
- Risk of restenosis of a stent
- Risk of thrombosis
- Risk of perforation of the coronary artery

Balloon Angioplasty

Balloon angioplasty expands the coronary lumen by stretching and tearing the atherosclerotic plaque and vessel wall.

Does not remove atherosclerosis — it displaces it to the sides of the vessel wall
Restenosis is common
Rare but possible: arterial rebound and vessel swelling causing occlusion worse than initial stenosis

Stents

Stents are used in 90% of PCI procedures worldwide and are the predominant form of PCI.

Tube-shaped devices placed in the artery to maintain vessel integrity and patency
Deployed by being fed into the coronary artery on a balloon catheter and expanded within the stenosis
Restenosis occurs in only ~1% of cases
Some stents are drug-impregnated to help prevent thrombosis and plaque development

Coronary Atherectomy

Atherectomy refers to the removal (rather than displacement) of obstructing atherosclerotic plaque by grinding it.

Allows for a larger final minimal lumen diameter than balloon angioplasty alone
The rotablator rotational atherectomy system is the most commonly used device
Restenosis remains a concern
Complication: distal blockages as plaque is broken away from the artery

Ablation

Ablation destroys myocardial tissue by delivering energy through a catheter electrode placed on the myocardium at a targeted location.

Energy types:
- Radiofrequency (RF) — generates heat through the catheter tip, destroying targeted tissue
- Cryo — destroys tissue through freezing
Used to eliminate:
- Foci causing SVT/arrhythmias
- Bridging tissue between scar tissue that sustains reentrant arrhythmias (circular electrical signals)

Radionuclide Studies

Also known as radionuclide angiography or blood pool imaging.

Provides imaging of the heart to detect ejection fractions and chamber volumes

Key Concepts

Term	Definition
Radionuclide (Isotope)	Radioactive chemical that emits radiation (usually gamma) detectable by imaging devices
Gamma camera	Detects gamma radiation and reconstructs an image on screen
Technetium-99 (99mTc)	The most commonly used isotope in radionuclide cardiac imaging

Isotopes have an excess number of protons or neutrons, giving them excess nuclear energy, making them easy to identify on gamma imaging devices or x-ray.

Radionuclide Ventriculography

Using 99mTc-pertechnetate, the gamma camera — which can rotate around the patient — produces images in:

Anterior-Posterior (AP)
Left Anterior Oblique (LAO)
Lateral views

Data is recorded in a computer synchronized with the R wave of the patient's ECG.

What Radionuclide Studies Can Identify

Size of heart chambers and great vessels
Regional wall motion
Global function (qualitative assessment)
Ventricular wall thickness
Pericardial effusion
Pericardial fat pad
Paracardiac mass

Blood pool imaging — a reduced ejection fraction (EF) results in blood pooling within one of the ventricles, which is visualized on radionuclide imaging.

Unit 3: Electrical Therapies

Synchronized Cardioversion

Synchronized cardioversion delivers a shock timed to the R wave to convert a fast, irregular heart rhythm to a regular rhythm.

A synchronizing function (manual or automatic) times the shock delivery
Marked as a 'Tic' mark on the R wave on the monitor
Shock is delivered at a predetermined optimal moment (milliseconds after R wave detection)

Indications

Indication	Notes
Hemodynamically significant SVT	Narrow-complex tachycardias
Atrial fibrillation
Atrial flutter
Ventricular tachycardia (with pulse)

Pulseless VT and VF are treated with unsynchronized shocks — this is called defibrillation, not cardioversion.

Procedure

Preparation:

Verify indication; explain procedure to the awake patient
Remove clothing from the upper body
Remove nitroglycerin paste/patches; wipe away any residue
Remove (shave) excessive hair from paddle/electrode sites
Do not apply alcohol, tincture of benzoin, or antiperspirant to skin
Print an ECG strip to document the rhythm
Ensure suction and emergency medications are available
Give oxygen and start an IV

Delivering the shock:

Ensure defibrillator is on
Apply defibrillation gel (standard paddles) or adhesive pads
Press the "Sync" control on the defibrillator
Select a lead with an optimum QRS amplitude and no artifact
Confirm sense markers appear on the R wave of each QRS (not on the T wave)
If sense markers are misplaced, adjust ECG size or select another lead
Administer sedation per protocol (if patient is awake and time permits)
Confirm machine is in Sync mode; select appropriate energy level
Charge the defibrillator; recheck rhythm
Place paddles/pads on the patient's chest
Call "Clear!" — ensure all personnel and equipment are clear; confirm oxygen is not flowing over the chest
Press and hold both discharge buttons simultaneously until the shock is delivered
Note: slight delay occurs while the machine detects the next R wave
Release controls after shock delivery; reassess rhythm and patient
If arrhythmia persists, confirm Sync mode is still active before delivering another shock

If the rhythm deteriorates to pulseless VT or VF, turn Sync off and defibrillate.

Pacemaker Interrogation

Pacemakers & ICDs — Overview

Device	Function
Pacemaker	Delivers low-voltage pacing pulses for symptomatic bradycardia or anti-tachycardia pacing (reentrant tachycardias)
ICD (Implantable Cardioverter-Defibrillator)	Delivers high-voltage shock pulses for atrial fibrillation and ventricular fibrillation

Indications

Device	Primary Indication
Pacemaker	Relieve or prevent symptomatic bradycardia; also for documented asymptomatic bradycardia at risk of becoming symptomatic
ICD	Prevention of sudden death from VT/VF; patients who have had sustained VT/VF

Cardiac Electrical Stimulation

Stimulus Type	Use	Energy Required
Standard pacing	Bradycardia	Low voltage
Antitachycardia pacing (ATP)	Reentrant tachycardias; delivered during the relative refractory period	Higher voltage
Defibrillation	VF/VT conversion	Highest energy

A stimulus that successfully stimulates local myocardium is said to have captured it.

Hardware

Leads:

Have common cable structures inserted into a "Header"
Bipolar leads are used more frequently — better sensing → better detection
Both unipolar and bipolar leads are available

Generator (the "Can"):

Clear plastic header where leads attach
Titanium casing houses all electronic components:
- Battery
- RAM/ROM memory
- Microprocessor
- Essentially a tiny computer in the patient's chest

Sensing, Detection & Oversensing

Function	Definition
Sensing	The instant the device detects atrial or ventricular depolarization has occurred
Detection	The software algorithm that deciphers sensing data to classify the rhythm (arrhythmia vs. normal) and determine appropriate treatment
Oversensing	The device detects a signal that is not a true depolarization → may cause inappropriate pacing or shock

Pacemaker Interrogation Checklist

A complete standard interrogation should document:

#	Item	Normal Value
1	Device & manufacturer	—
2	Current battery voltage (note ERI voltage)	—
3	Last full energy charge time (ICDs)	< 15 seconds
4a	Lead impedance	300–1,000 Ω (except high-impedance leads)
4b	Sensing	A > 1 mV; V > 5 mV
4c	Pacing threshold	Atrium: 1V @ 0.4 ms or less; Ventricle: 1–2V @ 0.4 ms or less
5	% time paced and sensed in A and V	—
6	Underlying rhythm	Test by decreasing pacing rate or temporarily suspending pacing
7	Mode switch episodes (pacemakers)	e.g., "none," "3," "frequent," "in progress"
8	Tachy events (ICDs)	—
9	Sensing threshold setting	< 1/2 sensing capability
10	Pacing output	2× pacing threshold (voltage); 3× threshold (pulse duration)

Noninvasive interrogation tools:

Remote management of the pacemaker
Short-range telemetry with an inductive wand

Precautions for Device Implantation

Damage to cardiac vasculature during placement
Cardiac perforation
Device infection (e.g., MRSA)
Lead displacement
Stroke