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Other complications: hypotension, radiation skin injury, contrast-induced acute kidney injury


In this chapter we discuss three non-coronary complications: hypotension, radiation skin injury, and contrast-induced acute kidney injury (CI-AKI).

28.1

Hypotension

CTO Manual Online cases 69 , 85 , 92 , 129 , 146

PCI Manual Online cases 23 , 27 , 40 , 45 , 72

Continuous careful monitoring of the pressure and electrocardiographic tracing is critical for enhancing the safety of PCI ( Section 2.2 ). Awareness of the differential diagnostic algorithm if hypotension occurs during angiography or PCI can facilitate rapid decision making and initiation of corrective actions.

28.1.1

Causes

The appearance of low blood pressure on hemodynamic monitoring does not necessarily mean that the patient’s systemic blood pressure is low, as “hypotension” could be due to technical issues ( Fig. 28.1 ). Therefore, when hypotension occurs, it should be immediately assessed to determine whether the patient is truly hypotensive or not. If the patient’s systemic blood pressure is indeed low, the differential diagnosis should be immediately considered to allow prompt diagnosis and treatment.

Figure 28.1, Differential diagnosis of hypotension. * left ventricular filling pressure can be low in cases of right ventricular failure.

28.1.1.1

False hypotension

(Systemic pressure is normal, but appears low on the arterial pressure tracing)

  • 1.

    Hemostatic valve of the Y-connector is open.

  • 2.

    Connection between catheter and pressure transducer is open or has air in the line.

  • 3.

    Pressure dampening. This is common, especially in patients with ostial coronary lesions and with use of large guide catheters, such as 8 French. Dampening can be masked when side hole guide catheters are used, hence the latter should never be used to engage the left main coronary artery (with the exception of ostial left main CTOs), as they can mask ischemia and lead to patient hemodynamic collapse.

  • 4.

    Catheter obstruction by air, thrombus, or contrast (contrast can cause pressure dampening, especially in 4 and 5 French catheters). The catheter should be aspirated. If aspiration fails, the catheter should be removed without performing any injection.

  • 5.

    Bulky equipment within the catheter.

28.1.1.2

True hypotension

There are three major causes of true hypotension: hypovolemia, cardiac failure, and peripheral vasodilation ( Fig. 28.1 ). If the cause of hypotension is not immediately apparent, right heart catheterization can be very useful for determining the cause of hypotension.

28.1.1.2.1

Hypovolemia

Hypovolemia is most commonly caused by bleeding. Inspection of the access sites may reveal a hematoma. Fluoroscopy of the bladder may demonstrate the “dented bladder” sign ( Fig. 29.3 ) that suggests retroperitoneal hematoma.

28.1.1.2.2

Cardiac failure

Cardiac output is the product of (stroke volume)×(heart rate). Decreased stroke volume may be due to: (1) left or right ventricular dysfunction, which is most commonly caused by ischemia; (2) valvular abnormalities, such as acute valvular regurgitation; and (3) pericardial tamponade.

Amplatz catheters (and deeply curved EBU catheters) may push the aortic cusp open and cause acute aortic regurgitation ( Fig. 28.2 ); simple guide catheter repositioning can immediately correct the hypotension.

Figure 28.2, Blood pressure is lower in the in the left half of the screen due to deep advancement of an Amplatz catheter on the aortic valve. Blood pressure increased after withdrawal of the Amplatz catheter ( right half of the screen ). The green pressure tracing has dampening.

Both tachyarrhythmias and bradyarrhythmias can also reduce cardiac output.

28.1.1.2.3

Peripheral vasodilation

Peripheral vasodilation may be due to a vasovagal reaction, a systemic anaphylactic reaction, or medication administration, such as nitroglycerin (especially if the patient had been recently exposed to phosphodiesterase 5 inhibitors) or verapamil (intracoronary or intraarterial for preventing radial spasm).

28.1.2

Prevention

Preventing false hypotension can be accomplished using meticulous techniques:

  • 1.

    Careful assessment and verification of all connections.

  • 2.

    Meticulous care in clearing the catheter after insertion.

  • 3.

    Avoiding deep catheter engagement causing dampening.

Preventing true hypotension can be achieved via careful planning of the procedure and attention to each step, as follows:

  • 1.

    Careful arterial access technique and use of radial access, as well as avoiding excessive anticoagulation can decrease the risk of bleeding.

  • 2.

    Adequate pre-procedural hydration.

  • 3.

    Considering prophylactic hemodynamic support in high-risk patients undergoing PCI, as described in Chapter 14 : Hemodynamic Support.

  • 4.

    Preventing prolonged coronary artery occlusion will minimize ischemia.

  • 5.

    Avoiding perforations and the resultant tamponade.

  • 6.

    Adequate premedication for patients with contrast allergy will decrease the risk of anaphylactic shock ( Section 3.3 ).

  • 7.

    Early diagnosis and correction of tachyarrhythmias and bradyarrhythmias.

  • 8.

    Adequate sedation and hydration may minimize the risk of a vasovagal reaction.

  • 9.

    Avoiding excessive doses of nitroglycerin and other vasodilators.

28.1.3

Treatment

Immediate and complete treatment of the underlying cause is best for correcting hypotension, but may not always be feasible, for example, in patients who develop acute vessel closure that cannot be recanalized. Therefore, concomitant implementation of measures that can increase the systemic blood pressure and maintain systemic perfusion is often needed.

28.1.3.1

Maintain systemic perfusion

While treating the underlying cause of hypotension, administration of vasopressors and inotropes and in some patients initiation of mechanical circulatory support ( Chapter 14 : Hemodynamic Support) may be necessary. If the patient develops cardiac arrest, cardiopulmonary resuscitation is performed (ideally using an automated system, such as the Lucas system), followed by veno-arterial extracorporeal membrane oxygenation (VA-ECMO) initiation if the patient does not promptly recover.

28.1.3.2

Treat underlying cause

Hypovolemia : Normal saline administration and blood transfusion in case of bleeding. If bleeding is due to an arterial access complication, a balloon should be inflated to stop active bleeding, followed by endovascular or surgical repair, as described in Chapter 29 - Vascular Access Complications.

Myocardial dysfunction : This is usually caused by ischemia and can be improved with coronary revascularization and in some cases with mechanical circulatory support.

Valvular disease : Although acute mitral or aortic regurgitation may benefit from vasodilator administration, they are often poorly tolerated requiring urgent or emergent surgery. Acute mechanical circulatory support may also improve hemodynamics, such as an intraaortic balloon pump for acute mitral regurgitation.

Pericardial disease : Tamponade is treated with pericardiocentesis. If the patient has myocardial rupture (usually in the setting of acute myocardial infarction) emergency surgery is needed.

Arrhythmias : Arrhythmias occurring in the cardiac catheterization laboratory are usually due to ischemia, hence treatment of ischemia will improve or correct them. Arrhythmias often occur after reperfusion (post-reperfusion arrhythmias). Bradycardia and atrioventricular block is often caused by medication administration, such as adenosine ( Section 3.2.4 ), however the duration of action of adenosine is very short.

Peripheral vasodilation : Epinephrine for anaphylactic shock and fluid administration.

28.2

Radiation skin injury

Excessive radiation dose can result in deterministic complications (e.g., radiation skin injury), but can also lead to stochastic complications (e.g., cancer or birth defects) . Significant technological developments can help reduce radiation dose .

28.2.1

Causes

Deterministic radiation effects, such as skin injury and cataracts, correlate directly with the air kerma dose to a particular skin area ( Fig. 28.3 ) .

Figure 28.3, Example of radiation-induced skin injury after CTO PCI. Erythema and epilation developed on a patient’s back 1 month after CTO PCI, during which he received 11.8 Gray air kerma dose.

The following AK dose thresholds are important to remember :

<5 Gray : Below this threshold skin injury is unlikely to occur.

5–10 Gray : Skin injury is possible.

10–15 Gray : Skin injury is likely, requiring physicist assessment of the case.

>15 Gray : This is considered a sentinel event by the Joint Commission for Hospital Accreditation and requires reporting to the regulatory authorities in the U.S.

28.2.2

Prevention

Preventing radiation skin injury can be achieved by limiting the overall radiation dose and by rotating the image intensifier to distribute the radiation dose to various skin areas ( Fig. 28.4 ).

Figure 28.4, How to prevent radiation injury during cardiac catheterization.

Reducing patient (and operator) radiation dose can be achieved both before and after the procedure:

Before the procedure

28.2.2.1

Planning

Careful planning of the procedure can prevent unnecessary steps, facilitate procedural success and minimize contrast and radiation dose. Careful procedural planning applies not only to complex procedures, such as chronic total occlusion interventions , but every procedure. For example, carefully studying the location of aorto-coronary bypass grafts on previous angiograms can expedite bypass graft engagement. Catheterization in very obese patients should be performed with newer X-ray systems.

28.2.2.2

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