Interventional Radiology PDF

Summary

This document discusses interventional radiology procedures, focusing on thrombolysis and stent/shunt placement. It covers objectives, equipment, approaches, complications, and follow-up procedures. This document is intended for professionals in the field.

Full Transcript

Thrombolysis
Stent / shunt placement
 Objectives of the lecture

By the end of lecture students should be:
▀Summarize the basic information concerning thrombolysis and stent /
shunt placement
▀ Develop the ability of performance thrombolysis
and stent / shunt placement

▀ Illustrate the purpose, indication, and necessary
patient preparation for thrombolysis and stent / shunt placement
 Thrombolysis

This is the use of drugs to break up a blood clot
by breaking down the fibrin holding the clot
together. Thrombolysis is not usually clinically
indicated >6 weeks after the thrombotic event
 Equipment
There are different techniques for performing thrombolysis, and the
equipment varies according to the strategy being used:
Ultrasound to guide puncture
Mini access kit
Basic angiography set
Infusion catheters: a 4F straight catheter with side holes
is suitable in most cases
A pump suitable for arterial infusion
Co-axial systems or microcatheters may be helpful
Pulse spray techniques require special catheters and pumps
 Approach

As always, the shortest most direct approach is usually
the best, as it affords the greatest scope for adjunctive
intervention. In some cases, the best approach will
involve direct puncture of a bypass graft. If possible,
avoid the brachial approach, as there is a risk of peri-
catheter thrombus embolizing to cause CVA.
Arterial puncture: At the risk of stating the obvious, try to make
a single arterial puncture. Thrombolysis is sure to lead to bleeding
from any extra puncture sites. This is a good time to use ultrasound to
ensure safe arterial puncture. Use a mini access kit to keep the size of
any unwanted holes to a minimum. Infra-inguinal grafts almost
invariably arise from the anterior aspect of the common femoral
artery (CFA). Arterial puncture must be sufficiently proximal to
allow manipulation of a shaped catheter (Cobra or RDC) to direct a
straight guidewire toward the graft origin.
Direct prosthetic graft puncture: Ultrasound guidance is still the
preferred option. When the graft is palpable, fix it between forefinger and
thumb and then perform a single wall puncture in the conventional manner.
There is a very distinctive give and fall in resistance as the needle enters the
graft lumen. Depending on the direction of catheterization, direct graft
puncture will preclude accessing either the origin or the outflow. Retrograde
lysis often occurs but sometimes it is necessary to make a second puncture
from the other end of the graft – the ‘crossed catheter technique’.
 Complications
Unfortunately, complications of thrombolysis are not rare and may be life-
threatening. Complications increase with the age of the patient, the
duration of treatment and the dose of the lytic agent. Stop the infusion and
the heparin if a complication develops.
CVA: perform an urgent CT scan if there are signs suggestive of CVA.
If there is thrombotic CVA, seek expert neurological opinion and discuss
whether to continue with thrombolysis; hemorrhage means game over.
Puncture site haematoma: perform manual compression, check that the
sheath has not been displaced and consider exchanging for a larger sheath.
 Complications
Significant bleeding: consult a haematologist for advice if bleeding persists
after the infusion is stopped. Check the clotting and try to intervene early
before the patient becomes unstable. Resuscitate the patient with blood and
fresh frozen plasma (FFP) as necessary. Surgical intervention may be required.
Acute clinical deterioration with increased pain: reassess, this is often due
to distal embolization of thrombus which occurs in up to 5% of patients.
Macroemboli may lyse spontaneously or can be aspirated. Microemboli are
much more serious and may cause trash foot.
Reperfusion syndrome: this is caused when there has been prolonged and
severe ischaemia. Adult respiratory distress syndrome and renal failure are
common sequelae and there is a high mortality.
 Mechanical thrombectomy

Mechanical thrombectomy uses special catheters to
macerate the thrombus. The residue is either small
enough to pass through the distal circulation or is
aspirated. The catheter has to be appropriately sized
for the vessel and large sheaths may be necessary.
These devices work best with fresh thrombus and
small acute emboli
Catheter-directed intrathrombus thrombolysis (CDT), which
refers to the infusion of a fibrinolytic drug directly into the
venous thrombus via a multi–side-hole catheter that is
embedded in the thrombus using imaging guidance.
Mechanical thrombectomy devices are capable of
macerating thrombus, and some devices (Angio Jet/Angiovac
Cleaner XT & 15/EKOS/Penumbra Indigo System/Trerotola)
Two of these techniques are performed with use of the
AngioJet. With the “powerpulse” technique the
AngioJet is first used to forcefully pulse-spray a bolus dose of
the thrombolytic drug directly into the thrombus
 May-Thurner syndrome
is caused when the left iliac vein is
compressed by the right iliac artery,
which increases the risk of deep vein
thrombosis (DVT) in the left extremity.
DVT is a blood clot that may partially or
completely block blood flow through the
vein
 Collateral circulation

is a network of tiny blood vessels, and, under normal
conditions, not open.... This allows blood to flow around the
blocked artery to another artery nearby or to the same artery
past the blockage, protecting the heart tissue from injury.
Stent / shunt placement
Transjugular Intrahepatic
Portosystemic Shunt (TIPS)
A transjugular intrahepatic portosystemic shunt
(TIPS) is a percutaneously created connection
within the liver between the portal and systemic
circulations.

A TIPS is placed to reduce portal pressure in
patients with complications related to portal
hypertension.
This procedure has emerged as a less invasive
alternative to surgery in patients with end-stage liver
disease.
▲The goal of TIPS placement is to
divert portal blood flow into the
hepatic vein, so as to reduce the
pressure gradient between portal
and systemic circulations.
▲ Shunt patency is maintained by
placing an expandable metal
stent across the intrahepatic
tract.
 INDICATIONS
Acute variceal bleeding that cannot be successfully
controlled with medical treatment, including
sclerotherapy.
Recurrent and refractory variceal bleeding.
Therapy for refractory ascites.
Portal decompression in patients with hepatic venous
outflow obstruction (Budd-Chiari syndrome, a blockage
in one or more veins that carry blood from the liver
back to the heart) or hepatorenal syndrome.
 INDICATIONS cont.…
Initial therapy of acute variceal hemorrhage
Initial therapy to prevent initial or recurrent
variceal hemorrhage
Reduction of intraoperative morbidity during
liver transplantation.
❖ Right-sided heart failure with increased
central venous pressure
❖ Polycystic liver disease
❖ Severe hepatic failure
□ Active intrahepatic or systemic infection (bacteria can
colonize the stent, causing persistent infection)
□ Severe hepatic encephalopathy poorly controlled with
medical therapy

□ Hypervascular hepatic tumors
□ PV thrombosis (Although PV thrombus may make the
procedure more technically demanding, it is not an
absolute contraindication to TIPS placement.)
▪ prophylactic broad-spectrum antibiotics.
▪ Appropriate resuscitation with fluid and blood
products.
▪ Portal vein (PV) patency should be confirmed prior
to attempts at TIPS placement by Doppler
sonography, arterial portography and MRI.
▪ In Patients with cirrhosis severe coagulopathy
should be addressed prior to procedure.
Procedure:

❖ Pt is laying supine on the table.
❖ General I.V sedative is injected.
❖ Contrast media is injected for the venogram.
❖ The catheter passed through the jugular vein to the vena cava.
❖ A TIPS procedure involves creating a pathway through the liver that
connects the portal vein to a hepatic vein.
❖ A stent placed inside this pathway keeps it open and allows blood to flow
normally from the portal vein through the liver to the hepatic vein, reducing
high blood pressure in the portal vein and bleeding from enlarged veins.
(a) A needle is passed under
radiologic guidance from a hepatic
vein into a major portal venous
branch, and a guide wire is advanced
through this needle. (b) A balloon is
passed over the guide wire, creating a
tract in the hepatic parenchyma. (c)
An expandable stent is placed through
this tract. (d) The effective result is a
nonselective portosystemic shunt.
Type & Amount of C.M
#The type is non-ionic contrast media(Omnipaque).
# The amount for adult is 40 ml
Steps in a TIPS procedure
Steps in a TIPS procedure
✓ This technique is preferably done under
general anesthesia
✓ After puncture of the jugular vein (most
often the right jugular vein) under
sonographic guidance, a catheter is
introduced into one hepatic vein and
wedged in the liver parenchyma.
✓ Gentle injection of dye allows the retrograde
visualization of intrahepatic portal vein branches.
✓ CO2 can be used in patients with renal function
impairment to avoid dye nephrotoxicity.

✓ The intrahepatic portal vein then is entered
with a modified Ross needle.
✓ A guide wire is advanced into the main portal
vein.
✓ The tract between the hepatic and the portal vein is dilated with an
angioplasty balloon catheter (8– 10 mm) followed by stent
placement to maintain the communication between both vessels
patent

Basic transjugular intrahepatic portosystemic shunt (TIPS)
procedure. A curved catheter is placed into the right hepatic
vein.
A wedged hepatic venogram Image demonstrates advancement of a
obtained by using the digital
Colapinto needle into the right portal
subtraction technique obtained
with CO2 gas demonstrates the vein.
location of the portal vein. The
catheter is wedged in a branch of
the right hepatic vein.
A TIPS (10 X 68 mm Wallstent dilated
with 10 mm X 4 cm balloon) has been
placed. Note flow through the Wallstent
and filling of the splenorenal shunt
 Shunt surveillance:at regular 3 to 6month intervals for
Assessment of:
MORPHOLOGY
Ascites
Portosystemic collaterals
Size of spleen
Diameter of stent (usually 8 to 10 mm)
Configuration of stent: areas of narrowing
Extension of stent into portal + hepatic veins
 HEMODYNAMICS
❑ Direction of flow in: extrahepatic portal vein, R + L
portal vein, SMV, splenic vein, all 3 hepatic veins,
intrahepatic IVC, paraumbilical vein, coronary vein
Peak blood flow velocity within main portal vein
Peak blood flow velocity within proximal + mid +
distal aspects of stent
 Doppler criteria for compromised TIPS function

1.Shunt velocity of 50cm/sec
compared with initial post-procedure value
3.Hepatofugal flow in main portal vein
 COMPLICATIONS
(A) Obstruction to flow
Shunt obstruction (38%)
Hepatic vein stenosis
(B)Trauma
(a)Vascular injury
Hepatic artery pseudoaneurysm
Arterioportal fistula
Intrahepatic/subcapsular hematoma
Hemoperitoneum (due to penetration of liver
capsule)
 (b)Biliary injury
Transient bile duct dilatation (due to hemobilia)
Bile collection

(C) Stent dislodgment with embolization to right
atrium, pulmonary artery, internal jugular vein.
Serious complications, reported in fewer than five percent of cases,
may include:
1. Occlusion, or complete blockage, of the stent and rapid
recurrence of symptoms
2. Infection of the stent or fabric lining
3. Abdominal bleeding that might require a transfusion
4.Laceration of the hepatic artery, which may result in severe liver
injury or bleeding that could require a transfusion or urgent
intervention
5.Heart arrhythmias or congestive heart failure.
6. Death (rare).
❖ Follow up with duplex sonography and shunt
angiography
❖Early shunt occlusion