ULNAR ARTERY PSEUDOANEURYSM (Color Doppler Evaluation)

Case History: A 30 years old was referred for evaluation of swelling in right

                       forearm following a trauma.

Findings: The  study was done on GE VOLUSON 730PRO color Doppler with 

                 10 MHz high frequency linear probe. Gray scale sonogram showed a large  thick walled complex pulsatile cystic mass with  mobile internal echoes adjacent to right ulnar artery ( Fig 1). Color Doppler image of the same lesion showed color flow signals within it with swirling pattern, suggestive of a vascular mass, probably pseudoaneurysm. An eccentric area of focal aliasing noted near ulnar artery through which blood is seen gushing in and out, s/o  neck of  pseudoaneurysm which is arising from the right ulnar artery proximal to wrist  (Fig 2). Turbulent flow was well demonstrated in pseudoaneurysm with the classic "ying-yang" appearance on color flow imaging (Fig 2, 3). Spectral Doppler sampling  from the pseudoaneurysm neck showed the characteristic to-and-fro blood flow pattern( Fig 4).                                             

Diagnosis: Post traumatic pseudoaneurysm of right ulnar artery.

Discussion: A pseudoaneurysm, or false aneurysm is a confined collection of thrombus and blood associated with disruption of one or more layers of an artery wall (1). Pseudoaneurysm is a typical complication of arterial puncture performed for diagnostic angiography or interventional procedures and is observed in up to 4% of persons after percutaneous transluminal angioplasty (PTA) and cardiac catheterization (Hust and Schuler 1992; Moll et al. 1991). A suture aneurysm is a

pseudoaneurysm developing after vascular surgery, in particular

after bypass operations.Less commonly, pseudoaneurysm can result from rupture of a native vessel or leakage at the site of a surgical anastamosis. Common femoral artery pseudoaneurysms complicating catheterization procedures are by far the most common. However, pseudoaneurysms can occur anywhere. Patients with pseudoaneurysms usually present with a mass in the

area of trauma that may be pulsatile ,as seen in this case.

 Pseudoaneurysms differ from true aneurysms in that the latter contain all three histologic layers of the arterial wall, whereas pseudoaneurysms contain less than three and often none of these layers and contained by only compressed fibrous tissue. The pseudoaneuyrsm lumen is connected to the underlying artery by a cylindrical neck-variable in length and diameter.

An aneurysm is seen on gray-scale images as a saccular or spindle-shaped dilatation of the vessel lumen.

The characteristic appearance of pseudoaneurysm in triplex ultrasound (B-mode combined with color and pulsed Doppler spectral analysis) include the presence of a hematoma of variable echogenicity, which may represent separate episodes of bleeding and rebleeding, expansile pulsatility and detection of turbulent flow (``yin-yang'' appearance) within the mass(Fig-3) [2].

The definitive diagnosis of pseudoaneurysm requires detection of the neck

connecting the pseudoaneurysm with the injured artery, and identification

within this neck of the pathognomonic``to and fro'' spectral waveform pattern (Fig-4) [3]. To-and-fro flow occurs in the neck of a pseudoaneurysm due to changing pressures: at the high intraluminal pressure during systole, blood flows through the narrow neck into the aneurysm at a rather high velocity. Under the reversed pressure conditions during diastole, the blood flows back into the artery at a slightly lower flow rate. Reflux is typically turbulent ( Fig 2).

Ultrasound is the imaging modality of choice to differentiate between pseudoaneurysm and non-communicating hematoma.

A false aneurysm must be differentiated from a perivascular hematoma with transmitted pulsation, but this is difficult on clinical grounds (Thomas et al. 1989). Using duplex ultrasound,an aneurysm can be differentiated from hypoechoic,

perivascular structures such as lymphnode, hematoma, seroma, or lymphocele by the depiction of to-and-fro flow, which is diagnostic of a pseudoaneurysm and requires no angiographic confirmation.

Arteriovenous (A-V) fistulas may coexist with pseudoaneurysms. Grayscale sonography rarely reveals any detectable abnormalities in patients with isolated A-V fistulas. In many patients high-velocity flow at the site of an A-V communications results in turbulence and focal perivascular tissue vibration. This can produce a dramatic color-Doppler display of random red and blue pixels in the perivascular soft tissues. Another hemodynamic consequence of an A-V fistula is decreased resistance to flow in the artery supplying the fistula. Direct arterial inflow into the vein produces turbulent flow in the venous lumen and often produces an arterialized venous waveform or a turbulent waveform.

The objective of doppler imaging is to differentiate between hematomas associated with pseudoaneurysm and those that are not. Whereas hematomas resolve spontaneously, a pseudoaneurysm can potentially rupture and therefore must be identified, closely monitored and in most instances, treated.

Before ultrasound enabled the precise localization of the aneurysmal neck relative to the skin surface, the treatment of choice was surgical closure. With advances in ultrasound equipment, it is now possible to occlude over 90% aneurysms by compression of the neck using color duplex imaging for guidance (Fellmeth et al. 1991; Hust et al. 1993). Thrombosis occurs after 10–30 min of compression.Success rates of 70–90% have been reported for ultrasound guided compression of pseudoaneurysm (Krumme et al. 1995; Lange et al. 2001) compared with 95–100% for induction of thrombosis by sonographically guided thrombin injection into the aneurysmal sac (Vicente and Kazmers 1999; Wixon et al. 2000).

So to conclude color Doppler US is  cost effective and reliable imaging modality to diagnose pseudoaneurysms, and can also be utilized for guided compression and thrombin therapy. 

Fig 1- Gray scale imaging showing complex cystic  pulsatile mass in forearm along ulnar artery
.

Fig-2 Color doppler imaging showing color aliasing at the neck of pseudoaneurysm due to turbulent blood flow.

Fig 3- Color flow imaging showing characteristic “yin-yang” sign due to swirling

          pattern of blood flow. The  red and blue color flow signals due to inflow and  

          outflow turn of blood respectively via neck of pseudoaneurysm.

Fig 4- Duplex spectral waveform sampling in the ulnar artery pseudoaneurysm  neck       

           demonstrating characteristic to-and-fro blood flow.

Contributed by: Dr. Subhash Tailor, Dr. Gopal Dhakar, Radiologists, Bhilwara,   

                          India.

Address for correspondence:-Dr.Gopal Dhakar,14 Ramsnehi hospital campus,

                                                  Bhilwara. Email-gld444@gmail.com.

References: .1. William J. Zwiebel, John S. Pellerito. Introduction to vascular

                             ultrasound, 5^th edition (2005), Elsevier Saunders, P 391-392.

  2. Carroll BA, Graif M, Orron DE. Vascular ultrasound. In: Kim DS,  

      Orron DE, eds. Peripheral Vascular Imaging and Intervention.

      St.Louis: Mosby Yearbook, 1992: 211±25.

                        3.Abu-Yousef MM, Wiese JA, Shamma AR. The ``to-and-fro'' gn:                                

                            Duplex Doppler evidence of femoral artery pseudo-neurysm. AJR  

                             1988;150:632