Duplex-guided foam sclerotherapy for the treatment of the symptomatic venous malformations of the face.

BACKGROUND:New sclerosing foam is considered to have the advantage of causing more damage on the intima than liquid form. Therefore we recently applied duplex-guided foam sclerotherapy in a patient with venous malformations of the face.METHODS:A 20-year-old man was referred to our institute for the evaluation and treatment of vascular malformations of the face. Preoperative duplex scanning and magnetic resonance imaging (MRI) revealed subcutaneous and intramuscular venous malformations. The sclerosing foam was produced by Tessari's method using 1% polidocanol, and the duplex-guided foam sclerotherapy was performed under general anesthesia. A 20-gauge plastic needle was inserted into the venous space using ultrasound guidance and a total of 5 ml of sclerosing foam was infused followed by immediate tie-over dressing.RESULTS:The venous malformations were successfully reduced in size and postoperative MRI showed significant reduction of the venous malformations.CONCLUSION:Although further collective study is necessary to ensure the validity of this treatment, duplex-guided foam sclerotherapy could have great promise in the treatment of symptomatic venous malformations.61962

Hemodynamic Characterization of Peripheral Arterio-venous Malformations

Peripheral arterio-venous malformations (pAVMs) are congenital vascular anomalies that require treatment, due to their severe clinical consequences. The complexity of lesions often leads to misdiagnosis and ill-planned treatments. To improve disease management, we developed a computational model to quantify the hemodynamic effects of key angioarchitectural features of pAVMs. Hemodynamic results were used to predict the transport of contrast agent (CA), which allowed us to compare our findings to digital subtraction angiography (DSA) recordings of patients. The model is based on typical pAVM morphologies and a generic vessel network that represents realistic vascular feeding and draining components related to lesions. A lumped-parameter description of the vessel network was employed to compute blood pressure and flow rates. CA-transport was determined by coupling the model to a 1D advection–diffusion equation. Results show that the extent of hemodynamic effects of pAVMs, such as arterial steal and venous hypertension, strongly depends on the lesion type and its vascular architecture. Dimensions of shunting vessels strongly influence hemodynamic parameters. Our results underline the importance of the dynamics of CA-transport in diagnostic DSA images. In this context, we identified a set of temporal CA-transport parameters, which are indicative of the presence and specific morphology of pAVMs