Although the use of endoscopic band ligation (EBL) for treatment of esophageal varices is well supported in the literature, its application for fundal variceal hemorrhage is limited. Initial case series revealed EBL to be safe and effective for the control of acute GVH [13, 14], but subsequent randomized controlled trials showed rebleeding rates as high as 60–70 % [15]. One prospective study that compared EBL to cyanoacrylate injection of gastric varices revealed comparable initial hemostasis (100 and 89 %, respectively), but a significantly higher rebleeding rate in the EBL group (72 % vs. 32 %) [16]. EBL is considered an ineffective treatment for sustained hemostasis of fundal variceal hemorrhage due to post-banding ulcers and recurrent hemorrhage after band sloughing (Fig. 13.3), as well as failure to completely ligate the deep aspect of the varix and its feeder vessel(s). Detachable snares or loops have also been used to ligate gastric varices. This technique was associated with low rebleeding rates (0–10 %) in two small studies [17, 18], although the technical challenge in loop placement and risk of torrential bleeding at the site of post-ligation ulcer have restricted the use of these devices in practice. Although EBL or loop ligation is not recommended as primary therapy for fundal variceal bleeding, these techniques can be considered in certain circumstances to temporarily arrest active bleeding from a fundal varix in order to buy time toward preparation for more definitive therapy (e.g., cyanoacrylate injection).

Endoscopic injection of sclerosants results in endothelial damage and thrombosis, leading to vascular obliteration [19]. Available sclerosing agents include absolute alcohol, fatty acid derivatives (e.g., ethanolamine oleate and sodium morrhuate), and synthetic chemicals (e.g., sodium tetradecyl sulfate and polidocanol). A sclerotherapy needle is passed through the working channel of the endoscope and the sclerosant is injected either into (intravariceal) or immediately adjacent (paravariceal) to the varix. Intravariceal injection results in direct occlusion of the vessel, while paravariceal injection occludes the vessel by submucosal fibrosis of tissue around the varix, leading to tamponade.

Although sclerotherapy in esophageal variceal hemorrhage is effective, with control of active bleeding in about 90 % of patients [20–23], its use in GVH is less impressive. The rates of initial hemostasis range from 44 to 92 %, with high rebleeding rates of 30–90 % and poor rates of eventual variceal obliteration [24–29]. Adverse events related to sclerotherapy include post-sclerotherapy ulceration with delayed bleeding and bacteremia/sepsis. Sclerotherapy is not recommended as first-line therapy for GVH unless no other options are available.

Thrombin assists in hemostasis by converting fibrinogen to a fibrin clot, as well as enhancing local platelet aggregation. Human thrombin is pooled from human plasma donors and is typically injected in aliquots of 1 ml per injection site, with an average dose of 1500–2000 units [31]. After the initial report of its use in 1947 by Daly [41], numerous small uncontrolled observational studies have shown thrombin to be an effective initial hemostatic agent for the treatment of gastric varices, with successful hemostasis in 70–100 % of patients and relatively low rebleeding rates [42–47]. There are no controlled trials of thrombin injection for gastric varices to date, although one trial that compared ethanolamine injection, with or without thrombin, showed lower rates of bleeding from the injection site in the thrombin group [48]. The cost of thrombin is substantially higher than cyanoacrylate, and further studies are needed before thrombin can be recommended as a primary treatment option for GVH.

Most centers perform glue injection under endoscopic guidance, which may result in injection adjacent to rather than within the varix. Data from sclerotherapy suggest that up to 60 % of injections are actually paravariceal in nature [49]. EUS-guided glue injection is attractive as it enables sonographic visualization for precise glue delivery into the variceal lumen. Furthermore, the technique allows for visualization of deeper varices as well as feeder vessels [50], which can be targeted separately. EUS can improve detection and visualization of gastric varices [51], especially in the setting of active bleeding which may obscure the endoscopic field of view. The monitoring of gastric varices with EUS and repeat injections until complete obliteration have been shown to decrease rebleeding rates [52], and color Doppler can be used to confirm complete variceal obliteration with absence of blood flow.

A large variety of embolization coils are available for transcatheter vascular use. Many of these fit through EUS fine-needle aspiration (FNA) needles and can be utilized for EUS-guided angiotherapy. The coils used at our institution are made of Inconel, a nickel-based superalloy. The coils contain radially extending, synthetic fibers that help induce clot formation and hemostasis. The coils are MRI conditional and can be used in a static magnetic field of 3 T or less. A variety of coil sizes and lengths are available. A 0.035-in. coil will fit through a 19-gauge FNA needle (Fig. 13.5). Straightened coil lengths range from 2 cm to 15 cm, with coiled diameters of 2 mm to 20 mm and approximate number of loops ranging from 1.9 to 5.6. Smaller 0.018-in. coils are also available and will fit through a 22-gauge FNA needle. Coil selection depends on the size of the varix, but typically a coiled diameter of 10–20 mm is optimal.

EUS-guided coil injection for acute variceal bleeding was initially reported in 2008 [53]. Embolization was accomplished using microcoils through a 22-gauge FNA needle for variceal obliteration of ectopic varices surrounding a choledochojejunal anastomosis. A retrospective trial of 30 patients comparing EUS-guided coil injection to EUS-guided cyanoacrylate injection revealed similar obliteration rates, but fewer endoscopy sessions were required in the coil group (82 % vs. 53 % obliteration in a single treatment session) [54]. Of note, the intended therapy was for coil injection when feasible, but only 11 of 30 patients underwent such therapy due to technical difficulties hindering the use of coils. The rate of adverse events was significantly higher in the cyanoacrylate group (58 % vs. 9 %), although 9 of the 11 adverse events in the cyanoacrylate group were asymptomatic pulmonary glue embolisms found on routine post-procedure CT. This indicates that glue embolization is occurring more commonly than appreciated, but that it rarely causes symptoms.

EUS-guided angiotherapy requires additional training and expertise in interventional EUS and performance of the technique appears currently limited to a very small number of tertiary centers. EUS-guided angiotherapy faces several challenges compared to standard endoscopic techniques, including a smaller echoendoscope channel size with limited suction capability and the required ultrasound processor, which makes bedside endoscopy in the intensive care unit difficult. Identification of the feeder vessel can also be challenging and time-consuming. Accidental injection of cyanoacrylate into an efferent vessel would not provide variceal obliteration and could increase the risk of embolization. Lastly, EUS-guided therapy is more suitable for localized gastric varices from a single feeder vessel, whereas a diffuse variceal network may not be amenable to EUS-guided therapy [55].

Our center has developed an EUS-guided approach consisting of coil placement followed immediately by glue injection into the same varix. We theorized that the coil provides a scaffold for glue retention at the site of intravariceal injection. We believe the combination of coil and glue may enhance the rates of hemostasis and variceal obliteration while decreasing the risk of glue embolization.

The procedural protocol at our center for combined EUS-guided coil and glue injection is as follows (Table 13.2 and Fig. 13.6):