IJGII Inernational Journal of Gastrointestinal Intervention

pISSN 2636-0004 eISSN 2636-0012


home All Articles View

Review Article

Gastrointestinal Intervention 2018; 7(3): 131-135

Published online October 31, 2018 https://doi.org/10.18528/gii180025

Copyright © International Journal of Gastrointestinal Intervention.

New endoscopic techniques in treating gastrointestinal bleeding

Young Sin Cho

Division of Gastroenterology, Department of Internal Medicine, Soonchunhyang University Cheonan Hospital, Soonchunhyang University College of Medicine, Cheonan, Korea

Correspondence to:*Division of Gastroenterology, Department of Internal Medicine, Soonchunhyang University Cheonan Hospital, Soonchunhyang University College of Medicine, 31 Suncheonhyang 6-gil, Dongnam-gu, Cheonan 31151, Korea. E-mail address: ys-jo98@hanmail.net (Y.S. Cho). ORCID: https://orcid.org/0000-0001-7090-2921

Received: July 16, 2018; Revised: September 14, 2018; Accepted: September 14, 2018

This is an open-access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/3.0) which permits unrestricted noncommercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Gastrointestinal (GI) bleeding is a common disorder encountered in an emergency department or primary clinical setting. The therapeutic basis for GI bleeding is endoscopic hemostasis. To date, epinephrine injection, through-the-scope clips, monopolar or biopolar coagulation, and band ligation have been established for GI bleeding. Despite the advances in endoscopic techniques, we often experience re-bleeding associated with significant inhospital mortality in GI bleeding. New devices that complement the disadvantages of these conventional endoscopic techniques have recently been introduced. For example, over-the-scope clip, which has wider and stronger pressure than conventional mechanical devices, can ligate a wide range of surrounding mucous membranes and has been reported to be effective in severe lesions of fibrosis. In addition, hemostatic powders achieved successful hemostasis as primary or rescue therapy in several cases of GI bleeding. Successful application of these new techniques requires appropriate patient selection and understanding of the device and further research is expected in the future.

Keywords: Bleeding, Clip, Hemostasis, endoscopic

Gastrointestinal (GI) bleeding is a serious illness, with a high mortality rate observed in clinical practice. Endoscopy plays an important role in risk stratification and treatment of patients with GI bleeding. In cases of GI bleeding, endoscopic hemostasis is usually performed using injection therapy, mechanical therapy with clips, loops, or ligation, and thermal therapy with argon plasma coagulation (APC) and bipolar or monopolar probes. A recent meta-analysis published by Baracat et al1 recommended the application of hemoclips or the combined use of injection therapy with thermal coagulation for the treatment of peptic ulcer bleeding.

Injecting epinephrine into a hemorrhagic site is a relatively easy procedure, and it is generally used because of its low cost. Injection therapy with epinephrine induces compression of lesion, vasoconstriction, and platelet activation, thus providing a hemostatic effect. Although a local injection of epinephrine diluent is reported to be more effective than a proton pump inhibitor alone, the hemostatic efficacy achieved is lower than that achieved with other endoscopic therapies, and about 20% of re-bleeding is reported when it is used alone. Therefore, a local injection of an epinephrine diluent is generally recommended for temporary endoscopic hemostasis or reduction of bleeding rate prior to other endoscopic hemostasis procedures.

Mechanical therapy using hemoclips is a well-established method of treating patients with GI bleeding. Several randomized studies have demonstrated the clinical efficacy of hemoclips in the treatment of bleeding peptic ulcers, Mallory-Weiss syndrome, and Dieulafoy’s lesions.24 However, the use of hemoclips in GI bleeding can be limited due to poor angulation and mobility of the endoscope. If the clip ligation is not performed accurately and delicately, the exposed blood vessels or the surrounding mucous membranes may be torn by the clip, which may thus further promote bleeding. In addition, clips that are ligated in the wrong position may be an obstacle to secondary treatment, if any.

Thermal coagulation is a method of causing hemostasis by applying direct or indirect heat to induce edema of tissue, coagulation of tissue protein, contraction of blood vessels, and the coagulation process. Contact coagulation induces thermal coagulation by direct contact (of hemostatic forceps, an electrocautery probe, or a heater probe) with a hemorrhagic lesion. Noncontact therapy is carried out without contact with tissues, using APC. Contact thermal therapy is effective for spurting bleeding, but achieving hemostasis can be difficult where direct contact is difficult. Non-contact methods, such as APC, can be used to obtain hemostasis, without limitation of location, and hemostasis can be achieved in a wide area. However, because deep penetration is limited, it is difficult to achieve hemostasis in deep vein.5 In addition, rare complications, such as pneumoperitoneum, pneumomediastinum, and perforation may occur.

Although the various hemostatic methods described above are known to effectively induce early hemostasis, there is a risk of re-bleeding. Depending on the location, characteristics, and extent of hemorrhagic lesions, hemostasis in GI bleeding may not be satisfactory. Therefore, in this article, we will review the recently introduced modalities of endoscopic hemostasis and explore their clinical usefulness.

Hemoclips were among the first therapeutic devices for flexible GI endoscopy. The clip design and delivery systems for endoscopic hemostasis continue to evolve. Clip devices are classified into two types according to the delivery system: through-the-scope (TTS) clips, where the clips are pre-loaded with a transparent detachable cap at the distal end of the scope, and over-the-scope clips (OTSC).

TTS clip

The TTS clips are available from different manufacturers and may have different opening lengths. The EZ clip is a commonly used device in South Korea. The EZ clip (Olympus Medical, Tokyo, Japan) has a different size with a short clip (5 mm), a standard clip (7 mm), and a long clip (9 mm). There are two types of angles: 90° and 135°. The EZ clip has the advantage of allowing rotation of the arm of the clip according to the position of the lesion, thereby allowing precise positioning, but the disadvantage is that the clip cannot be reopened after the handle operation. Several clip devices have been introduced to overcome these drawbacks. The QuickClip2 (Olympus America, Center Valley, PA, USA) has an opening diameter of 11 mm, and was designed to improve the ease of rotation to orient the clip to a target lesion; it can be opened and closed. The Resolution Clip (Boston Scientific, Natick, MA, USA) can also be opened and closed, and it has an 11-mm opening diameter (Fig. 1).6

Over-the-scope clip

In clinical practice, achieving hemostasis by using a TTS clip is limited in the case of bleeding lesions with difficult-to-access locations, arterial spurting in large vessels (of 2–3 mm diameter), and rigid lesions with fibrosis. To overcome the limitation of TTS clips, the over-the-scope clip (OTSC; Ovesco Endoscopy, Tuebingen, Germany) was developed and introduced in 2007.7 According to the U.S. Food and Drug Administration recommendations, the OTSC is approved for the following hemostatic indications: (1) bleeding ulcers, (2) arteries < 2 mm in diameter, (3) colon diverticula, (4) polyps < 1.5 cm in diameter, and (5) mucosal/submucosal defects < 3 cm.8

The OTSC system is mounted onto the distal tip of the endoscope, in a manner almost similar to how it is done with the band ligation device. Since the technique of this system is similar to that of the band ligation used earlier, it would be easy to use if endoscopists are familiar with variceal band ligation. The OTSC is made of nitinol (which has high elasticity) in the form of bear claws. Available clip sizes range from 11 to 14 mm. Three versions of OTSCs are available: a blunt atraumatic type, with pointed traumatic edges, and a clip for gastric wall closure with features of both the traumatic and atraumatic OTSC.9 Two accompanying aids, the twin grasper and anchor, may be used to approximate the tissue margins of large or fibrotic gaping defects, and to pull these into the transparent cap before releasing the clip (Fig. 2).

In previous studies, the OTSC was mainly used for perforation or closure of fistula, but it can be used effectively for GI bleeding. It can be particularly used in GI bleeding that is recalcitrant to conventional attempts at achieving endoscopic hemostasis. A recent study demonstrated the efficacy and safety of the use of OTSC in GI bleeding, resulting in a salvage endoscopic treatment. Manta et al10 reported that 30 patients who failed conventional endoscopic hemostasis underwent OTSC-based hemostasis. A total of 29 patients had primary hemostasis. Two patients experienced re-bleeding, requiring repeated endoscopic hemostasis. In one patient with a posterior wall duodenal ulcer, emergency radiological embolization was required to stop the bleeding after failure of the OTSC procedure. In another study, technical success rate was 100% for hemostasis with OTSC, and there were re-bleeding in two cases.11 Therefore, the authors concluded that the OTSC should be considered in patients with refractory bleeding, after failure of conventional methods of endoscopic hemostasis.

The use of OTSC to achieve primary hemostasis in GI bleeding has been reported in a small case series. Primary hemostasis in GI bleeding was achieved in 85% to 100% cases.10,12,13 In a recent study, Wedi et al14 reported the usefulness of OTSC as a first-line treatment for GI bleeding. In this study, the authors compared the re-bleeding, mortality, and mortality after re-bleeding in the Rockall cohort showing current procedure with the cohort using OTSC as first-line treatment. Primary hemostasis, using OTSC, was successful in 92.4% cases, and the mortality rate after re-bleeding was significantly reduced from 27.9% to 10.9% in the high-risk group with a Rockall risk category of 8 or more. The authors also reported that primary hemostasis using OTSC significantly reduced re-bleeding in the group that had a Rockall risk category 4 and above. Therefore, the authors noted that OTSC could be used as an alternative to standard hemostasis care in high-risk patients. However, this study was not a randomized, controlled study. As a control group, the Rockall cohort had the limitation of past treatment outcome. Therefore, additional prospective, randomized controlled studies are needed.

Severe complications, such as complete lumen closure secondary to clip misplacement and mucosal injury caused by the pointed teeth of the OTSC have been rarely described in the literature.15,16 Therefore, caution should be exercised when inserting the OTSC into a relatively narrow area, such as the cricopharynx or the pylorus. The main disadvantage of the OTSC is a need to withdraw the endoscope to mount the OTSC. Another disadvantage is that it is difficult to pass it through the upper esophageal sphincter or luminal stricture. Additional treatment is difficult if the OTSC is installed poorly. In addition, prices higher than that of normal clips limit OTSC accessibility. Prospective randomized studies and cost-effective analyses comparing OTSC with conventional clip devices are needed.

Endoscopic hemostasis using a mechanical device is an effective method, but it has limited efficacy in diffuse bleeding lesions. Therefore, the need for other methods to achieve hemostasis has been suggested. Topical agents for endoscopic hemostasis have been introduced in a relatively simple, safe, and effective way. In recent literature, hemostatic powders that have been introduced for endoscopic hemostasis include Hemospray (Cook Medical, Winston-Salem, NC, USA), EndoClot (EPI, Santa Clara, CA, USA), and Ankaferd Blood Stopper (ABS) (Ankaferd Health Products, Istanbul, Turkey) (Table 1).8


Hemospray (also named TC-325) is an inorganic powder that was developed by the armed forces for control of bleeding in military personnel during operations. This mineral powder is highly adhesive, absorbs liquid from the blood, and forms a sticky film when adsorbed on hemorrhagic lesions. The adsorbed powder increases the concentration of coagulation factors, activates platelets, and ultimately forms a plug in the wounded blood vessels.17 This powder does not contain human or animal proteins or plant substances, and does not have known allergens. Hemospray powder is delivered via a carbon dioxide-powered delivery system through a 7-Fr or 10-Fr catheter, and inserted through the working channel of an endoscope, which provides access to the site of the bleeding.18

Sung et al19 reported a human study in which Hemospray was used in 20 patients with peptic ulcer bleeding. Acute hemostasis was achieved in 95% of the patients (19/20), and bleeding recurred in 2 patients within 72 hours. No mortality, major adverse events, or treatment- or procedure-related serious events were reported during the 30-day follow-up. The clinical outcome of the use of Hemospray in upper GI bleeding, collected in 10 European centers using the multicenter survey in 2013, has been published.20 A total of 63 patients were included in the study, of which 30 patients had peptic ulcer bleeding. In upper GI bleeding, use of Hemospray resulted in a primary hemostasis rate of 85% when used as a monotherapy, and re-bleeding rate at 7 days was 15%. Eight patients, who failed conventional endoscopic hemostasis, underwent rescue therapy with Hemospray. The primary hemostasis rate was 100% and the re-bleeding rate at 7 days was 25%.

Hemospray is reported to be effective in diffuse bleeding lesions. Smith et al21 reported endoscopic hemostasis using Hemospray in four patients with non-variceal diffuse portal hypertensive bleeding. Chen et al22 describes the first 5 cases of malignant diffuse GI bleeding managed with Hemospray. Initial hemostasis was achieved in all patients, with only one case of re-bleeding. Other bleeding sources treated by Hemospray in upper GI bleeding include varices, post-procedure bleeding (sphincterotomy, endoscopic submucosal dissection).2326

No procedure-related complications were associated with the use of Hemospray. Theoretically possible side effects of Hemospray include embolization, intestinal obstruction, and allergic reaction to the powder. Because of the low pressure of carbon dioxide used for spraying the Hemospray powder, the actual risk for embolism is very low.27 GI obstruction is another possible risk as it is sloughed off from the GI wall and passes into the small intestine. If hemostasis fails, there is the disadvantage that the powder attached to the mucous membrane may limit the use of other hemostatic modalities, and Hemospray works only on active bleeding.18

Ankaferd Blood Stopper (ABS)

ABS is a plant-derived hemostatic agent used in Turkey as a topical treatment for dental and postsurgical external bleeding. ABS consists of a mixture of five herbs and can be dispensed in the form of ampoules, pads, and sprays. A preparation of 100 mL of ABS is composed of a standardized mixture of plants, including 5 mg Thymus vulgaris (dried grass extract), 9 mg Glycyrrhiza glabra (dried leaf extract), 8 mg Vitis vinifera (dried leaf extract), 7 mg Alpinia officinarum (dried leaf extract), and 6 mg Urtica dioica (dried root extract).28 Although the exact hemostatic mechanism of action of ABS is unknown, it is understood that erythrocyte aggregation and the formation of an encapsulated protein scaffold network have a hemostatic effect.29,30

The endoscopic hemostasis effect produced by ABS was reported in case reports and series for treatment of post-polypectomy bleeding, Mallory-Weiss syndrome, Dieulafoy lesions, radiation colitis, and bleeding from tumors.31 The hemostatic efficacy of ABS in published case reports is promising. However, additional prospective randomized controlled studies are needed.


The EndoClot polysaccharide hemostatic system is a non-contact endoscopic device that has recently been developed and sprays hemostatic powder. Its exact component is not known but consists of absorbable modified polysaccharides derived from plant starches that do not contain animal or human components. The EndoClot is observed as a white powder, and when this powder is sprayed on a bleeding lesion, it rapidly absorbs water from the blood. This dehydration process increases the concentration of platelets, red blood cells, and coagulation proteins (thrombin, fibrinogen, etc.) and forms a gelled, adhesive matrix that acts as a mechanical barrier to prevent bleeding.32

EndoClot has a powder in the chamber that works through a 2,300-mm delivery catheter through the working channel of the endoscope. The external air compressor produces sustained pressure that forces the powder in the chamber through the catheter to reach the bleeding lesion. Generally, particles of EndoClot are widely sprayed, so they can be easily used even in a difficult position to access the endoscope. In addition, there is no need to contact the catheter directly with the bleeding lesion during powder distribution, so it does not promote additional mucosal injury or bleeding (Fig. 3).

Huang et al33 first applied EndoClot for controlling and preventing bleeding related to endoscopic mucosal resection in 181 lesions in 81 patients. Delayed bleeding was observed in 3 patients that did not have immediate post-procedural bleeding. No major adverse events of the EndoClot therapy during a 30-day follow-up reported. In an observational study, endoscopic hemostasis using EndoClot was performed in 21 patients and immediate hemostasis was achieved in all patients. The 30-day re-bleeding rate in these patients was 4.8%.34 Recent studies have compared EndoClot and conventional hemostatic therapies using propensity score matching in non-variceal upper GI bleeding. In this study, 40 patients who received EndoClot therapy and 303 patients who received conventional therapy were compared. The rate of immediate hemostasis and re-bleeding of 7-day and 30-day did not differ between the two groups. Complications associated with EndoClot were not reported in this study.35

Recently, mechanical devices such as OTSC and various hemostatic powders have been introduced as a new method for endoscopic hemostasis in GI bleeding. These techniques and devices have been reported to be useful as primary therapy as well as rescue therapy in cases of failure of conventional hemostasis. Successful application of this technique depends on the appropriate indication and the endoscopist’s experience in using this device. Therefore, additional experience and comparative studies of the new techniques are warranted.

The image of over-the-scope clips were provided by Yunho Jung. The image of Resolution Clip was provided by Boston Scientific.

Fig. 1. Resolution Clip (Boston Scientific). (A) For-rest IIa ulcer in the body. (B) Hemostasis failed with conventional clip. (C) Resolution Clip. (D) Appearance following Resolution Clip.
Fig. 2. Over-the-scope clips (OTSC; Ovesco Endoscopy). (A) Tracheoesophageal fistula with active bleeding. (B) Appearance following OTSC placement.
Fig. 3. Endoscopic application of EndoClot (EPI). (A) Duodenal ulcer with active bleeding. (B) Endocopic appearance of EndoClot when applied to a bleeding lesion.

Overview on the Commercially Available Substance for Topical Application17

Contains Mechanism of action Approved human application Formulation
Ankaferd blood stopper Herbal mixture Protein networks, clotting cascade Dental procedure Tampons, sprays, ampoules
Hemospray Mineral powder Absorbs H2O, mechanical tamponade, clotting cascade Nonvariceal gastrointestinal bleeding CO2 pressurized handheld canister
EndoClot Absorbable polymere Absorbs H2O, concentrate cells, clotting cascade Adjuvant hemostatic therapy Pressurized air compressor
  1. Baracat, F, Moura, E, Bernardo, W, Pu, LZ, Mendonça, E, and Moura, D (2016). Endoscopic hemostasis for peptic ulcer bleeding: systematic review and meta-analyses of randomized controlled trials. Surg Endosc. 30, 2155-68.
    Pubmed CrossRef
  2. Gevers, AM, De Goede, E, Simoens, M, Hiele, M, and Rutgeerts, P (2002). A randomized trial comparing injection therapy with hemoclip and with injection combined with hemoclip for bleeding ulcers. Gastrointest Endosc. 55, 466-9.
    Pubmed CrossRef
  3. Chung, IK, Kim, EJ, Hwang, KY, Kim, IH, Kim, HS, and Park, SH (2002). Evaluation of endoscopic hemostasis in upper gastrointestinal bleeding related to Mallory-Weiss syndrome. Endoscopy. 34, 474-9.
    Pubmed CrossRef
  4. Park, CH, Sohn, YH, Lee, WS, Joo, YE, Choi, SK, and Rew, JS (2003). The usefulness of endoscopic hemoclipping for bleeding Dieulafoy lesions. Endoscopy. 35, 388-92.
    Pubmed CrossRef
  5. Kim, KB, Yoon, SM, and Youn, SJ (2014). Endoscopy for nonvariceal upper gastrointestinal bleeding. Clin Endosc. 47, 315-9.
    Pubmed KoreaMed CrossRef
  6. Brock, AS, and Rockey, DC (2015). Mechanical hemostasis techniques in nonvariceal upper gastrointestinal bleeding. Gastrointest Endosc Clin N Am. 25, 523-33.
    Pubmed CrossRef
  7. Kirschniak, A, Kratt, T, Stüker, D, Braun, A, Schurr, MO, and Königsrainer, A (2007). A new endoscopic over-the-scope clip system for treatment of lesions and bleeding in the GI tract: first clinical experiences. Gastrointest Endosc. 66, 162-7.
    Pubmed CrossRef
  8. Weilert, F, and Binmoeller, KF (2016). New endoscopic technologies and procedural advances for endoscopic hemostasis. Clin Gastroenterol Hepatol. 14, 1234-44.
    Pubmed CrossRef
  9. Goenka, MK, Rai, VK, Goenka, U, and Tiwary, IK (2017). Endoscopic management of gastrointestinal leaks and bleeding with the over-the-scope clip: a prospective study. Clin Endosc. 50, 58-63.
    Pubmed KoreaMed CrossRef
  10. Manta, R, Galloro, G, Mangiavillano, B, Conigliaro, R, Pasquale, L, and Arezzo, A (2013). Over-the-scope clip (OTSC) represents an effective endoscopic treatment for acute GI bleeding after failure of conventional techniques. Surg Endosc. 27, 3162-4.
    Pubmed CrossRef
  11. Chan, SM, Chiu, PW, Teoh, AY, and Lau, JY (2014). Use of the over-the-scope clip for treatment of refractory upper gastrointestinal bleeding: a case series. Endoscopy. 46, 428-31.
    Pubmed CrossRef
  12. Baron, TH, Song, LM, Ross, A, Tokar, JL, Irani, S, and Kozarek, RA (2012). Use of an over-the-scope clipping device: multicenter retrospective results of the first U.S. experience (with videos). Gastrointest Endosc. 76, 202-8.
    Pubmed CrossRef
  13. Wedi, E, Gonzalez, S, Menke, D, Kruse, E, Matthes, K, and Hochberger, J (2016). One hundred and one over-the-scope-clip applications for severe gastrointestinal bleeding, leaks and fistulas. World J Gastroenterol. 22, 1844-53.
    Pubmed KoreaMed CrossRef
  14. Wedi, E, Fischer, A, Hochberger, J, Jung, C, Orkut, S, and Richter-Schrag, HJ (2018). Multicenter evaluation of first-line endoscopic treatment with the OTSC in acute non-variceal upper gastrointestinal bleeding and comparison with the Rockall cohort: the FLETRock study. Surg Endosc. 32, 307-14.
    Pubmed CrossRef
  15. Parodi, A, Repici, A, Pedroni, A, Blanchi, S, and Conio, M (2010). Endoscopic management of GI perforations with a new over-the-scope clip device (with videos). Gastrointest Endosc. 72, 881-6.
    Pubmed CrossRef
  16. Nishiyama, N, Mori, H, Kobara, H, Rafiq, K, Fujihara, S, and Kobayashi, M (2013). Efficacy and safety of over-the-scope clip: including complications after endoscopic submucosal dissection. World J Gastroenterol. 19, 2752-60.
    Pubmed KoreaMed CrossRef
  17. Barkun, AN, Moosavi, S, and Martel, M (2013). Topical hemostatic agents: a systematic review with particular emphasis on endoscopic application in GI bleeding. Gastrointest Endosc. 77, 692-700.
    Pubmed CrossRef
  18. Changela, K, Papafragkakis, H, Ofori, E, Ona, MA, Krishnaiah, M, and Duddempudi, S (2015). Hemostatic powder spray: a new method for managing gastrointestinal bleeding. Therap Adv Gastroenterol. 8, 125-35.
    Pubmed KoreaMed CrossRef
  19. Sung, JJ, Luo, D, Wu, JC, Ching, JY, Chan, FK, and Lau, JY (2011). Early clinical experience of the safety and effectiveness of Hemospray in achieving hemostasis in patients with acute peptic ulcer bleeding. Endoscopy. 43, 291-5.
    Pubmed CrossRef
  20. Smith, LA, Stanley, AJ, Bergman, JJ, Kiesslich, R, Hoffman, A, and Tjwa, ET (2014). Hemospray application in nonvariceal upper gastrointestinal bleeding: results of the survey to evaluate the application of hemospray in the luminal tract. J Clin Gastroenterol. 48, e89-92.
    Pubmed CrossRef
  21. Smith, LA, Morris, AJ, and Stanley, AJ (2014). The use of hemospray in portal hypertensive bleeding; a case series. J Hepatol. 60, 457-60.
    Pubmed CrossRef
  22. Chen, YI, Barkun, AN, Soulellis, C, Mayrand, S, and Ghali, P (2012). Use of the endoscopically applied hemostatic powder TC-325 in cancer-related upper GI hemorrhage: preliminary experience (with video). Gastrointest Endosc. 75, 1278-81.
    Pubmed CrossRef
  23. Holster, IL, Poley, JW, Kuipers, EJ, and Tjwa, ET (2012). Controlling gastric variceal bleeding with endoscopically applied hemostatic powder (Hemospray). J Hepatol. 57, 1397-8.
    Pubmed CrossRef
  24. Ibrahim, M, El-Mikkawy, A, Mostafa, I, and Devière, J (2013). Endoscopic treatment of acute variceal hemorrhage by using hemostatic powder TC-325: a prospective pilot study. Gastrointest Endosc. 78, 769-73.
    Pubmed CrossRef
  25. Moosavi, S, Chen, YI, and Barkun, AN (2013). TC-325 application leading to transient obstruction of a post-sphincterotomy biliary orifice. Endoscopy. 45, E130.
    Pubmed CrossRef
  26. Curcio, G, Granata, A, and Traina, M (2014). Hemospray for multifocal bleeding following ultra-low rectal endoscopic submucosal dissection. Dig Endosc. 26, 606-7.
    Pubmed CrossRef
  27. Babiuc, RD, Purcarea, M, Sadagurschi, R, and Negreanu, L (2013). Use of Hemospray in the treatment of patients with acute UGIB: short review. J Med Life. 6, 117-9.
    Pubmed KoreaMed
  28. Goker, H, Haznedaroglu, IC, Ercetin, S, Kirazli, S, Akman, U, and Ozturk, Y (2008). Haemostatic actions of the folkloric medicinal plant extract Ankaferd Blood Stopper. J Int Med Res. 36, 163-70.
    Pubmed CrossRef
  29. Satar, NY, Akkoc, A, Oktay, A, Topal, A, and Inan, K (2013). Evaluation of the hemostatic and histopathological effects of Ankaferd Blood Stopper in experimental liver injury in rats. Blood Coagul Fibrinolysis. 24, 518-24.
    Pubmed CrossRef
  30. Haznedaroglu, BZ, Haznedaroglu, IC, Walker, SL, Bilgili, H, Goker, H, and Kosar, A (2010). Ultrastructural and morphological analyses of the in vitro and in vivo hemostatic effects of Ankaferd Blood Stopper. Clin Appl Thromb Hemost. 16, 446-53.
    Pubmed CrossRef
  31. Boškoski, I, Familiari, P, and Costamagna, G (2014). New and emerging endoscopic therapies for gastrointestinal bleeding. Curr Opin Gastroenterol. 30, 439-43.
    Pubmed CrossRef
  32. Garber, A, and Jang, S (2016). Novel therapeutic strategies in the management of non-variceal upper gastrointestinal bleeding. Clin Endosc. 49, 421-4.
    Pubmed KoreaMed CrossRef
  33. Huang, R, Pan, Y, Hui, N, Guo, X, Zhang, L, and Wang, X (2014). Polysaccharide hemostatic system for hemostasis management in colorectal endoscopic mucosal resection. Dig Endosc. 26, 63-8.
    Pubmed CrossRef
  34. Beg, S, Al-Bakir, I, Bhuva, M, Patel, J, Fullard, M, and Leahy, A (2015). Early clinical experience of the safety and efficacy of EndoClot in the management of non-variceal upper gastrointestinal bleeding. Endosc Int Open. 3, E605-9.
    Pubmed KoreaMed CrossRef
  35. Park, JC, Kim, YJ, Kim, EH, Lee, J, Yang, HS, and Kim, EH (2018). Effectiveness of the polysaccharide hemostatic powder in non-variceal upper gastrointestinal bleeding: using propensity score matching. J Gastroenterol Hepatol. 33, 1500-6.
    Pubmed CrossRef