Abstract:Cyanoacrylates were first used for medical purposes during World War II to close skin wounds. Over time, medical applications were developed, specifically in the vascular field. Uses now range from extravascular instillation in vascular grafting to intravascular injection for embolization. These applications were made possible by the conduct of numerous preclinical studies involving a variety of tests and outcome measures, including angiographic and histological criteria. Cyanoacrylates were first harshly crit… Show more
“…The mean injected volume (including into the dead space) was 0.81 mL (0.50 mL–1.95 mL) in our rabbit model, compared to 0.43 mL (0.3–0.6 mL) in a dog model. We chose rabbits because they share with rodents the advantages of small size, ease of handling and housing, and relatively low cost compared to swine [ 15 , 29 , 30 ]. The species taking account corresponding coagulation parameters and vessel size may not substantially affect the behavior of NBCA mixtures, since polymerization is initiated and propagated by anions present in all mammals [ 18 , 31 , 32 ].…”
Section: Discussionmentioning
confidence: 99%
“…To date, in clinical practice, the glue concentration in the embolizing mixture and the injection rate are adjusted empirically to ensure that polymerization occurs at the target site. This adjustment requires extensive operator training and navigation of a potentially long and tricky learning curve [ 4 , 13 , 14 , 15 , 16 ]. Existing methods used to control NBCA polymerization include the pressure-cooker or blocked-blood-flow (BBF) technique, in which a second microcatheter occludes the vessel proximally to prevent the reflux and fragmentation of the glue injected distally through the first microcatheter [ 17 ].…”
Section: Introductionmentioning
confidence: 99%
“…Existing methods used to control NBCA polymerization include the pressure-cooker or blocked-blood-flow (BBF) technique, in which a second microcatheter occludes the vessel proximally to prevent the reflux and fragmentation of the glue injected distally through the first microcatheter [ 17 ]. Moreover, the polymerization rate can be slowed by decreasing the NBCA concentration in the embolic mixture via the addition of lipiodol (Lipiodol Ultra Fluid ® [LUF], Guerbet, Villepinte, France) [ 15 , 18 , 19 ]. The slower rate gives the operator more leeway, and the radiopacity of lipiodol enables fluoroscopic monitoring [ 19 ].…”
Section: Introductionmentioning
confidence: 99%
“…It was the first cyanoacrylate glue to receive the European Union certification mark for endovascular use. Nonetheless, few studies have focused on the specific polymerization characteristics of Glubran ® 2 to better anticipate its in vivo behavior [ 15 , 22 ]. We therefore chose to use Glubran ® 2 for an in vivo animal study with the objective of assessing glue distribution in the downstream vascular network and parenchymal penetration using ex vivo X-ray microtomography (micro-CT).…”
Although introduced decades ago, few cyanoacrylate glues have been approved for endovascular use, despite evidence of their usefulness, notably for complex procedures suchas hemostatic embolization. Indications include massive bleeding requiring emergent hemostasis and prevention of severe bleeding during scheduled surgery to remove a hypervascular tumor. Adding radiopaque Lipiodol Ultra Fluid® (LUF) modulates glue polymerization and allows fluoroscopic guidance, but few comparative in vivo studies have assessed the impact of the resulting change in glue concentration or of other factors such as target-vessel blood flow. In a rabbit model, we used ex vivo X-ray microtomography to assess the results of in vivo renal-artery embolization by various mixtures of N-butyl cyanoacrylate (NBCA), metacryloxysulfolane, and LUF. Overall, penetration to the superficial interlobular arteries was achieved in about two-thirds of cases and into the capillaries in nearly half the cases, while cast fragmentation was seen in slightly more than half the cases. Greater NBCA dilution and the blocked-blood-flow technique were independently associated with greater distality of penetration. Blocked-blood-flow injection was independently associated with absence of fragmentation, capillary penetration, a shorter cast-to-capsule distance, and higher cast attenuation. A larger mixture volume was independently associated with higher indexed cast ratio and deeper penetration. Finally, microtomography is an adapted tool to assess ex vivo distribution of glue cast.
“…The mean injected volume (including into the dead space) was 0.81 mL (0.50 mL–1.95 mL) in our rabbit model, compared to 0.43 mL (0.3–0.6 mL) in a dog model. We chose rabbits because they share with rodents the advantages of small size, ease of handling and housing, and relatively low cost compared to swine [ 15 , 29 , 30 ]. The species taking account corresponding coagulation parameters and vessel size may not substantially affect the behavior of NBCA mixtures, since polymerization is initiated and propagated by anions present in all mammals [ 18 , 31 , 32 ].…”
Section: Discussionmentioning
confidence: 99%
“…To date, in clinical practice, the glue concentration in the embolizing mixture and the injection rate are adjusted empirically to ensure that polymerization occurs at the target site. This adjustment requires extensive operator training and navigation of a potentially long and tricky learning curve [ 4 , 13 , 14 , 15 , 16 ]. Existing methods used to control NBCA polymerization include the pressure-cooker or blocked-blood-flow (BBF) technique, in which a second microcatheter occludes the vessel proximally to prevent the reflux and fragmentation of the glue injected distally through the first microcatheter [ 17 ].…”
Section: Introductionmentioning
confidence: 99%
“…Existing methods used to control NBCA polymerization include the pressure-cooker or blocked-blood-flow (BBF) technique, in which a second microcatheter occludes the vessel proximally to prevent the reflux and fragmentation of the glue injected distally through the first microcatheter [ 17 ]. Moreover, the polymerization rate can be slowed by decreasing the NBCA concentration in the embolic mixture via the addition of lipiodol (Lipiodol Ultra Fluid ® [LUF], Guerbet, Villepinte, France) [ 15 , 18 , 19 ]. The slower rate gives the operator more leeway, and the radiopacity of lipiodol enables fluoroscopic monitoring [ 19 ].…”
Section: Introductionmentioning
confidence: 99%
“…It was the first cyanoacrylate glue to receive the European Union certification mark for endovascular use. Nonetheless, few studies have focused on the specific polymerization characteristics of Glubran ® 2 to better anticipate its in vivo behavior [ 15 , 22 ]. We therefore chose to use Glubran ® 2 for an in vivo animal study with the objective of assessing glue distribution in the downstream vascular network and parenchymal penetration using ex vivo X-ray microtomography (micro-CT).…”
Although introduced decades ago, few cyanoacrylate glues have been approved for endovascular use, despite evidence of their usefulness, notably for complex procedures suchas hemostatic embolization. Indications include massive bleeding requiring emergent hemostasis and prevention of severe bleeding during scheduled surgery to remove a hypervascular tumor. Adding radiopaque Lipiodol Ultra Fluid® (LUF) modulates glue polymerization and allows fluoroscopic guidance, but few comparative in vivo studies have assessed the impact of the resulting change in glue concentration or of other factors such as target-vessel blood flow. In a rabbit model, we used ex vivo X-ray microtomography to assess the results of in vivo renal-artery embolization by various mixtures of N-butyl cyanoacrylate (NBCA), metacryloxysulfolane, and LUF. Overall, penetration to the superficial interlobular arteries was achieved in about two-thirds of cases and into the capillaries in nearly half the cases, while cast fragmentation was seen in slightly more than half the cases. Greater NBCA dilution and the blocked-blood-flow technique were independently associated with greater distality of penetration. Blocked-blood-flow injection was independently associated with absence of fragmentation, capillary penetration, a shorter cast-to-capsule distance, and higher cast attenuation. A larger mixture volume was independently associated with higher indexed cast ratio and deeper penetration. Finally, microtomography is an adapted tool to assess ex vivo distribution of glue cast.
“…These data are consistent with findings previously reported by other authors. 13 Figure 6.Polymerisation times for n-BCA and various pH solution mixtures. There was a slight delay in the polymerisation of n-BCA and pH-3-mixtures and a slight acceleration in the pH-11-mixtures in all n-BCA ( n = 3).…”
Section: Polymerisation Of N-butyl Cyanoacrylates In Mixturesmentioning
Objectives The objective is to investigate the interaction of sclero-embolic and contrast agents with the polymerisation of medical grade n-butyl-cyanoacrylates. Methods An in vitro spectrophotometric absorbance method was developed to detect changes in light transmission to measure n-BCA polymerisation. The initiation and the rate-of-polymerisation of mixtures of n-BCA with sclero-embolic and contrast agents were investigated. Results Initiation of polymerisation: VENABLOCK™ and HISTOACRYL® were the fastest agents to polymerise, while VENASEAL™ was the slowest. Rate of polymerisation: Hypertonic saline inhibited the polymerisation of all n-BCAs, while hypertonic glucose prolonged the polymerisation rate. ETHANOL and detergent sclerosants had no effect. Contrast agents OMNIPAQUE™ and ULTRAVIST® initiated and prolonged the polymerisation of n-BCA, but in contrast, LIPIODOL® failed to initiate the process. Conclusions The commercially available medical cyanoacrylates differ in their polymerisation rates. These polymerisation rates are further affected when these products are used in conjunction with other compounds, such as sclero-embolic and contrast agents.
BackgroundMiddle meningeal artery (MMA) embolization is a promising intervention as a stand-alone or adjunct treatment to surgery in patients with chronic subdural hematomas. There are currently no large animal models for selective access and embolization of the MMA for preclinical evaluation of this endovascular modality. Our objective was to introduce a novel in vivo model of selective MMA embolization in swine.MethodsDiagnostic cerebral angiography with selective microcatheter catheterization into the MMA was performed under general anesthesia in five swine. Anatomical variants in arterial meningeal supply were examined. In two animals, subsequent embolization of the MMA with a liquid embolic agent (Onyx-18) was performed, followed by brain tissue harvest and histological analysis.ResultsThe MMA was consistently localized as a branch of the internal maxillary artery just distal to the origin of the ascending pharyngeal artery. Additional meningeal supply was observed from the external ophthalmic artery, although not present consistently. MMA embolization with Onyx was technically successful and feasible. Histological analysis showed Onyx material within the MMA lumen.ConclusionsMicrocatheter access into the MMA in swine with liquid embolic agent delivery represents a reproducible model of MMA embolization. Anatomical variations in the distribution of arterial supply to the meninges exist. This model has a potential application for comparing therapeutic effects of various embolic agents in a preclinical setting that closely resembles the MMA embolization procedure in humans.
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