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Sucralfate (Sucrose octasulfate–aluminum complex) Sale

目录号 : GC31777

A basic aluminum sucrose sulfate complex with gastroprotective activity

Sucralfate (Sucrose octasulfate–aluminum complex) Chemical Structure

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10mM (in 1mL DMSO)
¥491.00
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100mg
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500mg
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产品描述

Sucralfate is a basic aluminum sucrose sulfate complex that has gastroprotective activity.1 It inhibits rat pepsin in a concentration-dependent manner and pepsin activity in isolated human gastric juice. It also inhibits ulcer formation induced by pyloric ligation, indomethacin , or cysteamine in rats. Sucralfate (5,600 mg/animal) is protective against neutral ethanol and acidified taurocholic acid-induced damage in a rat model of hydrochloric acid-induced gastric mucosal damage, increasing the pH and reducing the disappearance of hydrogen ions.2 Formulations containing sucralfate have been used as antacids in the treatment of duodenal ulcer.

1.Borella, L.E., Seethaler, K., and Lippmann, W.Sucralfate: Antipeptic, antiulcer activities and antagonism of gastric emptyingArzneimittelforschung29(5)793-798(1979) 2.Harrington, S.J., Schlegel, J.F., and Code, C.F.The protective effect of sucralfate on the gastric mucosa of ratsJ. Clin. Gastroenterol.3(Suppl 2)129-134(1981)

Chemical Properties

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Research Update

Sucralfate and soluble sucrose octasulfate bind and stabilize acidic fibroblast growth factor

The actions of the anti-ulcer drug sucralfate have been proposed to be mediated through interaction with fibroblast growth factors (Folkman, J., Szabo, S., Strovroff, M., McNeil, P., Li, W. and Shing, Y. (1991) Ann. Surg. 214, 414-427). We show here that acidic fibroblast growth factor (aFGF; FGF-1) binds in vitro to both the soluble potassium salt and the insoluble aluminum salt of sucrose octasulfate, as demonstrated by a variety of biophysical techniques. Similar to the well-described interaction and stabilization of aFGF by heparin, soluble sucrose octasulfate (SOS) stabilizes aFGF against thermal, urea and acidic pH-induced unfolding as determined by a combination of circular dichroism, fluorescence spectroscopy and differential scanning calorimetry. In addition, SOS also enhances the mitogenic activity of aFGF and partially protects the protein's three cysteine residues from copper-catalyzed oxidation. SOS competes with heparin and suramin for the aFGF polyanion binding site as measured by both fluorescence and light scattering based competitive binding assays. Front-face fluorescence measurements show that the native, folded form of aFGF binds to the insoluble aluminum salt of sucrose octasulfate (sucralfate). Moreover, sucralfate stabilizes aFGF against thermal and acidic pH-induced unfolding to the same extent as observed with SOS. Thus, due to their high charge density, SOS and sucralfate bind and stabilize aFGF via interaction with the aFGF polyanion binding site.

Why does sucralfate improve healing in reflux esophagitis? The role of sucrose octasulfate

In the present investigation, one of sucralfate's major components, sucrose octasulfate (SOS), is shown in vitro to protect human esophageal epithelium against acid injury. This was done by mounting sections of human epithelia obtained at the time of esophagectomy in Ussing chambers and monitoring the change in electric resistance (R) on luminal acidification with 60 mM HCl. Mucosal-to-serosal mannitol fluxes were also performed before and after exposure to HCl. In untreated control tissues luminal acidification progressively reduced R with time and significantly increased tissue permeability to mannitol. In contrast, tissues exposed to 10 mg/ml SOS showed a minimal decrease in R and no significant change in permeability to mannitol (p less than 0.05 compared with control for both factors). Since SOS does not buffer luminal H+, protection by SOS is mediated by a direct action on the tissue. The impact of these results on sucralfate's reported ability to improve healing in reflux esophagitis is discussed.

A thin layer of sucrose octasulfate protects the oesophageal mucosal epithelium in reflux oesophagitis

Sucralfate is effective for the treatment of gastric and duodenal ulcers owing to its protective gel-forming ability. However, the mechanism by which sucralfate protects the oesophageal mucosa against reflux oesophagitis has not been clarified. We aimed to investigate the mechanisms of action of sucralfate and sucrose octasulfate (SOS), a component of sucralfate. SOS and sucralfate were administered to oesophagitis-induced rats, and the ulcer lesion size was macroscopically examined and scored. Effective pepsin activity in the gastric juices obtained from the animal model was evaluated by a casein digestion test. Sucralfate and SOS improved the pathology scores in a dose-dependent manner, whereas gastric juice pepsin activity was not impaired by therapeutic doses of SOS. As SOS lacks the ability to form a thick gel layer by polymerisation, we examined the distribution of SOS in the mucosal lumen by imaging mass spectrometry (IMS) to determine whether SOS directly adheres to the mucosal surface. A clear homogeneous thin-layer SOS film (>100 μm thick) was visualized on the oesophageal mucosal surface. Moreover, this SOS film formation was enhanced at ulcer lesion sites. Taken together, SOS appears to protect oesophageal mucosa against reflux oesophagitis via thin-layer formation on the mucosal surface.

Coadministration of basic fibroblast growth factor and sucrose octasulfate (sucralfate) facilitates the rat dorsal flap survival and viability

The effective use of local growth factors and cytokines may replace the lengthy staged surgical delay process. We tested the efficacy of basic fibroblast growth factor (bFGF) coadministered with sucralfate (sucrose octasulfate) on the rat dorsal flap model. A total of 76 male Wistar rats were used in this experiment. Four groups of the animals were divided. Group 1 (n = 5) was the vehicle control (saline soaked), group 2 (n = 5) was sucrose octasulfate soaked (100 microg/ml, 1 ml), group 3 (n = 5) was bFGF soaked (1 microg/ml, 1 ml), and group 4 (n = 5) was both bFGF and sucrose octasulfate soaked. All agents were soaked equally in Gelfoam. The flap survival measured by the quantitative computer-assisted morphologic analysis was significantly improved by day 5 postoperatively in the combined administration group compared with the vehicle control (81 and 53 percent, respectively; p < 0.05). In lead oxide-gelatin microangiography, there was enhanced pedicle vessel formation observed as well as the extended vessel sprouting up to very close to the distal end in combined group on day 5. The endogenous bFGF mRNA expressions shown by reverse transcriptase-polymerase chain reaction were detected in all four groups. The angiogenesis indicated by alpha-smooth muscle actin immunopositivity was significantly more enhanced in the combined group than the vehicle control (37.3 and 19.4, respectively; p < 0.01). In the combined group, there was stronger immunopositivity for bFGF in epidermis and hair follicles observed, and more notably bFGF-immunopositive dermal fibroblasts were evident. Thus, coadministration of bFGF and sucralfate markedly facilitates the rat dorsal flap survivability by enhancing the bFGF expression and angiogenesis.

Sucrose octasulfate stimulates gastric somatostatin release

To explore the mechanisms of the effects of sucralfate on the stomach, we investigated the action of sucrose octasulfate (SOS), a constituent of sucralfate, on the function of canine gastric parietal cells and somatostatin cells and in the isolated perfused intact rat stomach. Somatostatin cells from the canine gastric fundus were isolated by EDTA-collagenase dispersion and counterflow elutriation, and somatostatin-like immunoreactivity (SLI) release in response to SOS was measured by radioimmunoassay. Similar methods were used to isolate gastric parietal cells, in which gastric acid secretion was measured by uptake of a radiolabeled weak base, [14C]aminopyrine. SLI release by the intact rat stomach was examined in an isolated vascularly perfused rat stomach model. SOS, either alone or co-administered with epinephrine or gastrin heptadecapeptide (G17), dose-dependently stimulated SLI release by isolated canine fundic D-cells. At the highest doses, SOS potentiated the effect of epinephrine but not G17. Similarly, SOS potentiated the stimulating effect of dibutyryl cyclic adenosine 3',5'-monophosphate (DBcAMP), but not 12-O-tetradecanoylphorbol 13-acetate (TPA). The effect of SOS on SLI release could be inhibited by octreotide, a somatostatin analogue. SOS did not alter acid secretion by cultured canine parietal cells either in the basal state or when coadministered with acid secretagogues. In isolated perfused rat stomach studies, SOS produced a significant (60% greater than basal) increase in SLI secretion. There was a similar effect when SOS was perfused against a background of isoproterenol. SOS stimulates SLI release from gastric somatostatin cells and from the isolated perfused stomach but has no direct effect on gastric parietal cells. These actions of SOS may mediate in part the apparent ability of sucralfate to enhance gastric mucosal defense.