Powder compaction properties of sodium starch glycolate disintegrants.

The compaction behavior of three "as supplied" commercially available grades of sodium starch glycolate (SSG), Explotab, Primojel, and Vivastar P, was investigated at compression speeds of 0.17 and 30 mm/sec. The results suggested that the three "as supplied" materials exhibit different compression and compaction behavior. Primojel and Explotab exhibited similar compactibility, whereas Vivastar P produced compacts of poor integrity. This behavior was not mirrored in the compressibility of the powders, where Vivastar P and Explotab exhibited similar performance. The materials were studied using x-ray diffraction, scanning electron microscopy, Carr's compressibility index, and swelling volume. In terms of material characteristics, all the products exhibited similar swelling in water. Primojel and Explotab retained most of the crystallographic order from the parent potato starch and exhibited comparable particle surface topographies. Vivastar P contained the lowest moisture level. However, it is not clear if the poor compactibility of Vivastar P is due to differences in moisture content, the reduced surface topography, or subtle differences in the SSG polymer structures (substitution, cross-linking, and crystallinity). Overall, even though the three commercial grades of sodium starch glycolate are successfully used as disintegrants, they do exhibit differences in their "as supplied" powder mechanical properties: Primojel and Explotab exhibit similar compactibility, whereas Vivastar P is poorly compactable but exhibits similar compressibility to Explotab. These observations may have implications when formulating poorly compactable or moisture-sensitive drugs.

Interaction of some polyhexamethylene biguanides and membrane phospholipids in Escherichia coli.

The interaction between some polyhexamethylene biguanides and the cell envelope of Escherichia coli has been investigated. An amine-ended dimer, (AED, n = 2), a polydisperse mixture (ICI plc) available as the active ingredient of Vantocil IB, (PHMB, n = 5.5), and a high molecular weight fraction, (HMW, n = greater than or equal to 10) of PHMB were used. The sensitivity of batch cultures depleted of magnesium (M-dep), phosphorus (P-dep) or glycerol (C-dep) towards the biocides was assessed by monitoring the rate and extent of potassium ion leakage. P-dep suspensions were particularly resistant to all these agents and possessed less than half the quantity of phospholipid of other cell types. This was compensated for by a proportionate increase in fatty acid and neutral lipid content of the cells. The reduction in phospholipid content was accounted for by decreases in phosphatidylglycerol (PG) and phosphatidylethanolamine (PE). Diphosphatidylglycerol (DPG) and phosphatidylserine (PS) content of the cultures remained unaffected by the depleting nutrient. Fourier-transform n.m.r. spectroscopy was used to study proton nuclei during the interaction of HMW, AED and PHMB with various phospholipid-vesicle preparations. The results strongly suggest that the biocides acted preferentially on the acidic phospholipids PG and DPG, rather than towards PE or PS. Resistance of P-dep cultures therefore reflected reductions in PG content. A molecular basis for the interaction of these compounds and membranes is proposed.

Binding of some polyhexamethylene biguanides to the cell envelope of Escherichia coli ATCC 8739.

Absorption and antibacterial action of some polyhexamethylene biguanides upon Escherichia coli has been investigated. An amine-ended-dimer (AED) (n = 2), a polydisperse mixture sold by ICI Limited as the active ingredient of vantocil IB (PHMB) (n = 5.5), and a high molecular weight fraction of PHMB (HMW, n greater than or equal to 10) were used. Bactericidal activity was determined over a range of pH (5-9). Similarly, adsorption of drug to the cell surface, indicated by changes in electrophoretic mobility, and overall drug absorption by the cells were determined. Maximal activity occurred at pH 6 for PHMB and HMW and at pH 5 for AED. This corresponded to minimal surface adsorption and maximal distribution of drug to the underlying cytoplasm and cytoplasmic membrane. Uptake of drug corresponded to high affinity isotherms and indicated a rapid transfer of biocide into the cells following their initial interaction at the surface.

Injury and recovery of Escherichia coli ATCC 8739 from treatment with some polyhexamethylene biguanides.

The action of some polyhexamethylene biguanides upon Escherichia coli has been investigated. An amine-ended-dimer (n = 2), a polydisperse mixture (n = 5.5) and a high molecular weight fraction (n greater than 10) of the compounds were employed. The three compounds caused damage and disruption of the cell envelope indicated by changes in permeability towards the dye 2-p-toluidinylnaphthylene-6-sulphonate. This damage was shown to be reversible below certain critical concentrations of the biocides. Prolongation of treatment time did not increase the extent of non-recoverable injury nor influence those critical concentrations of biocide initiating it. Recovery processes were rapid and complete within 1 min. The inclusion of an inhibitor of respiration, antimycin A, in the recovery medium did not reduce the rate of recovery by damaged cells.