Influence of cell concentration,temperature, and press performance on flow characteristics and disintegration in the freeze-pressing of Saccharomyces cerevisiae with the X-press

The pressure required for initiation of flow when freeze-pressing with the X-press is related to the phase boundaries of water, particularly those between ice I and liquid even at temperatures around ?25°C and lower. Widening the orifice of the pressure chamber to diameters larger than 2.5 mm leads to lower pressures and less extensive cell disintegration. Pressing Saccharomyces cerevisiae slowly with the aid of a manual hydraulic jack at ?25°C produces a disintegration of 60–75% irrespective of cell concentration. Pressing at ?35°C shows no clear differences. Pressing more rapidly with the aid of a motor-driven hydraulic press produces a similar extent of disruption of diluted cell suspensions (5.4 mg/g) as slow pressing. However, freeze-pressing a paste of baker's yeast (270 mg/g) increases the degree of disintegration. Under these conditions the disintegration is further enhanced by a lower temperature, ?35°C, and by a high velocity of flow through the orifice, such that more than 95% of the S. cerevisiae is disrupted by one pressing at less than 2 × 10⁸ Pa. Mechanisms for flow through the X-press are suggested and discussed in relation to the phase diagram of water.     

Development of a high-throughput assay for the HIV-1 integrase disintegration reaction

Both HIV-1 integrase (IN) and the central catalytic domain of IN (IN-CCD) catalyze the disintegration reaction in vitro. In this study, IN and IN-CCD proteins were expressed and purified, and a high-throughput format enzyme-linked immunosorbent assay (ELISA) was developed for the disintegration reaction. IN exhibited a marked preference for Mn²⁺ over Mg²⁺ as the divalent cation cofactor in disintegration. Baicalein, a known IN inhibitor, was found to be an IN-CCD inhibitor. The assay is sensitive and specific for the study of disintegration reaction as well as for the in vitro identification of antiviral drugs targeting IN, especially targeting IN-CCD.     

Ribosomes from the blue-green alga Anabaena variabilis

Summary Extracts from the blue-green alga Anabaena variabilis were prepared by ultrasonic disintegration or by extrusion through a French pressure cell; examination by sucrose density gradient centrifugation and analytical ultracentrifugation indicated the existence of a procaryotic (70S) ribosome. However both the ribosomes and their sub-units were found to be relatively unstable after isolation and examination in tris buffer pH 7.4 but not in 10^-3 m-sodium phosphate buffer pH 7.0 containing 10^-1 m-potassium chloride. Experiments with ³²P and ³⁵S isotopes indicated that this instability was associated with the loss of ³⁵S labelled material, presumably therefore protein rather than nucleic acid. A comparison of behaviour with that of bacterial ribosomes is presented and the existence of certain similarities to ribosome preparations from chloroplasts of several plant species discussed.     

Comparative effects of different cellulosic-based directly compressed orodispersable tablets on oral bioavailability of famotidine

Famotidine is a potent H₂-receptor antagonist most commonly used by elderly patients. Orodispersible tablets (ODT) are gaining popularity over conventional tablets due to their convenience and suitability for patients having dysphagia. The purpose of this study is to prepare famotidine ODT using the economic direct-compression method.A 3² full factorial design was used to evaluate the influence of different excipients on the properties and in vitro dissolution of famotidine ODT. Two factors were studied for their qualitative effects, namely, disintegrants and diluents. Disintegrants were studied in three levels viz. Ac-Di-Sol, sodium starch glycolate (Primojel) and low-substituted hydroxypropyl cellulose (L-HPC). Fillers were studied in three levels viz. mannitol, spray dried lactose and Avicel PH 101. The ODTs were prepared by direct compression and were evaluated for hardness, drug content, uniformity of weight, in vitro disintegration time, oral disintegration time, wetting time and in vitro dissolution. Maximum dissolution and minimum oral disintegration time (11.4 s) were observed in F7 prepared using L-HPC and mannitol. Furthermore, in human volunteers it showed significant increase in bioavailability compared to Servipep^® with mean AUC_(0–∞) 117.1 ng/ml and 82.71 ng/ml, respectively, and its relative bioavailability was 141.57%. Hence, ODT (F7) could possibly be used to overcome the drawbacks of conventional famotidine tablets in elderly patients with significant increase in oral bioavailability.     

An extreme pressure pump for continuous cell disintegration

The use of an air operated extreme pressure hydraulic pump for continuous cell disintegration is described, together with figures obtained for soluble protein released from suspensions of commercially obtained baker's yeast (Saccharomyces cerevisiae).     

Fluorimetric quantification of intracellular lactate dehydrogenase during fermentation using flow injection analysis

A flow injection system for the on-line detection of the intracellular enzyme lactate dehydrogenase (LDH) during fermentation has been developed. The system is comprised of an on-line cell disintegration part, an immobilised dye based expanded bed column for the affinity capture of LDH and a fluorimetric detection unit. The system with a linearity of 0.1–5.4 U LDH ml^–1 was applied for the detection of intracellular accumulation of LDH during Lactococcus lactis subsp.lactis cultivation.     

Dermal cysts participate in reparative regeneration of epidermis in Hrhr/Hrhr mice

One of the phenotypic effects of mutation in the Hr gene in mice is disintegration of hair follicles and their degeneration into open funnel-shaped structures (utricles) opened on skin surface and cysts located in the depth of the dermis. The aim of the current study consists in analysis of the process of reparative regeneration of skin in homozygotous mice with one of the mutant alleles of the Hr gene—Hr ^hr . It is shown that epithelial cells that constitute the inner pavement of cysts take part in the process of epithelization of deep skin wounds. This indicates that the competence of ectodermal cells in relation to inductive signals from injured skin remains in Hr ^hr homozygote mice, in spite of the significant anatomic abnormalities of the hair follicles.     

Forecasting infections of the red rot disease on Porphyra yezoensis Ueda (Rhodophyta) cultivation farms

Pythium porphyrae is a fungal pathogen responsible for red rot disease of the seaweed Porphyra (Rhodophyta). Infection forecasts of Porphyra by P. porphyrae were estimated from the epidemiological observations of Porphyra thalli and numbers of zoospore of P. porphyrae in laboratory and cultivation areas. Four features of forecasting infections were determined by relating zoospore concentrations to the incidence of thallus infection; infection (in more than 1000 zoospores L⁻¹), microscopic infection [less than 2 mm in diameter of lesion (in from 2000 to 3000 zoospores L⁻¹)], macroscopic infection [more than 2 mm in diameter of lesion (in from 3000 to 4000 zoospores L⁻¹), and thallus disintegration (in more than 4000 zoospores L⁻¹). High zoospore concentrations led to more infection. The tendency that zoospore concentration of P. porphyrae increased with the rate of infection of Porphyra thalli was generally observed in forecasting infections in both the laboratory and in cultivation areas. Based on the Porphyra cultivation areas, the accuracy and consistency of forecasting infections suggest that this method could be employed to manage and control red rot disease.     

Effects of plantain and corn starches on the mechanical and disintegration properties of paracetamol tablets

The effects of plantain starch obtained from the unripe fruit of the plantMusa paradisiaca L. (Musaceae) on the mechanical and disintegration properties of paracetamol tablets have been investigated in comparison with the effects of corn starch BP using a 2³ factorial experimental design. The individual and combined effects of nature of starch binder (N), concentration of starch binder (C), and the relative density of tablet (RD) on the tensile strength (TS), brittle fracture index (BFI), and disintegration time (DT) of the tablets were investigated. The ranking of the individual effects on TS was RD>C≫N, on BFI was C≫RD>N and on DT was N>C>RD. The ranking for the interaction effects on TS and DT was N-C≫N-RD>C-RD, while that on BFI was N-C≫C-RD>N-RD. Changing nature of starch from a “low” (plantain starch) to a “high” (corn starch) level, increasing the concentration of starch binding agent from 2.5% to 10.0% wt/wt, and increasing relative density of the tablet from 0.80 to 0.90, led to increase in the values of TS and DT, but a decrease in BFI. Thus, tablets containing plantain starch had lower tensile strength and disintegration time values than those containing corn starch, but showed better ability to reduce the lamination and capping tendency in paracetamol tablet formulation. The interaction between N and C was significantly (P<.001) higher than those between N and RD and between C and RD. There is therefore the need to carefully choose the nature (N) and concentration (C) of starch used as binding agent in tablet formulations to obtain tablets of desired bond strength and disintegration properties. Furthermore, plantain starch could be useful as an alternative binding agent to cornstarch, especially where faster disintegration is required and the problems of lamination and capping are of particular concern. Published: October 22, 2005     

A critical comparison of the pressure-probe and pressure-chamber techniques for estimating leaf-ceil turgor pressure in Kalanchoë daigremontiana

The aim of the present study was to test the accuracy of the pressure-chamber technique as a method for estimating leaf-cell turgor pressures. To this end, pressure-probe measurements of cell turgor pressure (P^cell) were made on mesophyll cells of intact, attached leaves of Kalanchoë daigremontiana. Immediately following these measurements, leaves were excised and placed in a pressure chamber for the determination of balance pressure (P^bal). Cell-sap osmotic pressure (?^cell) and xylem-sap osmotic pressure (?^xyl) were also measured, and an average cell turgor pressure calculated as P^cell=?^cell–?^xyl–P^bal. The apparent value of P^bal was positively correlated with the rate of increase of chamber pressure, and there was also a time-dependent increase associated with water loss. On expressing sap from the xylem, ?^xyl fell to a plateau value that was positively correlated with ?^cell. Correcting for these effects yielded estimates of P^bal and ?^xyl at the time of leaf excision. On average, the values of P^cell obtained with the two techniques agreed to within ±002 MPa (errors are approximate 95% confidence limits). If ?^xyl were ignored, however, the calculated turgor pressures would exceed the measured values by an average of 0.074 ± 0.012MPa, or 48% at the mean measured pressure of 0.155 MPa. We conclude that the pressure-chamber technique allows a good estimate to be made of turgor pressure in mesophyll cells of K. daigremontiana, provided that ?^xyl is included in the determination. The 1:1 relationship between the measured and calculated turgor pressures also implies that the weighted-average reflection coefficient for the mesophyll cell membranes is close to unity.     

Effect of a Pulsed Electric Field Treatment on Expression Behavior and Juice Quality of Chardonnay Grape

This work discusses the effects of pulsed electric field (PEF) application on low-pressure mechanical expression (the pressure maximum was 1 bar) and characteristics of juice produced from Chardonnay white grape. The experiments were carried out using a texture analyzer equipped with a PEF-treatment compression chamber operated at moderate electric field strength E = 400 V/cm. Two regimes of extraction were compared: expression at constant pressure (0.5 or 1 bar) and expression at progressive pressure increase (from 0 to 1 bar). This last one was chosen for the scale-down modeling of industrial grape pressing process. It was shown that PEF treatment at the electric field E = 400 V/cm and the total time of treatment t _PEF ≈ 0.1 s allowed reaching of a high level of cell disintegration, Z ≈ 0.8. The energy consumption of PEF treatment corresponding to this level of disintegration was rather low and equal to W ≈ 15 kJ/kg. The PEF pretreatment resulted in juice yield increase from 67% to 75% (1 h of pressing at constant pressure of 1.0 bar). PEF treatment accelerated development of grape deformation. Decrease of difference between deformations of untreated and PEF-treated samples at high pressure and long-pressing time was observed. Statistical analysis showed no significant effect of PEF treatment on turbidity and content of polyphenols for the constant pressure regime. However, PEF treatment application resulted in elevation of the content of polyphenols (more than 15%) for the progressive pressure-increase regime.     

Carbofuran- and cypermethrin-induced histopathological alterations in the liver of Labeo rohita (Hamilton) and its recovery

Alterations in the liver histology of Labeo rohita were examined after exposure to different concentrations of carbofuran (0.06 and 0.15 mg L^?1) and cypermethrin (0.16 and 0.40 μl L^?1) for 28 days. Histological recovery was also studied by maintaining the intoxicated fish in a freshwater system for an additional 28 days. Major damages caused by carbofuran toxicity were diffuse necrosis, cordal disarrangement, individualization of hepatocytes, etc.; significant changes induced by cypermethrin were hyperplasia, disintegration of hepatic mass, focal coagulative necrosis, etc. In both cases, damages were dose‐dependent, with cypermethrin exhibiting more sensitivity than carbofuran. In all cases, recovery was prominent and rate of recovery was faster with carbofuran than when using cypermethrin.     

Comparative study of fungal cell disruption—scope and limitations of the methods

Simple and effective protocols of cell wall disruption were elaborated for tested fungal strains: Penicillium citrinum, Aspergillus fumigatus, Rhodotorula gracilis. Several techniques of cell wall disintegration were studied, including ultrasound disintegration, homogenization in bead mill, application of chemicals of various types, and osmotic shock. The release of proteins from fungal cells and the activity of a cytosolic enzyme, glucose-6-phosphate dehydrogenase, in the crude extracts were assayed to determine and compare the efficacy of each method. The presented studies allowed adjusting the particular method to a particular strain. The mechanical methods of disintegration appeared to be the most effective for the disintegration of yeast, R. gracilis, and filamentous fungi, A. fumigatus and P. citrinum. Ultrasonication and bead milling led to obtaining fungal cell-free extracts containing high concentrations of soluble proteins and active glucose-6-phosphate dehydrogenase systems.     

Pressure adaptation of teleost gill Na+/K+-adenosine triphosphatase: role of the lipid and protein moieties

Summary The effects of temperature and pressure on Na⁺/K⁺-adenosine triphosphatases (Na⁺/K⁺-ATPases) from gills of marine teleost fishes were examined over a range of temperatures (10–25°C) and pressures (1–680 atm). The relationship between gill membrane fluidity and Na⁺/K⁺-ATPase activity was studied using the fluorescent probe 1,6-diphenyl-1,3,5-hexatriene (DPH). The increase in temperature required to offset the membrane ordering effects of high pressure was 0.015–0.025°C·atm^-1, the same coefficient that applied to Na⁺/K⁺-ATPase activities. Thus, temperature-pressure combinations yielding the same Na⁺/K⁺-ATPase activity also gave similar estimates of membrane fluidity. Substituion of endogenous lipids with lipids of different composition altered the pressure responses of Na⁺/K⁺-ATPase. Na⁺/K⁺-adenosine triphosphatase became more sensitive to pressure in the presence of chicken egg phosphatidylcholine, but phospholipids isolated from fish gills reduced the inhibition by pressure of Na⁺/K⁺-ATPase. Cholesterol increased enzyme pressure sensitivity. Membrane fluidity and pressure sensitivity of Na⁺/K⁺-ATPase were correlated, but the effects of pressure also dependent on the source of the enzyme. Our results suggest that pressure adaptation of Na⁺/K⁺-ATPase is the result of both changes in the primary structure of the protein and homeoviscous adaptation of the lipid environment.Abbreviations EDTA; DPH 1,6-diphenyl-1,3,5-hexatriene - PC phosphatidylcholine - PL phospholipid - SDH succinate dehydrogenase     

Biological Control of Phytophthora Root Rot of Pepper Using Trichoderma harzianum and Streptomyces rochei in Combination

A combination of two compatible micro‐organisms, Trichoderma harzianum and Streptomyces rochei, both antagonistic to the pathogen Phytophthora capsici, was used to control root rot in pepper. The population of the pathogen in soil was reduced by 75% as a result. Vegetative growth of the mycelium of P. capsici was inhibited in vitro on the second day after P. capsici and T. harzianum were placed on the opposite sides of the same Petri plate. Trichoderma harzianum was capable of not only arresting the spread of the pathogen from a distance, but also after invading the whole surface of the pathogen colony, sporulating over it. Scanning electron microscopy showed the hyphae of P. capsici surrounded by those of T. harzianum, their subsequent disintegration, and the eventual suppression of the pathogen's growth. Streptomyces rochei produced a zone of inhibition, from which was obtained a compound with antioomycete property secreted by the bacteria. When purified by high‐pressure liquid chromatography, this compound was identified as 1‐propanone, 1‐(4‐chlorophenyl), which seems to be one of the principal compounds involved in the antagonism. A formulation was prepared that maintained the compound's capacity to inhibit growth of the pathogen for up to 2 years when stored at room temperature in the laboratory on a mixture of plantation soil and vermiculite. The two antagonists, added as a compound formulation, were effective at pH from 3.5 to 5.6 at 23–30°C. The optimal dose of the antagonists in the compound formulation was 3.5 × 10⁸ spores/ml of T. harzianum and 1.0 × 10⁹ FCU/ml of S. rochei. This is the first report of a compound biocontrol formulation of these two antagonists with a potential to control root rot caused by P. capsici.     

Hyphal and mycelial interactions betweenAgaricus bisporus andScytalidium thermophilum on agar media

The interaction betweenAgaricus bisporus andScytalidium thermophilum on agar media was studied by differential interference contrast and phase contrast microscopy.A. bisporus combatively replacesS. thermophilum in culture on agar media. The antagonistic effect ofA. bisporus is transmissible through a cellophane membrane and causes irreversible disintegration ofS. thermophilum protoplasm, resulting in a total loss of viability after prolonged interaction between the two fungi. On compost extract agar, but not on other media, the growth rate ofA. bisporus increased from 2.7 to 5.3 mm·d^–1 following contact withS. thermophilum mycelium.     

Optimization Studies on Design and Evaluation of Orodispersible Pediatric Formulation of Indomethacin

In the present study, the aim was to optimize an orodispersible formulation of indomethacin using a combined approach of subliming agent and superdisintegrant. The tablets were made by non-aqueous wet granulation technique with superdisintegrant incorporated both intragranularly and extragranularly. A 2³ factorial design was used to investigate the effects amount of subliming agents namely camphor and ammonium bicarbonate and taste masking and soothening hydrophilic agent mannitol as independent variables and disintegration time and crushing strength as dependent responses. The volatilization time of eight hours at 50°C was optimized by conducting solid-state kinetic studies of optimized formulations. Optimized orodispersible tablets were evaluated for wetting time, water absorption ratio, porosity and in vitro and in vivo disintegration tests. Results show that higher levels of camphor and mannitol and a lower level of ammonium bicarbonate is desirable for orodispersion. Scanning electron microscopy (SEM) revealed the porous surface morphology and kinetic digital images substantiated the orodispersible property. Differential Scanning Calorimetry (DSC) studies exhibited physiochemical compatibility between indomethacin and various excipients used in the tablet formulation. Stability studies carried out as per ICH Q₁ A guidelines suggested the stable formulations for the tested time period of 6 months. The systematic approach of using subliming and disintegrating agents helped in achieving a stable, optimized orodispersible formulation, which could be industrially viable.     

Comparison of molecular properties of rat plasma and erythrocyte selenium-dependent glutathion peroxidase

The molecular structure of plasma and erythrocyte selenium-dependent glutatione peroxidase (GSH-Px) was studied in rats drinking water containing [⁷⁵Se]selenious acid, 1.3 mg Se/L. Substantial differences were found using three-step fractionation, including gel filtration of crude plasma and erythrocyte lysate, gel filtration of⁷⁵Se-GSH-Px treated by mercaptoethanol, and SDS-electrophoresis. Native plasma⁷⁵Se-GSH-Px, which exhibited a molecular weight (M _r) of approx 700,000, could be destroyed by mercaptoethanol action, resulting in disintegration of enzyme into several different⁷⁵Se-protein fragments and release of part of low-mol-wt⁷⁵Se. Native erythrocyte⁷⁵Se-GSH-PxM _r, value was found to be 113,000; two⁷⁵Se-protein fragments arose after mercaptoethanol treatment without⁷⁵Se release from the enzyme. The⁷⁵Se-subunits of 22,500 and 21,900 were isolated from plasma and erythrocyte⁷⁵Se-GSH-Px, respectively. Another minor⁷⁵Se-GSH-Px was identified in erythrocyte lysate (M _r, 214,000, subunit 22,100), which was considered to be a dimer of the above-mentioned erythrocyte enzyme. It can be assumed, based on these data, that native plasma GSH-Px, in contrast to erythrocyte enzyme, represents a high-molecular wt complex composed of several tetramers linked with S—S bonds. A certain part of selenium present in this complex is probably not selenocysteine and may be released with the mercaptoethanol treatment.     

The diurnal pattern of protein and photopigment synthesis in the retina of the crayfish,Procambarus clarkii

Summary The interrelationship between the diurnal cycle of membrane loss and synthesis of new rhabdom components remains a key element in forming a complete picture of the turnover of photopigment-containing membrane in the crayfish photoreceptor cell. In order to examine this aspect of the turnover process, the diurnal pattern of photopigment synthesis was examined using an in vitro incubation system for incorporation of³H-leucine into photoreceptor protein. The incorporation of³H-leucine into total protein and photopigment specifically was measured in photoreceptors isolated from incubated retinas. The results indicate that for both total protein and photopigment there is no significant variation in the rate of synthesis during the 12-12 light-dark cycle. These data combined with earlier data on diurnal membrane loss from the rhabdom suggest that light-stimulated rhabdom membrane loss is superimposed on a diurnally constant level of synthesis and assembly of new rhabdom constituents.Abbreviations dpm disintegration per minute - LRB lysosome related body - TCA trichloroacetic acid     

Turgor pressure changes trigger characteristic changes in the electrical conductance of the tonoplast and the plasmalemma of the marine alga Valonia utricularis

The giant marine alga Valonia utricularis is capable of regulating its turgor pressure in response to changes in the osmotic pressure of the sea water. The turgor pressure response comprises two phases, a fast, exponential phase arising exclusively from water shifting between the vacuole and the external medium (time constant about 10 min) and a second very slow, almost exponential phase adjusting (but not always) the turgor pressure near to the original value by release or uptake of KCl (time constant about 5 h). The changes in the vacuolar membrane potential as well as in the individual conductances of the tonoplast and plasmalemma accompanying turgor pressure regulation were measured by using the vacuolar perfusion assembly (with integrated microelectrodes, pressure transducers and pressure‐regulating valves) as described by Wang et al. (J. Membrane Biology 157, 311–321, 1997). Measurements on pressure‐clamped cells gave strong evidence that the turgor pressure, but not effects related to water flow (i.e. electro‐osmosis or streaming potential) or changes in the internal osmotic pressure and in the osmotic gradients, triggers the cascade of osmotic and electrical events recorded after disturbance of the osmotic equilibrium. The findings definitely exclude the existence of osmosensors as postulated for other plant cells and bacteria. There was also evidence that turgor pressure signals were primarily sensed by ion transporters in the vacuolar membrane because conductance changes were first recorded in the many‐folded tonoplast and then significantly delayed in the plasmalemma independent of the direction of the osmotic challenge. Consistently, turgor pressure up‐regulation (but not down‐regulation) could be inhibited reversibly by external addition of the K⁺ transport inhibitor Ba²⁺ and/or by the Cl^– transport inhibitor 4,4′‐diisothiocyanatostilbene‐2,2′‐disulfonic acid (DIDS). Extensive studies under iso‐, hyper‐ and hypo‐osmotic conditions revealed that K⁺ and Cl^– contribute predominantly to the plasmalemma conductance. Addition of 0.3 mm NaCN showed further that part of the K⁺ and Cl^– transporters depended on ATP. These transporters are apparently up‐regulated upon hyper‐osmotic, but not hypo‐osmotic challenge. These findings explain the strong increase of the K⁺ influx upon lowering turgor pressure and the less pronounced pressure‐dependence of the Cl^– influx of V. utricularis reported in the literature. The data derived from the blockage experiments under hypo‐osmotic conditions were also equally consistent with the experimental findings that the K⁺ efflux is solely passive and progressively increases with increasing turgor pressure due to an increase of the volumetric elastic modulus of the cell wall. However, despite unravelling some of the sequences and other components involved in turgor pressure regulation of V. utricularis the co‐ordination between the ion transporters in the tonoplast and plasmalemma remains unresolved because of the failure to block the tonoplast transporters by addition of Ba²⁺ and DIDS from the vacuolar side.