Treatment with lithium salts reduces ethanol dehydration shrinkage of glutaraldehyde fixed tissue

Changes in the area of glutaraldehyde fixed 15 day p.c. mouse embryo limbs were recorded using a Quantimet 720 image analysing computer attached to a light microscope: during a period of treatment with an isotonic salt solution (mostly halides of the alkali or alkaline earth metals); a subsequent wash with distilled water; and dehydration through a 30, 50, 70, 80, 90, and 100% ethanol series. Pretreatment with NaCl, KCl, RbCl had no significant effect. Treatment with LiCl, LiNO3, LiF (0.03 M), CsF and CsCl caused an increase (relative to Na, K or Rb treated samples) in the specimen volume during dehydration, which persisted in 100% ethanol. Li treated samples showed the largest post-critical-point-drying (CPD) volumes, followed by Cs treated tissue. Pretreatment with Be, Mg, Ca, Sr and Ba chlorides caused shrinkage and the 100% ethanol and post-CPD volumes of these samples were all lower than those treated with the monovalent cation containing salts.     

Disappearance of the Cartilage Interlacunar Network During Histological Dehydration

The interlacunar network connects adjacent chondrocytes in rapidly growing cartilage and with anionic dyes stains more intensely than the surrounding matrix. The network is seen in fresh-frozen sections and sections treated with a variety of fixatives, dehydration agents and embedding media. The network is not seen after using such common dehydrating fluids as ethanol and acetone. Polyanionic glycosaminoglycans (GAG) are abundant in the cartilage matrix and it has been suggested that the network is an artifact caused by a rearrangement of the matrix GAG during histological processing. Extraction of GAG from neonatal rat cartilage with guanidine hydrochloride removes stainable extracellular matrix but not the interlacunar network. However, after extraction of GAG and immersion of the cartilage in either 50% or 100% aqueous ethanol or acetone, the network was no longer visible. The network apparently is not an artifact formed by soluble matrix GAG, but a real structure which is extracted, collapsed or otherwise destroyed during dehydration in ethanol or acetone.     

Dehydration reduces left ventricular filling at rest and during exercise independent of twist mechanics

The purpose of this study was to determine whether the reduction in stroke volume (SV), previously shown to occur with dehydration and increases in internal body temperatures during prolonged exercise, is caused by a reduction in left ventricular (LV) function, as indicated by LV volumes, strain, and twist ("LV mechanics"). Eight healthy men [age: 20 ± 2, maximal oxygen uptake (VO?max): 58 ± 7 ml·kg?1·min?1] completed two, 1-h bouts of cycling in the heat (35°C, 50% peak power) without fluid replacement, resulting in 2% and 3.5% dehydration, respectively. Conventional and two-dimensional speckle-tracking echocardiography was used to determine LV volumes, strain, and twist at rest and during one-legged knee-extensor exercise at baseline, both levels of dehydration, and following rehydration. Progressive dehydration caused a significant reduction in end-diastolic volume (EDV) and SV at rest and during one-legged knee-extensor exercise (rest: Δ-33 ± 14 and Δ-21 ± 14 ml, respectively; exercise: Δ-30 ± 10 and Δ-22 ± 9 ml, respectively, during 3.5% dehydration). In contrast to the marked decline in EDV and SV, systolic and diastolic LV mechanics were either maintained or even enhanced with dehydration at rest and during knee-extensor exercise. We conclude that dehydration-induced reductions in SV at rest and during exercise are the result of reduced LV filling, as reflected by the decline in EDV. The concomitant maintenance of LV mechanics suggests that the decrease in LV filling, and consequently ejection, is likely caused by the reduction in blood volume and/or diminished filling time rather than impaired LV function.     

Optimization of immunogold labeling TEM. An ELISA-based method for rapid and convenient simulation of processing conditions for quantitative detection of antigen.

We developed an ELISA-based method for rapid optimization of various tissue processing parameters in immunogold labeling for electron microscopy. The effects of aldehyde fixation, tannic acid, postfixation, dehydration, temperature, and antigen retrieval on antibody binding activity of Vitreoscilla hemoglobin (VHb) expressed in E. coli cells were assayed by ELISA and the results confirmed by quantitative immunogold labeling transmission electron microscopy (TEM). Our results demonstrated that low concentrations (0.2%) of glutaraldehyde fixation caused minimal loss in total binding compared to higher concentrations. Dehydration in up to 70% ethanol resulted in some distortion of cellular ultrastructure but better antibody binding activity compared to dehydration up to 100%. Postfixation or incorporation of tannic acid in the primary fixative caused almost total loss of activity, whereas antigen retrieval of osmium-postfixed material resulted in approximately 90-100% recovery. The sensitivity of detection of proteins by immunogold labeling electron microscopy depends on the retention of antibody binding activity during tissue processing steps, e.g., fixation and dehydration. Our study indicated that an ELISA-based screening method of various tissue processing procedures could help in rapid selection and optimization of a suitable protocol for immunogold localization and quantification of antigen by TEM.     

Microwave processing for scanning electron microscopy

The normal processing of biological samples for Scanning Electron Microscopy, includes treatment with aldehyde (1 to 2 hours), postfixation with Osmium (1 hour), followed by dehydration in a ascending grade of ethanol (30 a 100%), 10 to 15 minutes in each step, and finally drying. This procedure takes at least 8 hours. In this work, samples of mosquitoes (Aedes), protozoa (Tritrichomonas muris), bacteria (Clostridium oceanicum), murine liver, and small intestine were processed in the same manner in a domestic microwave oven for two minutes at 20% of its maximum power. The complete procedure from the initial fixation to dehydration in 100% ethanol was reduced to one hour with good preservation of the ultrastructural details of the specimens.     

Effect of cadmium on ethanol induced sleeping time in mice

The effect of cadmium on sleeping time induced by ethanol was studied in mice. When 0.25, 2.5 or 5.0 mg/kg of CdCl₂ was injected intraperitoneally (i.p.), the ethanol induced sleeping time was enhanced by 50 %, 100 % or 150 % from that of saline treated mice. The enhancement of ethanol induced sleeping time by cadmium was completely blocked by intracerebroventricular (i.vt.) pretreatment with CDTA, an agent that chelates cadmium ion. This indicates that the ethanol induced sleeping time was enhanced by a part of cadmium which passed through blood brain barrier after the i.p. injection.On the other hand, the ethanol induced sleeping time was also increased by 50 % with i.vt. injection of L-serotonin but not altered with L-dopamine or L-norepinephrine. In addition to this, i.vt. injection of L-serotonin plus L-norepinephrine enhanced by 170 % the ethanol induced sleeping time. Furthermore, the enhancement of ethanol induced sleeping time by cadmium was potentiated by i.vt. treatment of L-serotonin or L-norepinephrine but not by L-dopamine. These results suggest that the enhancement of ethanol induced sleeping time by cadmium may be caused by an increase in L-serotonin levels or both L-serotonin and L-norepinephrine levels but not by L-dopamine levels in brain of mouse.     

Inactivation of Viable Ascaris Eggs by Reagents during Enumeration

Various reagents commonly used to enumerate viable helminth eggs from wastewater and sludge were evaluated for their potential to inactivate Ascaris eggs under typical laboratory conditions. Two methods were used to enumerate indigenous Ascaris eggs from sludge samples. All steps in the methods were the same except that in method I a phase extraction step with acid-alcohol (35% ethanol in 0.1 N H₂SO₄) and diethyl ether was used whereas in method II the extraction step was avoided by pouring the sample through a 38-μm-mesh stainless steel sieve that retained the eggs. The concentration of eggs and their viability were lower in the samples processed by method I than in the samples processed by method II by an average of 48 and 70%, respectively. A second set of experiments was performed using pure solutions of Ascaris suum eggs to elucidate the effect of the individual reagents and relevant combination of reagents on the eggs. The percentages of viable eggs in samples treated with acid-alcohol alone and in combination with diethyl ether or ethyl acetate were 52, 27, and 4%, respectively, whereas in the rest of the samples the viability was about 80%. Neither the acid nor the diethyl ether alone caused any decrease in egg viability. Thus, the observed inactivation was attributed primarily to the 35% ethanol content of the acid-alcohol solution. Inactivation of the eggs was prevented by limiting the direct exposure to the extraction reagents to 30 min and diluting the residual concentration of acid-alcohol in the sample by a factor of 100 before incubation. Also, the viability of the eggs was maintained if the acid-alcohol solution was replaced with an acetoacetic buffer. None of the reagents used for the flotation step of the sample cleaning procedure (ZnSO₄, MgSO₄, and NaCl) or during incubation (0.1 N H₂SO₄ and 0.5% formalin) inactivated the Ascaris eggs under the conditions studied.     

Selective dehydration of bio-ethanol to ethylene catalyzed by lanthanum-phosphorous-modified HZSM-5: influence of the fusel

Bio-ethanol dehydration to ethylene is an attractive alternative to oil-based ethylene. The influence of fusel, main byproducts in the fermentation process of bio-ethanol production, on the bio-ethanol dehydration should not be ignored. We studied the catalytic dehydration of bio-ethanol to ethylene over parent and modified HZSM-5 at 250°C, with weight hourly space velocity (WHSV) equal to 2.0/h. The influences of a series of fusel, such as isopropanol, isobutanol and isopentanol, on the ethanol dehydration over the catalysts were investigated. The 0.5%La-2%PHZSM-5 catalyst exhibited higher ethanol conversion (100%), ethylene selectivity (99%), and especially enhanced stability (more than 70 h) than the parent and other modified HZSM-5. We demonstrated that the introduction of lanthanum and phosphorous to HZSM-5 could weaken the negative influence of fusel on the formation of ethylene. The physicochemical properties of the catalysts were characterized by ammonia temperature-programmed desorption (NH(3)-TPD), nitrogen adsorption and thermogravimetry (TG)/differential thermogravimetry (DTG)/differential thermal analysis (DTA) (TG/DTG/DTA) techniques. The results indicated that the introduction of lanthanum and phosphorous to HZSM-5 could inhibit the formation of coking during the ethanol dehydration to ethylene in the presence of fusel. The development of an efficient catalyst is one of the key technologies for the industrialization of bio-ethylene.     

Purification of heparin,dermatan sulfate and chondroitin sulfate from mixtures by sequential precipitation with various organic solvents

Heparin, dermatan sulfate and chondroitin sulfate in mixtures were fractionated by sequential precipitation with methanol, ethanol and propanol. The recovered fractions from 0.1 to 2.0 volumes of various solvents were analyzed by agarose-gel electrophoresis and densitometric analysis. Heparins with different relative percentages of slow-moving and fast-moving components were precipitated from 0.5 to 0.7 volumes of methanol, and in this range of volumes, the amount of slow-moving component of heparin decreases and that of the fast-moving species increases. From 0.8 to 1.6 volumes of methanol, mixtures with different percentages of the fast-moving component, dermatan sulfate and chondroitin sulfate are precipitated. Heparin was precipitated from mixtures in the range of 0.1 to 0.4 volumes of ethanol, and from 0.5 to 0.8 volumes mixtures with different relative percentages of dermatan sulfate and chondroitin sulfate were precipitated. From 1.0 to 2.0 volumes of ethanol, high purity (about 100%) chondroitin sulfate can be precipitated. Propanol induces the precipitation of heparin from 0.3 to 0.4 volumes, whilst dermatan sulfate with a purity greater than 85% is precipitated at 0.5 and 0.6 volumes of propanol. 100% chondroitin sulfate is obtained with volumes greater than 0.8. Heparin and chondroitin sulfate from a bovine lung extract of glycosaminoglycans were purified by sequential precipitation with ethanol. The fraction precipitated with 0.4 volumes of ethanol shows greater than 90% heparin and that recovered from 0.9 to 2.0 volumes is composed of 100% chondroitin sulfate.     

Synergistic effect ofSacoglottis gabonensis bark extract,

Aflatoxin B₁ metabolism was studied using microsomal and cytosolic fractions isolated from weanling male Fischer F344 rats given in drinking water for 7 days an aqueous extract ofSacoglottis gabonensis bark, 0.1% ethanol solution, or a solution containing both extract and ethanolad libitum. Microsomal production of aflatoxin B₁-dihydrodiol, aflatoxin Q₁, aflatoxin M₁, aflatoxin Pi and proteinaflatoxin adduct formation, and cytosolic aflatoxin B₁-glutathione conjugation were assayed. Pretreatment with the extract alone or together with ethanol caused significant increases in aflatoxin M₁ production as compared to controls given only water, but aflatoxin Q₁ production was enhanced only by pretreatment with both extract and ethanol. All the three treatments caused significant reductions in liver glutathione content. The highest aflatoxin B₁ metabolising activity as determined by aflatoxin M₁ and aflatoxin Q₁ production was observed in rats pretreated with both ethanol and the extract, suggesting synergism. The findings suggest that at relatively mild doses,S. gabonensis extract alone or in concert with ethanol may influence response to aflatoxin.     

Antioxidant effect of a phytoestrogen equol on cultured muscle cells of embryonic broilers

Previous studies have shown that the in ovo injection of equol can markedly improve the water-holding capacity of muscles of broilers chickens at 7 wk of age through promotion of the antioxidant status. We aimed to investigate directly the antioxidant effects of equol on muscle cells in broilers. Muscle cells were separated from leg muscle of embryos on the 11th day of incubation and treated with equol and H₂O₂, either alone or together. Cells were pretreated with medium containing 1, 10, or 100 μM equol for 1 h prior to the addition of 1 mM H₂O₂ for a further 1 h. Photomicrographs of cells were obtained. Cell viability, malondialdehyde (MDA) content, and L-lactate dehydrogenase (LDH) activity in the cell supernatant, as well as intracellular total superoxide dismutase (T-SOD) and glutathione peroxidase (GSH-Px) activities were determined. Treatment with 1 mM H₂O₂ caused serious damage to cells, indicated by comets with no clear head region but a very apparent tail of DNA fragments. Pretreatment with low (1 μM) but not high concentrations of equol (10 μM) inhibited cell damage, while 100 μM equol caused more serious damage than H₂O₂ alone. Pretreatment with 1 μM equol had no effect on cell viability, while pretreatment with 10 and 100 μM equol significantly decreased cell viability in a dose-dependent manner. Compared with H₂O₂ alone, pretreatment with low-dosage equol markedly decreased LDH activity and MDA production in the supernatant, significantly increased intracellular T-SOD activity (P < 0.05) and tended to increase intracellular GSH-Px activity (0.05 < P < 0.1). Pretreatment with high-dosage equol (10 and 100 μM) significantly enhanced LDH activity, but had no effect on MDA content, T-SOD or GSH-Px activity induced by H₂O_2, except for an obvious increase in GSH-Px activity caused by 10 μM equol. These results indicate that equol at low dosage can prevent skeletal muscle cell damage induced by H₂O₂, while pretreatment with high-dosage equol shows a synergistic effect with H₂O₂ in inducing cell damage.     

Acetic acid-catalyzed hydrothermal pretreatment of corn stover for the production of bioethanol at high-solids content

Corn stover (CS) was hydrothermally pretreated using CH₃COOH (0.3 %, v/v), and subsequently its ability to be utilized for conversion to ethanol at high-solids content was investigated. Pretreatment conditions were optimized employing a response surface methodology (RSM) with temperature and duration as independent variables. Pretreated CS underwent a liquefaction/saccharification step at a custom designed free-fall mixer at 50 °C for either 12 or 24 h using an enzyme loading of 9 mg/g dry matter (DM) at 24 % (w/w) DM. Simultaneous enzymatic saccharification and fermentation (SSF) of liquefacted corn stover resulted in high ethanol concentration (up to 36.8 g/L), with liquefaction duration having a negligible effect. The threshold of ethanol concentration of 4 % (w/w), which is required to reduce the cost of ethanol distillation, was surpassed by the addition of extra enzymes at the start up of SSF achieving this way ethanol titer of 41.5 g/L.     

Response of cowpea bruchid,Callosobruchus maculatus (Fab.) (Coleoptera: Chrysomelidae) to cheese wood,Alstonia boonei De Wild stem bark oil extracted with different solvents

Cheese wood, Alstonia boonei De Wild stem bark was extracted with five different solvents namely: methanol, ethanol, acetone, petroleum ether and n-hexane. The extracts were tested for insecticidal activity on cowpea bruchid, Callosobruchus maculatus (Fab.). Adult mortality and adult emergence of the insects were investigated. Oviposition deterrences using dual-choice and multiple-choice tests were also investigated as well as percentage damage and weight loss at temperature of 28?±?2?°C and 75?±?5% relative humidity. Results showed that at the rate of 2% extract per 20?g of cowpea seeds, methanol, petroleum ether and n-hexane extracts caused 100% mortality of adult cowpea bruchid after four?days of post treatment. When the bruchid had choice of oviposition substrate, they laid significantly (p?<?0.05) fewer eggs on cowpea seeds treated with extracts compared to untreated seeds. There was no adult emergence in seeds treated with methanol, ethanol, petroleum ether and n-hexane extracts and 100% reduction in F₁ progeny was recorded compared with untreated that had 81.86% adults emergence and 0% reduction in F₁ progeny. The results obtained from this study revealed that methanol, ethanol, acetone, petroleum ether and n-hexane extracts of A. boonei stem bark were effective in controlling C. maculatus and could serve as an alternative to synthetic insecticides for the protection of stored cowpeas against bruchids.     

The effect of ethanol on arachidonic acid metabolism in the murine peritoneal macrophage

Exposure to ethanol in man has been linked to an alteration of the immune surveillance system and reduced ability of the macrophage to undergo phagocytosis. Since ethanol has been suggested to alter membrane function and inhibit the production of calcium ionophore stimulated synthesis of prostaglandins and leukotrienes by the human neutrophil and transformed murine mast cell, the dose response effect of ethanol on the biosynthesis of icosanoids by the peritoneal macrophage during zymosan phagocytosis was studied. Peritoneal macrophages from two inbred strains of mice derived from a common stock (HS) and selected for sensitivity to ethanol (shoprt sleep [SS]/long sleep [LS]) were studies. Zymosan phagocytosis was found to lead to synthesis of LTC₄ (70 ng/10⁶ cells), 6-keto-PGF_1a (5 ng/10⁶ (3 ng/10⁶ cells). For the HS macrophage, ethanol caused a dose dependent inhibition of these lipid mediators as well as inhibition of phagocytosis and release of beta-hexosaminidase. However, a difference was observed in arachidonate metabolism stimulated by phagocytosis between the LS and SS mice below 100 mM ethanol. The SS mouse had a 50% inhibition of cyclooxygenase products at 86 mM ethanol with no inhibition of lipoxygenase metabolites. The LS mice had a trend suggesting increased lipoxygenase metabolites below 100 mM ethanol. At these levels of ethanol which can be found in man, these results suggest there may be differential production of lipid mediators under genetic control.     

Inactivation of viable Ascaris eggs by reagents during enumeration.

Various reagents commonly used to enumerate viable helminth eggs from wastewater and sludge were evaluated for their potential to inactivate Ascaris eggs under typical laboratory conditions. Two methods were used to enumerate indigenous Ascaris eggs from sludge samples. All steps in the methods were the same except that in method I a phase extraction step with acid-alcohol (35% ethanol in 0.1 N H(2)SO(4)) and diethyl ether was used whereas in method II the extraction step was avoided by pouring the sample through a 38-microm-mesh stainless steel sieve that retained the eggs. The concentration of eggs and their viability were lower in the samples processed by method I than in the samples processed by method II by an average of 48 and 70%, respectively. A second set of experiments was performed using pure solutions of Ascaris suum eggs to elucidate the effect of the individual reagents and relevant combination of reagents on the eggs. The percentages of viable eggs in samples treated with acid-alcohol alone and in combination with diethyl ether or ethyl acetate were 52, 27, and 4%, respectively, whereas in the rest of the samples the viability was about 80%. Neither the acid nor the diethyl ether alone caused any decrease in egg viability. Thus, the observed inactivation was attributed primarily to the 35% ethanol content of the acid-alcohol solution. Inactivation of the eggs was prevented by limiting the direct exposure to the extraction reagents to 30 min and diluting the residual concentration of acid-alcohol in the sample by a factor of 100 before incubation. Also, the viability of the eggs was maintained if the acid-alcohol solution was replaced with an acetoacetic buffer. None of the reagents used for the flotation step of the sample cleaning procedure (ZnSO(4), MgSO(4), and NaCl) or during incubation (0.1 N H(2)SO(4) and 0.5% formalin) inactivated the Ascaris eggs under the conditions studied.     

Metabolic alterations produced in the liver by chronic ethanol administration. Increased oxidative capacity

1. Administration of ethanol (14g/day per kg) for 21–26 days to rats increases the ability of the animals to metabolize ethanol, without concomitant changes in the activities of liver alcohol dehydrogenase or catalase. 2. Liver slices from rats chronically treated with ethanol showed a significant increase (40–60%) in the rate of O₂ consumption over that of slices from control animals. The effect of uncoupling agents such as dinitrophenol and arsenate was completely lost after chronic treatment with ethanol. 3. Isolated mitochondria prepared from animals chronically treated with ethanol showed no changes in state 3 or state 4 respiration, ADP/O ratio, respiratory control ratio or in the dinitrophenol effect when succinate was used as substrate. With β-hydroxybutyrate as substrate a small but statistically significant decrease was found in the ADP/O ratio but not in the other parameters or in the dinitrophenol effect. Further, no changes in mitochondrial Mg²⁺-activated adenosine triphosphatase, dinitrophenol-activated adenosine triphosphatase or in the dinitrophenol-activated adenosine triphosphatase/Mg²⁺-activated adenosine triphosphatase ratio were found as a result of the chronic ethanol treatment. 4. Liver microsomal NADPH oxidase activity, a H₂O₂-producing system, was increased by 80–100% by chronic ethanol treatment. Oxidation of formate to CO₂ in vivo was also increased in these animals. The increase in formate metabolism could theoretically be accounted for by an increased production of H₂O₂ by the NADPH oxidase system plus formate peroxidation by catalase. However, an increased production of H₂O₂ and oxidation of ethanol by the catalase system could not account for more than 10–20% of the increased ethanol metabolism in the animals chronically treated with ethanol. 5. Results presented indicate that chronic ethanol ingestion results in a faster mitochondrial O₂ consumption in situ suggesting a faster NADH reoxidation. Although only a minor change in mitochondrial coupling was observed with isolated mitochondria, the possibility of an uncoupling in the intact cell cannot be completely discarded. Regardless of the mechanism, these changes could lead to an increased metabolism of ethanol and of other endogenous substrates.     

Anesthetic Effects on Secondary Dormancy and Phytochrome Responses in Setaria faberi Seeds

Seeds of giant foxtail (Setaria faberi Herm.) entered secondary dormancy after pretreatment in H₂O at 35°C. Pretreatment in 0.1 m ethanol, or several other substances with anesthetic properties, prevented secondary dormancy induction. Pretreatment in 0.5 m ethanol inhibited germination in darkness, but germination could be stimulated by a red irradiation. Germination was initially insensitive to light. Two separate responses are indicated. The first, affected by a variety of substances and low (0.1 m or less) concentrations of ethanol, is related to anesthetic effects and prevention of secondary dormancy. The second, induction of response to red irradiation, is caused by 0.5 m ethanol and some closely related substances. The anesthetic effect is accomplished within the first 8 hours of imbibition while the phytochrome induction effect required treatment for more than 24 hours. Both responses were lost if the 35°C imbibition began in H₂O. Involvement of cell membranes is suggested in the prevention of secondary dormancy by anesthetics.     

A cohesion/tension model for the gating of aquaporins allows estimation of water channel pore volumes in Chara

The water permeability (hydraulic conductivity; Lp) of turgid, intact internodes of Chara corallina decreased exponentially as the concentration of osmolytes applied in the medium increased. Membranes were permeable to osmolytes and therefore they could be applied on both sides of the plasma membrane at concentrations of up to 2.0 m (5.0 MPa of osmotic pressure). Organic solutes of different molecular size (molecular weight, MW) and reflection coefficients (σ_s) were used [heavy water HDO, MW: 19, σ_s: 0.004; acetone, MW: 58, σ_s: 0.15; dimethyl formamide (DMF), MW: 73, σ_s: 0.76; ethylene glycol monomethyl ether (EGMME), MW: 76, σ_s: 0.59; diethylene glycol monomethyl ether (DEGMME), MW: 120, σ_s: 0.78 and triethylene glycol monoethyl ether (TEGMEE), MW: 178, σ_s: 0.80]. The larger the molecular size of the osmolyte, the more efficient it was in reducing cell Lp at a given concentration. The residual cell Lp decreased with increasing size of osmolytes. The findings are in agreement with a cohesion/tension model of the osmotic dehydration of water channels (aquaporins; AQPs), which predicts both reversible exponential dehydration curves and the dependence on the size of osmolytes which are more or less excluded from AQPs (Ye, Wiera & Steudle, Journal of Experimental Botany 55, 449–461, 2004). In the presence of big osmolytes, dehydration curves were best described by the sum of two exponentials (as predicted from the theory in the presence of two different types of AQPs with differing pore diameters and volumes). AQPs with big diameters could not be closed in the presence of osmolytes of small molecular size, even at very high concentrations. The cohesion/tension theory allowed pore volumes of AQPs to be evaluated, which was 2.3 ± 0.2 nm³ for the narrow pore and between 5.5 ± 0.8 and 6.1 ± 0.8 nm³ for the wider pores. The existence of different types of pores was also evident from differences in the residual Lp. Alternatively, pore volumes were estimated from ratios between osmotic (P_f) and diffusional (P_d) water flow, yielding the number of water molecules (N) in the pores. N-values ranged between 35 and 60, which referred to volumes of 0.51 and 0.88 nm³/pore. Values of pore volumes obtained by either method were bigger than those reported in the literature for other AQPs. Absolute values of pore volumes and differences obtained by the two methods are discussed in terms of an inclusion of mouth parts of AQPs during osmotic dehydration. It is concluded that the mouth part contributed to the absolute values of pore volumes depending on the size of osmolytes. However, this can not explain the finding of the existence of two different types or groups of AQPs in the plasma membrane of Chara.