Segmental barrier properties of the pulmonary microvascular bed.

We determined liquid flux across single pulmonary microvessels of dog, ferret, and rat by our split-drop technique (J. Appl. Physiol. 64: 2562-2567, 1988). Data are reported from 58 lungs excised under halothane or pentobarbital sodium anesthesia and then blood perfused. We stopped blood flow at known vascular pressures and then micropunctured microvessels to inject oil, which we split with albumin solution. From measurements of vessel diameter and split oil drop length, we calculated Jv, the liquid transport rate per unit surface area [x 10(-6) ml/(cm2.s)]. At constant vascular pressure, Jv was not significantly different after different periods of oil-endothelium contact and at different sites within a single vessel. From measurements of Jv at different vascular pressures, we determined Lp, the hydraulic conductivity [x 10(-7) ml/(cm2.s.cmH2O)], and Pzf, the zero filtration pressure. From determinations of Pzf at different albumin concentrations, we quantified sigma alb, the albumin reflection coefficient. Lp and Pzf did not differ among venules of the same lung. However, in venules, Lp was 40% higher and sigma alb 25% lower than in arterioles (P less than 0.01). We conclude that 1) micropuncture procedures incidental to our split-drop technique do not progressively deteriorate the experimental microvessel and 2) in lung, permeability is higher in venules than in arterioles.     

Sites of transendothelial liquid transport in lung microcirculation

The widely held concept that the lung transmicrovascular liquid flux occurs primarily across septal vessels has not been experimentally verified. In fact, the recent literature suggests that much if not all of the flux may occur across extraseptal vessels. Support for this idea is available from morphological studies, from segmental filtration data, and from micropuncture data concerning lung microvascular and interstitial pressures. Recent split-drop measurements of lung venular hydraulic conductivity suggest that the surface area of filtration in the lung may be considerably smaller than presumed. The view is advanced that a major portion of lung filtration may occur in the preseptal microcirculation.     

Venular endothelium-derived NO can affect paired arteriole: a computational model

Venular endothelial cells can release nitric oxide (NO) in response to intraluminal flow both in isolated venules and in vivo. Experimental studies suggest that venular endothelium-released NO causes dilation of the adjacent paired arteriole. In the vascular wall, NO stimulates its target hemoprotein, soluble guanylate cyclase (sGC), which relaxes smooth muscle cells. In this study, a computational model of NO transport for an arteriole and venule pair was developed to determine the importance of the venular endothelium-released NO and its transport to the adjacent arteriole in the tissue. The model predicts that the tissue NO levels are affected within a wide range of parameters, including NO-red blood cell reaction rate and NO production rate in the arteriole and venule. The results predict that changes in the venular NO production affected not only venular endothelial and smooth muscle NO concentration but also endothelial and smooth muscle NO concentration in the adjacent arteriole. This suggests that the anatomy of microvascular tissue can permit the transport of NO from arteriolar to venular side, and vice versa, and may provide a mechanism for dilation of proximal arterioles by venules. These results will have significant implications for our understanding of tissue NO levels in both physiological and pathophysiological conditions.     

Immobilization of lipase by ultrafiltration and cross-linking onto the polysulfone membrane surface

In this study, a biphasic enzymatic membrane reactor was made by immobilizing Candida Rugosa lipase onto the dense surface of polysulfone ultrafiltration membrane by filtration and then cross-linking with glutaraldehyde solution. The reactor was further applied for the hydrolysis of olive oil, the performance of which was evaluated in respect of apparent reaction rate based on the amount of fatty acids extracted into the aqueous phase per minute and per membrane surface. It was found that the ultrafiltration and cross-linking process greatly improved the reaction rate per unit membrane area and the enzyme lifetime. The highest reaction rate reached 0.089 micromol FFA/min cm2 when the enzyme loading density was 0.098 mg/cm2. The results also indicated that the performance of lipase immobilized on the membrane surface was superior to that immobilized in the pores, and the apparent reaction rate and stability of immobilized lipases were improved greatly after cross-linking. It suggested that immobilization of enzymes by filtration and then cross-linking the enzymes onto the membrane surface is a simple and convenient way to prepare a high-activity immobilized enzyme membrane.     

Erythrocyte deformability and lung segmental vascular resistance: effect of hematocrit

We have investigated the role of erythrocyte (RBC) deformability and perfusate viscosity on lung segmental vascular resistance in 12 isolated perfused lungs of 3- to 5-wk-old rabbits. Each lung was perfused alternately with control and formaldehyde-fixed rabbit RBCs at a flow rate of 80 ml.kg-1.min-1, left atrial and airway pressures being 8 and 6 cmH2O, respectively (zone 3). Perfusate RBC concentration was kept constant at 3.2 x 10(6)/mm3 for group I lungs (n = 6) and 7.2 x 10(6)/mm3 for group II lungs (n = 6). In all lungs, we measured pressures in the pulmonary artery and in 20- to 50-microns-diam arterioles and venules with the micropipette servo-null method during both perfusion periods. Compared with control, fixed cells had a 60% decrease in deformability index (i.e., the volume of a dilute solution of RBCs filtered through a 5-microns Nuclepore filter in 1 min). In groups I and II, perfusate viscosity of fixed cells was 15 and 55% greater, respectively, than that of control cells. We found that perfusion with fixed cells in group I lungs did not alter total or segmental vascular pressure drops. However, in group II lungs, perfusion with fixed cells at twice the cell concentration resulted in an increase in total vascular pressure drop, mainly due to an increase in pressure drop in veins (50% of total) and arteries (33%). The relatively small (17%) increase in pressure drop in microvessels was probably due to distension and/or recruitment of capillaries resulting from increased venular pressures.(ABSTRACT TRUNCATED AT 250 WORDS)     

Solution of fatty acids from monolayers spread at the air-water interface: identification of phase transformations and the estimation of surface charge

The contraction or decrease in area of fatty acid monolayers maintained at a constant surface pressure of 16 dynes/cm was studied as a function of fatty acid chain length, unsaturation, temperature, and the hydrogen ion concentration in the subphase. The data were consistent with the hypothesis that fatty acid solution from the monolayer into the subphase was the mechanism for film loss. Autoxidative reactions did not contribute significantly to film loss since contraction occurred with saturated fatty acid monolayers and with unsaturated fatty acid monolayers in an anaerobic environment. The decrease in area per unit time or the solution rate was inversely proportional to chain length and directly proportional to the degree of unsaturation. Arrhenius plots showed activation energies of 1.5-2.5 kcal mole(-1) for tetradecanoic, octadecenoic, and octadecadienoic acids, and 25 kcal mole(-1) for hexadecanoic acid. The solution rate from the monolayer increased in a sigmoidal fashion with an increase in subphase pH, and the apparent surface pK(a) was estimated as the point where the solution rate was half-maximum. Apparent surface pK(a) values were: hexadecanoic acid, 9.7; octadecenoic acid, 8.3; tetradecanoic acid, 7.9; and octadecadienoic acid, 8.0.     

Determination of the Relationship between Nutrient Uptake Rate and Solution Concentration at the Root Surface under Field Conditions: 32P-Orthophosphate Uptake by Apple Roots

The relationships between the rates of uptake of ³²P-labelledorthophosphate per unit length, surface area and volume of rootand the concentration of ³²P-orthophosphate in solution at theroot surface were determined in a solution depletion experimentconducted in a root laboratory, using a part of the currentseason's roots of a 3.5-year-old composite apple tree growingunder field conditions. The results are compared with thoseof a previous experiment on young M.9 rootstocks grown in controlledenvironment. The rate of P uptake per unit root of the field-grown tree increasedapproximately linearly with P concentration in the externalsolution over the range 0.8–10.0 mmol m^–3, confirmingthe results of the growth cabinet experiment However, at anygiven external concentration, uptake rate per unit root of thefield-grown tree was lower than that observed in the growthcabinet experiment. Possible reasons for this difference arediscussed.     

Mechanism of inhibition of the proximal tubular isotonic fluid absorption by polylysine and other cationic polyamino acids.

The present study was initiated with the hope of clarifying the role of negative charges in the luminal brush border membrane in the overall process of trans-epithelial isotonic sodium and water absorption. Using micropuncture techniques, cationic polyamino acids such as polylysine (mol wt 100,000, 17,000 and 1,500-5,000, 1 mg/ml), tetralysine, polyornithine (mol wt 100,000, 1mg/ml), polyethyleneimine (2 mg/ml), polymyxin B (2 mg/ml), protamine sulfate (25 mg/ml) and histone (0.5 mg/ml) were perfused through the segments of rat kidney proximal tubule for 30 sec to 2 min. The rate of isotonic fluid absorption was measured before and after each perfusion with the Gertz's split drop method using Ringer's solution as a shrinking drop. Polylysine 100,000 and 17,000 and polyornithine were the most potent, inhibiting isotonic reabsorption by 93%. The sequence of inhibitory effect was: polylysine 100,000 congruent to polyornithine 100,000 congruent to polylysine 17,000 greater than polyethyleneimine greater than polylysine 1,500-5,000 congruent to polymyxin B greater than protamine sulfate congruent to histone. In contrast, tetralysine (2 mg/ml) showed no inhibitory effect. Electrical potential difference (p.d.) of the proximal tubular cells was destroyed within 10 sec of luminal perfusion with polylysine 100,000 (1 mg/ml). Simultaneously with the drop in p.d., electrical resistance of the luminal brush border membrane was nearly totally eliminated, whereas transepithelial input resistance remained unaltered. Furthermore, trypan blue dye was taken up by polylysine 100,000-perfused tubular cells but not by normal cells. Expanding drop analysis (mannitol solution as a split drop) was performed as a screening test to examine if the permeability for water and sodium in the lateral paracellular pathway is altered by polylysine 100,000. No significant difference was observed in the velocity of split drop expansion between untreated and polylysine-perfused tubules. A lower concentration of polylysine 100,000 (0.1 mg/ml) showed a much less inhibitory effect on fluid absorption and on cell p.d. These observations indicate that the strong inhibition on proximal tubular fluid absorption exerted by polylysine and perhaps also by other cationic polyamino acids is due not to modification of membrane negative charges but to the lysis of tubular cells by these polycations.     

Physiological determinants of the pulmonary filtration coefficient

Current emphasis on translational application of genetic models of lung disease has renewed interest in the measurement of the gravimetric filtration coefficient (K(f)) as a means to assess vascular permeability changes in isolated perfused lungs. The K(f) is the product of the hydraulic conductivity and the filtration surface area, and is a sensitive measure of vascular fluid permeability when the pulmonary vessels are fully recruited and perfused. We have observed a remarkable consistency of the normalized baseline K(f) values between species with widely varying body weights from mice to sheep. Uniformity of K(f) values can be attributed to the thin alveolar capillary barrier required for gas exchange and the conserved matching of lung vascular surface area to the oxygen requirements of the body mass. An allometric correlation between the total lung filtration coefficient (K(f,t)) and body weight in several species (r(2)=1.00) had a slope that was similar to those reported for alveolar and pulmonary capillary surface areas and pulmonary diffusion coefficients determined by morphometric methods in these species. A consistent K(f) is dependent on accurately separating the filtration and vascular volume components of lung weight gain, then K(f) is a consistent and repeatable index of lung vascular permeability.     

Plant factors influencing phosphorus uptake by white clover from solution culture

Summary The phosphorus (P) uptake rate of several white clover populations was determined in two solution culture experiments. Populations and cultivars differed in P uptake per plant and per unit root length in both experiments. Correlation and multiple regression analysis showed that differences between populations for P uptake per plant were largely related (r²>80%) to differences in leaf area and absolute growth rate, when plants had been grown at high-P levels, and by differences in root size and absolute growth rate when plants had been grown at low-P levels. Differences between populations for P uptake per unit root length were related (r²≈50%) to leaf area and relative growth rate in experiment 1 and to transpiration rate and water influx in experiment 2, when plants were pretreated at high-P levels. Differences between populations for P uptake per unit root length were negatively related to root size when plants had been grown at low-P levels. On the basis of these and other results it is suggested that P uptake per plant is determined largely by shoot factors. However, P uptake per unit root length is negatively related to root size, because demand for P is largely determined by shoot factors, and so differences in root size lead to an apparent difference in uptake per unit of root size.     

Oil drop size and gas hold-up in an oil–water airlift system with motionless mixers

The degree of emulsification, measured as surface area of oil generated, was studied. The effect of interfacial tension, volume fraction of oil, and power per unit volume on the Sauter mean diameter of the oil drops was determined in an airlift system with motionless mixers. A mathematical expression to predict the Sauter mean diameter was developed using regression techniques. From this equation another equation, which will predict the surface area of oil in terms of the same variables, was derived. The effects of water air surface tension and power per unit volume on the gas hold-up were obtained using similar techniques. The results show that the interfacial tension and the surface tension are important variables when hydrocarbon fermentations are carried out in airlift systems.     

Relation between cytochrome P-450 increase and endoplasmic reticulum proliferation in hepatocytes of mice treated with phenobarbital: a microphotometric and morphometric study.

To obtain detailed information on phenobarbital (PB)-induced cytochrome P-450 (P-450) increase and endoplasmic reticulum (ER) proliferation in hepatocytes, we estimated microphotometrically the amount of P-450 per unit cytoplasmic volume and morphometrically the area of ER per unit cytoplasmic volume in hepatocytes adjacent to the portal area or central venule (1 periportal or 1 perivenular cells) and in the second and third layers from the portal area or central venule (2, 3 periportal or 2, 3 perivenular cells) from mice injected with 35, 50, 100, or 150 mg/kg PB once a day for 3 days. By dividing the P-450 amount by the ER area, the number of P-450 molecules per unit ER area was also calculated. In 1 and 2, 3 perivenular cells, except for 2, 3 perivenular cells after injection of 150 mg/kg PB, the amount of P-450 increased with ER proliferation and the number of P-450 molecules in ER remained unchanged after injection of 50, 100, or 150 mg/kg PB. In 2, 3 periportal cells, however, the P-450 amount and the number of P-450 molecules in ER increased markedly without or with some ER proliferation after injection of 50, 100, or 150 mg/kg PB; the P-450 increase appears to be generally independent of ER proliferation. The 1 periportal cells are probably exceptional hepatocytes that usually did not respond to PB stimulation.     

Exercise training prevents the inflammatory response to hypoxia in cremaster venules.

Systemic hypoxia produces microvascular inflammation in several tissues, including skeletal muscle. Exercise training (ET) has been shown to reduce the inflammatory component of several diseases. Alternatively, ET could influence hypoxia-induced inflammation by improving tissue oxygenation or increasing mechanical antiadhesive forces at the leukocyte-endothelial interface. The effect of 5 wk of treadmill ET on hypoxia-induced microvascular inflammation was studied in the cremaster microcirculation of rats using intravital microscopy. In untrained rats, hypoxia (arterial Po(2) = 32.3 +/- 2.1 Torr) increased leukocyte-endothelial adherence from 2.3 +/- 0.4 to 10.2 +/- 0.3 leukocytes per 100 microm of venule (P < 0.05) and was accompanied by extravasation of FITC-labeled albumin after 4 h of hypoxia (extra-/intravascular fluorescence intensity ratio = 0.50 +/- 0.07). These responses were attenuated in ET (leukocyte adherence was 1.5 +/- 0.4 during normoxia and 1.8 +/- 0.7 leukocytes per 100 mum venule after 10 min of hypoxia; extra-/intravascular fluorescence intensity ratio = 0.11 +/- 0.02; P < 0.05 vs. untrained) despite similar reductions of arterial (32.4 +/- 1.8 Torr) and microvascular Po(2) (measured with an oxyphor-quenching method) in both groups. Shear rate decreased during hypoxia to similar extents in ET and untrained rats. In addition, circulating blood leukocyte count was similar in ET and untrained rats. The effects of ET on hypoxia-induced leukocyte-endothelial adherence remained up to 4 wk after discontinuing training. Thus ET attenuated hypoxia-induced inflammation despite similar effects of hypoxia on tissue Po(2), venular shear rate, and circulating leukocyte count.     

河西地区几种中生植物的蒸腾和传导率与叶内外环境的关系

用LI-1600稳态气孔仪,测定了河西地区分布较广的五种木本植物的蒸腾和传导率及环境因子。只要光照不低于气孔开启所需的强度,植物蒸腾率最高点之前的高低变化与叶温上升的速率无关,而仅与每一时刻叶温高低密切相关。在种内,蒸腾率大致随叶的厚度和单位叶面积的栅栏组织表面积的增大而提高。但种间则无此相关性。同一样本叶的上下表面蒸腾率之比与其气孔数之比相对应,而种间则毫无关系。环境条件大致相同情况下,二白杨(Populus kansuensis)全天蒸腾量为78.2gH2O·dm-2,沙枣(Elaeagnus angustifolia)为40,4gH2O·dm-2。分别是箭杆杨(P.nigra var.thevestina)的2.5和1.3倍。同一灌溉条件下,梨光杏(Prunus armeniaca var.glabra)为26.7gH2O·dm-2,比毛杏(P.armeniaca var.ansu)高0.6倍。     

Capillary filtration coefficient is independent of number of perfused capillaries in cat skeletal muscle

The capillary filtration coefficient (CFC) is assumed to reflect both microvascular hydraulic conductivity and the number of perfused capillaries at a given moment (precapillary sphincter activity). Estimation of hydraulic conductivity in vivo with the CFC method has therefore been performed under conditions of unchanged vascular tone and metabolic influence. There are studies, however, that did not show any change in CFC after changes in vascular tone and metabolic influence, and these studies indicate that CFC may not be influenced by alteration in the number of perfused capillaries. The present study reexamined to what extent CFC in a pressure-controlled preparation depends on the vascular tone and number of perfused capillaries by analyzing how CFC is influenced by 1) vasoconstriction, 2) increase in metabolic influence by decrease in arterial blood pressure, and 3) occlusion of precapillary microvessels by arterial infusion of microspheres. CFC was calculated from the filtration rate induced by a fixed decrease in tissue pressure. Vascular tone was increased in two steps by norepinephrine (n = 7) or angiotensin II (n = 6), causing a blood flow reduction from 7.2 +/- 0.8 to at most 2.7 +/- 0.2 ml x min(-1) x 100 g(-1) (P < 0.05). The decrease in arterial pressure reduced blood flow from 4.8 +/- 0.4 to 1.40 +/- 0.1 ml x min(-1) x 100 g(-1) (n = 6). Vascular resistance increased to 990 +/- 260% of control after the infusion of microspheres (n = 6). CFC was not significantly altered from control after any of the experimental interventions. We conclude that CFC under these conditions is independent of the vascular tone and number of perfused capillaries and that variation in CFC reflects variation in microvascular hydraulic conductivity.     

XYLEM ANATOMY,WATER FLOW,AND HYDRAULIC CONDUCTANCE IN THE FERN CYRTOMIUM FALCATUM

Xylem anatomy and water relations were studied in holly fern (Cyrtomium falcatum, Aspidiaceae) to determine the details of the pathway for water flow through an entire plant and the influence of tracheid number and lumen diameter on water flow. Each leaf has two adaxial traces and an abaxial trace, which are supplied by diarch adventitious roots attached to the dictyostele of the rhizome near the leaf base. Anatomical observations and dye experiments showed that each adaxial bundle vascularizes the approximately seven pinnae on its side of a leaf. An abaxial bundle is intermittently connected to an adaxial bundle as well as other abaxial bundles, forming a minor vascular pathway between the bundles of the leaf axis. Changes in both number and diameter of tracheids result in an acropetal decrease in hydraulic conductance per unit length along the rachis, although tracheid number locally increases when the trace for a pinna is produced in an adaxial bundle. Water flow was determined from the transpiration distal to the point in question or by forcing a solution through an axis with applied pressure. The water potential gradient along the plant axis was quite constant, indicating that hydraulic conductance per unit length varied with leaf area to be supplied. About 40% of the overall water potential drop occurred from the rachis into the pinnae, which reflected factors controlling water potential gradients in the lamina and not a very low conductance in the petiolule xylem. Hydraulic conductances calculated using the Hagen-Poiseuille equation and tracheid diameters were generally double those of measured conductances. Since the values tended to vary by a constant factor, tracheid number and diameter may largely control water flow in the xylem.     

Partition of lipids between emulsified oil and micellar phases of glyceride-bile salt dispersions

The composition of the emulsified oil and of the micellar phases obtained when a glyceride-fatty acid mixture is dispersed in bile salt solution has been defined. The micellar phase in equilibrium with the emulsified oil phase was obtained by filtration through Millipore filters. The behavior of different lipids in such systems was defined as the partition ratio, micellar/emulsified oil phase (m/o). Partition of fatty acids was found to be strongly dependent on the chain length of the fatty acid and the pH of the dispersion. The curve for partition against pH for oleic acid was interpreted to show a pK(a) for oleic acid in bile salt solution of approximately 7. The partition between micellar and oil phases is given for a series of lipids of different polarity. No significant difference in behavior was found for cholesterol and sitosterol. A relationship was found between the partition m/o and filtration rates through a Millipore filter in micellar solution. The lower the partition coefficient the lower was the rate of filtration. The results obtained are discussed in relation to the mechanism of absorption of fat from the small intestine.     

Nutrient inflows into apple roots. II. Nitrate uptake rates measured on intact roots of mature trees under field conditions

Abstract The rates of uptake of nitrate-N per unit length; surface area and volume of root were measured in solution depletion experiments conducted in a root laboratory, using intact roots of two 4.5-year-old apple trees (Discovery/M.9 and Worcester Pearmain/M.9) at two different depths in the soil profile. In Discovery/M.9, NO₃^? uptake rate per unit root was constant over the 20-200 mmol m^?3 range of solution concentration. In Worcester/M.9, the uptake rate per unit root over the 200-150 mmol m^?3 range (corresponding to a ‘lag’ phase) was lower than that over 150-20 mmol m^?3. The uptake rates after the lag phase at depths of 46 and 104 cm were ca. 1.3 and 5.0 times greater than those in Discovery/M.9 at the 46 and 110 cm depths, respectively. The concentration below which net uptake was zero was ca. 1 mmolm^?3. In Discovery/M.9, the uptake rate per unit root at the 46cm depth was about 2.8 times that at 110 cm whereas in Worcester/M.9, the uptake rates at 46cm depth were about 1.8 and 1.4 times lower than those at 104cm over the solution concentration ranges 200-150 and 150-20 mmol m^?3, respectively. Only small differences were observed in uptake rates per unit root between 1400-1700 h, 2400-0400 h, and 0700-1100 h. For successive 5°C-increments in root temperature between 5 and 25° C, the nitrate uptake rate per unit root increased by 130, 10, 30 and 5%, respectively. A major change in the activation energy for nitrate uptake was observed at a transition temperature located between 5°and 10°C.     

Effects of total parenteral nutrition on rat bile canaliculi: a stereologic analysis

OBJECTIVE: To quantitate, in a stereologic manner, changes in bile canalicular morphology before and after choleretic infusion of total parenteral nutrition (TPN) and to determine whether TPN produces changes in localized regions within the hepatic lobule. STUDY DESIGN: Livers were obtained from sham-operated on normal adult male rats (control) and from rats that received intravenous TPN solution containing 20% glucose and 3.5% Molipron F. The tissues, obtained by a rigorous sampling procedure, were systematically subjected to stereologic analysis. Measurements were made on electron micrographs at two levels of magnification by point, intersection and profile counts, and then volume, surface area and length were estimated per unit parenchymal volume. RESULTS: The surface area of the canalicular wall per parenchymal volume increased significantly (from 5.33 x 10(-2) to 6.73 x 10(-2) microns 2/micron 3) after TPN treatment, as did the length of microvilli (from 0.241 to 0.267 microns/micron 3). However, the volume of bile canalicular lumina per parenchymal volume (0.306% and 0.320%), total length of bile canaliculi (1.05 x 10(-2) and 1.06 x 10(-2) microns/micron 3) and diameter of microvilli (8.73 x 10(-2) and 8.94 x 10(-2) microns) remained constant. CONCLUSION: These results indicate that changes in canalicular shape and microvillus hypertrophy may cause lowering efficiency of the bile flow rate.