Largest recent impact craters on Mars: Orbital imaging and surface seismic co-investigation.

Two >130-meter-diameter impact craters formed on Mars during the later half of 2021. These are the two largest fresh impact craters discovered by the Mars Reconnaissance Orbiter since operations started 16 years ago. The impacts created two of the largest seismic events (magnitudes greater than 4) recorded by InSight during its 3-year mission. The combination of orbital imagery and seismic ground motion enables the investigation of subsurface and atmospheric energy partitioning of the impact process on a planet with a thin atmosphere and the first direct test of martian deep-interior seismic models with known event distances. The impact at 35°N excavated blocks of water ice, which is the lowest latitude at which ice has been directly observed on Mars.

Three-dimensional growth of human hepatoma C3A cells within alginate beads for fluidized bioartificial liver.

OBJECTIVES: Alginate beads allow cultivation of cells in a 3-dimensional environment. The aim of our study was to assess the influence of a 3-dimensional culture in alginate microbeads, on hepatic cell metabolism. METHODS: We used 2 types of alginate: low viscosity (LV) and medium viscosity (MV). The hepatic cell line C3A was encapsulated in alginate beads. Cells were cultured for 2 weeks. Using scanning electron microscopy, the morphology of 3D structures and the surfaces of cells were analyzed. Fluidized bed bioartificial liver experiments were performed 24 hours, 7, and 14 days after bead formation. RESULTS: Two different cell growth types in alginate beads were observed: channel-like structures and spherical aggregates characteristic of LV and MV alginate, respectively. A significant increase in albumin synthesis was observed in long-term culture. Formation of characteristic hepatic cell microvilli on cell surfaces was observed under scanning electron microscopy for both types of alginate. Prolonged static cultivation of C3A cells within the alginate beads in both types of alginates caused significant increases in albumin production in the fluidized bioreactor. CONCLUSIONS: Cultivation of the hepatic C3A cells within the alginate microbeads significantly improved bioreactor effectiveness in albumin production. The presence of extensions of cell membranes on the surface of hepatoma cells in 3-dimensional culture within the alginate beads indicated formation of microvilli-like structures characteristic of normal hepatocytes.

Culture of C3A cells in alginate beads for fluidized bed bioartificial liver.

Extracorporeal bioartificial liver has been designed to sustain the detoxification and synthetic function of the failed liver in patients suffering from acute liver failure until the time of liver allotransplantation or regeneration of their own. A fluidized bed, bioartificial liver improves the mass transfer velocity between the medium and the hepatocytes. Detoxification functions of the liver could be replaced by completely artificial systems, but the synthetic functions of hepatocytes may be obtained only by metabolically active cells. The aim of our study was to investigate the influence of C3A cell culture in alginate beads on synthetic function in a fluidized bed, bioartificial liver. Cells in alginate beads were prepared using an electrostatic droplet generator of our own design using low-viscosity alginate. Beads were cultured for 24 hours then 7 days in static conditions and then 24 hours of fluidization in the bioreactor to assess albumin production. We observed significantly increased albumin production by C3A cells entrapped in alginate beads during static culture. Fluidization increased albumin production compared with static culture. Fluidization performed after 7 days of static culture resulted in a significant increase in albumin synthesis. In conclusion, static culture of alginate beads hosting hepatic cells facilitates restoration of cell function.

Three-dimensional culture of hepatocytes on spongy polyethersulfone membrane developed for cell transplantation.

Implantable bioartificial liver has been investigated for patients suffering from liver insufficiency after mass liver resection or acute liver failure. Liver cells are implanted as free cell suspension, in microencapsulation systems or using microcarriers. To exhibit their typical functions, hepatic cells need a three-dimensional environment that is much more physiological than a flat one. The aim of our study was in vivo evaluation of spongy polyethersulfone membranes as a synthetic support for hepatic cells grown three dimensionally and transplanted to SCID/NOD mice. Spongy membranes were prepared using phase inversion from membrane-forming mixtures containing the following: polyethersulfone (based polymer), dimethylformamide (solvent), polyvinylpyrrolidone MW 10000 (small pore precursor), and cellulose (large pore precursor). We observed that polyethersulfone membranes were well tolerated by C3A cells and we did not observe any toxic effect, resulting in viability of cells >95%. Use of collagen gel as a support for cells on the scaffold gives the opportunity to increase 10 times the number of cells seeded on the membrane. Heparin addition to collagen gel did not influence albumin production in SCID/NOD mice. We observed an increase of albumin production after 7 and 14 days after implantation. Use of collagen gels in combination with polymer scaffolds allows preparation of bioartificial organs possessing high cell concentration for transplantation purposes.

Comparison of kinetic characteristics of amino acid-based and dipeptide-based peritoneal dialysis solutions.

UNLABELLED: A mixture of dipeptides (DP) has been proposed as alternatives (to glucose and amino acids, (AA)) osmotic agent in peritoneal dialysis (PD) solutions. DP based solutions may have metabolic and nutritional advantages compared to AA based solutions, as some sources of AA (such as tyrosine) are poorly soluble in water. In a previous study, we compared the kinetic characteristics of DP and AA based solutions; however, the amount of AA differed substantially. The aim of the present study was to compare solutions with almost equal amounts of AA. METHODS: The following solutions were used: (1) amino acid (AA) solution containing leucine, valine, lysine, isoleucine, threonine, phenylalanine and histidine (tyrosine was omitted because of its poor solubility), (2) dipeptide (DP) solution containing leucyl-valine, lysyl-isoleucine, threonyl-phenylalanine and histidyl-tyrosine. Sixteen Sprague-Dawley rats were divided in two groups and were subjected to intraperitoneal injection of either 25 mL of AA (n=8) or DP solution. Dialysate and blood samples were taken frequently postinfusion for measurement of AA and DP concentrations as well as AA from DP. RESULTS: Kinetic models were developed for estimation of diffusive mass transport coefficient between peritoneal cavity and blood (K BD), DP hydrolysis rate coefficient (K H) and AA clearance in the body (K C). Calculations showed that K H is about ten times lower than K BD. Thus, hydrolysis rate in peritoneal cavity is much lower than the diffusive transport rate of DP. K BD for AA appeared to be similar to K BD for dipeptides. K C was much higher than K BD for AA. This finding explains the rapid clearance of amino acids from blood. Nevertheless, the AA-based solution resulted in much higher peak concentrations of AA in blood after 120 min of the dwell than AA concentrations achieved following the use of the DP-based solution. CONCLUSIONS: Peritoneal transport characteristics of AA and DP were similar; however their kinetics in blood differs substantially. The DP solution resulted in a less pronounced increase in AA concentrations in blood, suggesting that DP solution could provide AA in a more physiological way.

Fluid and solute transport in CAPD patients before and after permanent loss of ultrafiltration capacity.

BACKGROUND: Two major types of permanent loss of ultrafiltration capacity (UFC) were previously distinguished among patients treated with CAPD: 1) type HDR with high diffusive peritoneal transport rate of small solutes and low osmotic conductance,but with normal fluid absorption rate, and 2) type HAR with high fluid absorption rate, but with normal diffusive peritoneal transport rate of small solutes and normal osmotic conductance. However, the detailed pattern of changes in peritoneal transport parameters in patients developing loss of ultrafiltration capacity is not known. OBJECTIVE: Analysis of solute and fluid transport parameters in the same patient before and after UFC loss. PATIENTS: Seven CAPD patients who had undergone repeated dwell studies,which were carried out before and/or after the onset of UFC loss. METHODS: Dialysis fluids (2 L) with glucose or a mixture of amino acids as osmotic agent at three basic tonicities were applied during 6 hour dwell studies. Fluid and solute transport parameters were previously shown not to be affected by these dialysis solutions (except by hypertonic amino acid-based solution). Intraperitoneal dialysate volume and fluid absorption rate were assessed using radiolabeled human serum albumin (RISA). Osmotic conductance (a(OS))was estimated by a mathematical model as ultrafiltration rate induced by unit osmolality gradient. Diffusive mass transport coefficients, K(BD), for glucose,urea,and creatinine were estimated using the modified Babb-Randerson-Farrell model. RESULTS: Five patients had increased K(BD) for small solutes after the onset of UFC loss,and three of them had decreased a(OS),whereas two patients had normal a(OS). In one of them, a(OS) decreased with time after the onset of UFC loss with concomitant normalization of glucose absorption. In all studies of these five patients the fluid absorption rate was within the normal range. Two other patients had increased fluid absorption rate (about 5 ml/min),and one of them also had increased K(BD) for small solutes,in two consecutive dwell studies in each patient with the second study being carried out at 1 and 7 months respectively after the first one. In all four studies in these two patients, the a(OS) was within the normal range. The sodium dip during dialysis with 3.86% glucose-based solution was lost, not only among most patients with UFC loss related to reduced osmotic conductance, but also in patients with increased K(BD). CONCLUSIONS: The occurrence of two major types of UFC loss was confirmed. However, a case of a mixed type of UFC loss with high fluid absorption rate and high K(BD) for small solutes, but normal osmotic conductance, and with normalization of initially high K(BD) for small solutes, linked with decreasing initially normal osmotic conductance,was also found. As a reduced sodium dip with hypertonic glucose solution is not only seen in patients with reduced osmotic conductance, it cannot reliably be used as a single measure of decreased aquaporin function. Permanent ultrafiltration capacity loss may be a dynamic phenomenon with a variety of alterations in peritoneal transport characteristics.

Survival analysis of Escherichia coli encapsulated in a hollow fiber membrane in vitro and in vivo: preliminary report.

The purpose of the observations was the viability and quality evaluation of E. coli bacteria encapsulated in hollow fiber membranes (HF) in short in vivo and in vitro experiments. A polypropylene, surface-modified hollow fiber was applied for immunoisolation of E. coli bacteria transfected with a green fluorescent protein (E. coli GFPI). The presence of GFP fluorescence of organisms was assessed with the use of flow cytometry. The E. coli GFPIs were then observed for the period of 5 days in in vitro experiments in the culture medium. A single IPTG (isopropyl beta-D-1-thiogalactopyranoside) induction of GFP gene appeared to be adequate for an expression of GFP protein for 5 days. The GFP expression values observed for E. coli GFPs encapsulated in HF during culture in different culture media were comparable. The survival of E. coli GFPIs encapsulated in HF after 1, 2, 4, or 5 days of subcutaneous implantation into mice was evaluated. The explanted E. coli GFPIs exhibited mean expression 603 +/- 17 (n = 32) units of fluorescence during the implantation period. The values obtained were comparable for selected days of observation. It was observed that the membranes applied ensured the bacteria growth within the HF's space only.

Membrane for immunoisolation--properties before, and post implantation: preliminary report.

The membranes preventing tissue overgrowth as well as toxic influence on cells encapsulated within can be obtained modifying the polypropylene membranes by silanization. The influence of the silanization with different siloxanes on membrane transport properties was assessed before and post implantation. No change in cut-off values was observed. All of the modified membranes delayed tissue overgrowth of implant in mouse. Spectroscopic evaluation of the membrane material after 4, 7 days, 2 and 4 months of implantation revealed membrane material stability. We concluded that evaluated membranes with cells encapsulated within may be applied as the systems for delivery of biologically active substances.

Kinetic studies of dipeptide-based and amino acid-based peritoneal dialysis solutions.

BACKGROUND: Dipeptide-based peritoneal dialysis solutions may have potential advantages compared with the glucose or amino acid-based solutions. Dipeptides may hydrolyze in the peritoneal cavity, generating constituent amino acids and thereby increasing the osmolality of the dialysate. Dipeptides can also be a valuable source of amino acids, which are poorly soluble in water, such as tyrosine. METHODS: Dwell studies in rats were performed during four hours with dipeptide solutions containing five dipeptides (Gly-His, Ala-Tyr, Thr-Leu, Ser-Phe, Val-Lys), 8, or 16 mmol/L of each dipeptide (low or high dipeptide group). Dwell studies were also performed with a 1.1% amino acid solution (Nutrineal(R)). The model of dipeptide hydrolysis (hydrolysis rate, KH), diffusive (rate constant, KBDD) and convective transport as well as transport of constituent amino acids consisted of mass balance equations, written for each dipeptide and amino acid. RESULTS: Peritoneal volume with the amino acid solution decreased much faster than that with the high and low dipeptide solutions. KH for all dipeptides did not differ between the high and low dipeptide groups. In the low dipeptide group, KH was 0.004 +/- 0.004 mL/min (mean +/- SD) for Gly-His (the lowest) and 0.088 +/- 0.048 mL/min for Thr-Leu (the highest). KBDD was higher than KH for all dipeptides, the average being 0.2 +/- 0.05 mL/min. CONCLUSIONS: Dipeptides are hydrolyzed in the peritoneal cavity, generating constituent amino acids. However, the hydrolysis rate appears to be several times lower than the dipeptide diffusive transport rate from dialysate to blood. Due to the higher molecular weight and intraperitoneal generation of amino acids, the dipeptide-based solutions provide more sustained ultrafiltration than the amino acid solution. The plasma concentration of amino acids at 60 minutes, in relation to the dose of amino acids delivered between 0 and 60 minutes, is considerably higher during the dwells with amino acid-based solution than during dwells with the dipeptide-based solutions.

Evaluation of a system producing the hemopoietic factor. WEHI-3B cell line function, when encapsulated in a polypropylene hollow fibre.

The purpose of our study was evaluation of functioning of WEHI-3B (an mouse cell line producing IL-3) cells encapsulated in hollow fibers (HF). In vitro: the WEHI-3B cells were encapsulated in HF of polypropylene K600 silikonized, and cultured over two weeks. In vivo: the encapsulated WEHI-3B after weeks culture, were implanted subcutaneously into mice for 1 week. After explantation encapsulated WEHI 3-B were cultured again in culture medium for one week. The production of IL-3 by encapsulated WEHI-3B cells was assessed by evaluation of IL-3 dependent, BaF3 cells viability. The percent number of one day survival of BaF3 cells in the culture medium supplemented with 15% of encapsulated WEHI-3B in vitro or encapsulated WEHI-3B after in vivo conditioned medium was comparable with positive control. Possible replacement of recombinant cytokines with HF encapsulated cytokine-producing cells may be a chance for continous supplementation of the factors for hematopoietic stem cells differentiation.

Errors involved in the application of an imperfect peritoneal volume marker.

Peritoneal volume markers have been used in numerous studies on fluid transport in peritoneal dialysis. The basic assumption used was that the macromolecular marker was stable and that the free fraction of a label (usually radiolabel) was negligibly small. In this study are presented theoretical investigations on the errors involved in application of an imperfect volume marker containing free fraction of a label. These investigations were used in assessing the errors in calculation of peritoneal volume time course, V, and fluid absorption rate (estimated by volume marker clearance, kE) using data from 20 clinical dwell studies with 1.36% Dianeal dialysis solution and radioiodinated human serum albumin as a volume marker. It has been shown that with an in vitro measured 125I free fraction of 2.72%, the error of kE estimation was 11%. However, the maximal error in estimation of V was only 0.2%. In conclusion, the performed analysis implies that calculation of the peritoneal volume time course during the dwell (with correction for the volume marker elimination) is very reliable, and the existence of a free fraction of a volume marker label results in a negligibly small error. However, even small free fraction of the label results in a significant overestimation of the fluid absorption rate.

Encapsulation of parathyroid cells in hollow fibers: a preliminary report.

The purpose of experiments was to evaluate the survival and functioning of human parathyroid cells after encapsulation in hollow fibers (HFs). The polypropylene HFs K600(PP Accurel (Akzo-Nobel, Germany) of inner diameter 0.6 mm, wall thickness 0.2 mm, original or surface modified were used for encapsulation. Production of parathormone (PTH) by encapsulated cells was measured in vitro. HF were filled with parathyroid cell suspension and tightly closed. Encapsulated cells were cultured for 9 or 33 days in RPMI 1640 containing 10% FCS or in Chang's medium. The level of PTH, produced by encapsulated cells was evaluated in the culture medium with radioimmunoassay test (RIA). The assays were performed every 2-4 days. The result of PTH assay was similar in both types of tested media as well as with unmodified and modified HFs, being 2-4 pg/ml of culture medium per 10(3) encapsulated cells. In conclusion, encapsulation in original or modified HFs ensures diffusion of nutrients from culture medium to encapsulated cells and allows for functioning of cells for at least 33 days in vitro.

Kinetic modeling of fluid and solute transport in peritoneal dialysis.

Mathematical models for fluid and solute transport during peritoneal dialysis are described. A model for the transport of the so-called volume marker enables the correct estimation of the kinetics of the intraperitoneal dialysate volume as well as the rate of peritoneal fluid absorption. On the basis of these estimations, the solute transport components (diffusion, convective solute transport with ultrafiltrate and peritoneal solute absorption) may be separated within the net solute transport using a modified version of the Babb-Randerson-Farrell (BRF) model. The diffusive mass transport coefficient and sieving coefficient are given by the model. A simplified method for the estimation of the diffusive mass transport coefficient during the so-called isovolemia period is also described and compared to the BRF modeling. The three-pore model and the distributed model, which describe the structure-function relationship for the peritoneum, are also addressed.

Discriminative impact of ultrafiltration on peritoneal protein transport.

OBJECTIVE: The dialysate concentration of large proteins increases, on average, linearly during the whole peritoneal dialysis dwell, and this linear pattern seems to be independent of the rate of ultrafiltration induced by dialysis fluid. However, we observed a high variability of protein kinetics in individual dwell studies. Therefore, we studied the details of the kinetic pattern of peritoneal transport. DESIGN AND METHODS: Kinetics of beta2-microglobulin, albumin, and total protein was examined in 23 clinically stable continuous ambulatory peritoneal dialysis patients using Dianeal 3.86% (15 dwell studies) or Dianeal 1.36% (9 dwell studies) dialysis fluid. Dialysate volume was measured using radioisotopically labeled albumin as a volume marker, with corrections for sample volume and absorption of fluid and marker from the peritoneal cavity. The generalized version of the Babb-Randerson-Farrell model was applied to estimate diffusive mass transport coefficient (K(BD)) and sieving coefficient (S) for proteins and small solutes (urea, creatinine, glucose, sodium, potassium). To quantify deviations from the linear pattern of protein dialysate concentration increase, the ratio (SR) of the slope of the linear regression line for the initial 3-30 minutes, divided by the slope for the next 60 - 360 minutes, was evaluated for albumin. RESULTS: In 5 dwell studies with Dianeal 3.86% fluid, SR was lower than 1 [low albumin transport (LAT) group, median SR = 0.49, range -4.39 - 0.71], while in the other 10 dwell studies with this solution, SR was higher than 1 [high albumin transport (HAT) group, median SR = 2.77, range 1.32 - 7.56]. Clearances of albumin up to 120 minutes were higher in the HAT group than in the LAT group. The transport of fluid, beta2-microglobulin, and small solutes did not differ between the LAT and the HAT groups. K(BD) values for proteins did not differ between the groups, but S values for albumin and total protein were lower for the LAT group than for the HAT group. A similar diversity was found in the dwell studies with Dianeal 1.36%: In three dwell studies, SR for albumin was lower than 1 (median SR = 0.95, range 0.70 - 0.97), and in six dwells it was higher than 1 (median SR = 1.55, range 1.23 - 1.98). In general, the SR values observed with Dianeal 1.36% were closer to 1 than those for Dianeal 3.86%. CONCLUSIONS: Ultrafiltration may affect the initial kinetic patterns of large protein (such as albumin) transport in two opposing ways: (1) by slowing the increase of protein concentration in dialysate (due to a low sieving coefficient, LAT group), and (2) by speeding up the increase of protein concentration in dialysate (due to a high sieving coefficient, HAT group). The average pattern in a non-selected group of studies is, however, close to a steady (linear) increase.

A simple method for hepatocyte attachment in hollow fibre bioreactors.

A new method for hepatocyte attachment in hollow fibre (HF) bioreactors was proposed and verified. A flow of medium with suspended hepatocytes, evoked by transmembrane pressure (TMP), and directed across the membrane into the fibre lumen, has accelerated and improved hepatocyte contact with the HF. It was found that seeding of hepatocytes onto the membrane was optimal at TMP of 50-80 mmHg. Ammonia utilisation and ureagenesis rates in hepatocytes seeded in the bioreactor suggests that the proposed method warrants proper conditions for cell functionality and allows for extended culture of hepatocytes in HF bioreactors. It is speculated that time cutback between introduction of hepatocytes into the bioreactor and the start of the cell attachment process, accomplished by the presented method, leads to substantially improved recovery of freshly isolated hepatocytes, and consequently to better overall performance of HF bioreactor.

Effect of blood perfusion on diffusive transport in peritoneal dialysis.

BACKGROUND: Diffusive transport between blood and dialysate during peritoneal dialysis is evaluated in clinical and experimental studies by the diffusive mass transport coefficient, KBD. This global parameter depends on the local diffusive characteristics of the blood capillary wall (permeability) and the tissue, as well as on the density and distribution of capillaries within the tissue. It also depends on the rate of delivery (or washout) of solutes from the tissue with blood flow, that is, on the rate of tissue perfusion. However, the role of blood perfusion in peritoneal transport has not been theoretically evaluated. METHODS: The relationship between the local characteristics of the peritoneal tissue and the global diffusive mass transport coefficient was studied using a new extended version of the distributed model for peritoneal transport, which included the effect of tissue perfusion and capillary surface area on the blood-tissue transport. RESULTS: The solute concentration profiles within the tissue were found to depend on the solute penetration depth, which is equal to the square root of the ratio of the solute diffusivity in tissue to the solute clearance from the capillary bed to tissue. It was shown that KBD might be interpreted as the dialysance of a capillary bed of a characteristic size that would be immersed directly in dialysate. A definition of the effective peritoneal blood flow (EPBF; the blood flow within the tissue layer) was formulated, and it was shown that EPBF depends on the local transport characteristics for the solute. Assuming typical values of the model parameters (known from physiological studies), the values of KBD and EPBF for urea, creatinine, glucose, and CO2 were calculated and compared with the measured values with good qualitative agreement. The transient initial increase of KBD values observed at the beginning of the peritoneal dialysis dwell was interpreted as a transient sixfold increase in tissue perfusion and a twofold increase in the capillary surface area. CONCLUSION: The distributed model can be useful as a theoretical tool for detailed physiological interpretations of changes in peritoneal transport associated with changes in peritoneal microcirculation and structure of the interstitium.

A simple and fast method to estimate peritoneal membrane transport characteristics using dialysate sodium concentration.

BACKGROUND: The peritoneal equilibration test (PET) is widely used to classify a patient's peritoneal transport characteristics. However, PET is laborious and the prediction of fluid removal based on PET is generally poor. It is believed that osmosis by glucose occurs partially through transcellular water channels, resulting in sieving of sodium and decrease of dialysate sodium concentration when using hypertonic glucose dialysate. OBJECTIVE: In this study, we investigated the possibility of using dialysate sodium concentration to classify the patient's peritoneal transport characteristics. METHODS: A 6-hour dwell study with frequent dialysate and plasma sampling was performed in 46 patients using 2 L of 3.86% glucose dialysate with 131I-albumin as an intraperitoneal volume (IPV) marker. The peritoneal transport of sodium, creatinine, glucose, and fluid was evaluated. RESULTS: The dialysate sodium concentration at 240 min (D(Na240)) significantly correlated with D/P creatinine (r = 0.76, p < 0.001) and D/D0 glucose (r = -0.83, p < 0.001) at 240 min of the dwell (better than dialysate sodium concentration at any other time of the dwell). DNa240 also significantly correlated with IPV at 240 min of the dwell (r = -0.61, p < 0.001)(better than D/P creatinine and D/D0 glucose). There were significant correlations between D(Na240) and the sodium-sieving coefficient (r = 0.71, p < 0.001) and the diffusive mass transfer coefficient for sodium (r = 0.50, p < 0.001). When using D(Na240) to divide the patients into four groups, as in the PET method, no significant difference was found between the two methods. CONCLUSION: Using 3.86% glucose solution, D(Na240) can be used instead of D/P creatinine to classify patients into different transport groups. D(Na240) provides a better prediction of peritoneal fluid transport and reflects both the diffusive and convective transport properties of the membrane. As only one dialysate sample (and no blood sample) is needed, D(Na240) may offer important clinical advantages compared with PET.

Evidence of circadian rhythm in low-density lipoprotein apoB catabolism and its impact on the estimation of kinetic parameters.

BACKGROUND: Compartmental models with constant parameters are commonly used in kinetic analysis of low-density lipoproteins (LDLs). Recent studies in animals have demonstrated the existence of circadian rhythms (CRs) in cholesterol synthesis and LDL catabolism. In this study, we investigated the possible existence of a CR in the fractional catabolic rate (FCR) of LDL apoB in man. MATERIALS AND METHODS: Radioactivity data from 45 turnover studies using 125I-labelled LDL apoB were analysed. In a preliminary analysis the pattern of radioactivity decay was investigated. Kinetic analysis was performed by using one- and two-compartment models with constant parameters (steady-state, SS, analysis). Parameters were estimated by the use of the whole data set, which included frequent sampling during the first day of the turnover study, or the once-a-day data, taken at 08.00 h. The selection of once-a-day data allowed elimination of the impact of a CR on parameter evaluation. Furthermore, non-steady-state (NSS) analysis was performed in which the FCR of LDL apoB was calculated as a function of time. In one additional subject, the FCR of LDL apoB was calculated separately for the day and the night using the urine-to-plasma (U/P) radioactivity ratio. RESULTS: The presence of a CR in LDL apoB catabolism, with higher FCR values during the day than during the morning, was demonstrated by the NSS analysis and confirmed by LDL apoB calculation from the U/P ratio. The SS analysis with the whole and the once-a-day data sets resulted in similar average FCR of apoB values (0.329 +/- 0.076 and 0.321 +/- 0.071 respectively) when the two-compartment model was used. Thus, a CR appeared to have little impact on the average FCR of apoB estimation. However, frequent sampling used in the hope of improving parameter estimation accuracy actually resulted in deterioration of the intercompartmental parameter estimators. CONCLUSION: The fractional catabolic rate of LDL apoB exhibited a circadian rhythm with higher FCR values during the day than during the morning. The presence of a CR had, however, a limited impact on the overall FCR of apoB values.

Peritoneal transport of glucose in rat.

OBJECTIVE: To evaluate the convective transport characteristics of glucose and the effect of high glucose and insulin during experimental peritoneal dialysis in rat. METHODS: Male Sprague-Dawley rats weighing 300-400 g were used in this study. Mannitol (5%) was used as osmotic agent. Glucose was added to dialysis solution to yield a concentration of 100 mg/dL (group 1) or 300 mg/dL (group 2). Mannitol solution (5%) containing the same concentration of electrolytes and lactate but without glucose was used as control (group 3). In group 2, blood sugar was maintained at approximately 300 mg/dL by continuous intravenous infusion of 25% glucose solution and 0.9% NaCl solution. A 2-hour dwell study was performed with 30 mL of test solutions. Intraperitoneal volume was calculated by volume marker (18.5 kBq of 131I-human radioiodinated serum albumin, RISA) dilution with corrections made for the elimination of RISA from the peritoneal cavity (K(E)) and sample volume. The diffusive mass transport coefficient (K(BD)) and sieving coefficient (S(BRF)) were calculated by using the Babb-Randerson-Farrell model. S was also calculated directly by using isocratic methods (S(I)). The peritoneal fluid absorption rate (K(E)) was taken into account for the calculation of S(I). RESULTS: Intraperitoneal volume was significantly higher in group 2 compared with groups 1 and 3. Peritoneal fluid absorption rate, K(E), was similar in all three groups. S(BRF) and S(I) for glucose were significantly lower in group 2 compared with groups 1 and 3. S(BRF) for glucose in group 2 was below zero and S(I) near zero. K(BD) for glucose was significantly higher in group 2 than in groups 1 and 3. Plasma and dialysate concentrations of insulin increased during the initial hour and then decreased to the baseline value in groups 1 and 3, while in group 2 it continuously increased. CONCLUSION: Significantly lower sieving coefficients for glucose in the high glucose and high insulin group suggest that transport mechanisms other than simple passive transport are involved in peritoneal glucose transport, and that high glucose per se and/or high insulin may be important factors that determine glucose transport characteristics.

Attachment and metabolic activity of hepatocytes cultivated on selected polymeric membranes.

Plasma or hormones added to hepatocyte incubation media mask the function of membranes as substrata per se for hepatocyte adhesion. This hypothesis was verified with hepatocyte cultures on various membranes in serum and hormone free medium. Freshly isolated rat hepatocytes were seeded on flat sheet membranes made of Cellulose Acetate (CA), aminated Cellulose Acetate (aCA), polysulfone (PSf) and sulfonated polysulfone (sPSf) and incubated in Hank's Balanced Salts Solutions (HBSS) as well as in William's E medium supplemented with newborn calf serum. It was found that PSf promoted hepatocyte adhesion most effectively. Good properties of PSf as a biomaterial for hepatocyte culture were confirmed in both media cultures. Urea synthesis and ammonia utilization measured in hepatocytes cultured on PSf were higher compared with other membrane cultures. PSf secured longer viability for a higher number of cells seeded on membrane compared with other investigated membranes, which is the reason for higher metabolic activity in PSf culture.