Errors in measuring water potentials of small samples resulting from water adsorption by thermocouple psychrometer chambers

The adsorption of water by thermocouple psychrometer assemblies is known to cause errors in the determination of water potential. Experiments were conducted to evaluate the effect of sample size and psychrometer chamber volume on measured water potentials of leaf discs, leaf segments, and sodium chloride solutions. Reasonable agreement was found between soybean (Glycine max L. Merr.) leaf water potentials measured on 5-millimeter radius leaf discs and large leaf segments. Results indicated that while errors due to adsorption may be significant when using small volumes of tissue, if sufficient tissue is used the errors are negligible. Because of the relationship between water potential and volume in plant tissue, the errors due to adsorption were larger with turgid tissue. Large psychrometers which were sealed into the sample chamber with latex tubing appeared to adsorb more water than those sealed with flexible plastic tubing. Estimates are provided of the amounts of water adsorbed by two different psychrometer assemblies and the amount of tissue sufficient for accurate measurements of leaf water potential with these assemblies. It is also demonstrated that water adsorption problems may have generated low water potential values which in prior studies have been attributed to large cut surface area to volume ratios.     

A deoxygenation system for measuring protein phosphorescence

An inexpensive and quick deoxygenation system for measuring protein phosphorescence is described. Oxygen was first reduced to less than 1 ppb from nitrogen or other inert gas by passing through an oxygen trap. The oxygen-free gas was routed through stainless steel tubing directly into the sample compartment of the phosphorimeter. Flexible tubing, coupled to the stainless steel tubing, was run through the septum of a cuvette sealed with a gray butyl rubber lyophilization stopper. The flexible tubing allowed for manipulation of the cuvette during alternate cycles of vacuuming and nitrogen equilibration. Utility of the system was demonstrated by measuring the phosphorescence lifetimes of N-acetyl-L-tryptophanamide, alkaline phosphatase, human serum albumin, and recombinant human serum albumin. Phosphorescence lifetimes of 2 ms for N-acetyl-L-tryptophanamide, almost double that previously reported, were routinely achieved while a lifetime of 1.84 s was obtained for alkaline phosphatase, well within the reported range of 1.5-2s. Human serum albumin, which contains a single tryptophan, showed a biexponential decay with lifetimes of 4.33 and 17 ms, in contrast to previous reports of a biexponential decay with rates of 0.2 and 0.9 ms. Recombinant human serum albumin was even more striking with lifetimes of 4.60 and 68.2 ms. The data are explained based on the recently published X-ray crystallographic structure of human serum albumin. The simplicity and reproducibility of the system should make this technique practical for most biochemical labs.     

Internal current generation in respiration chambers

A technical device generating a constant and directed current within a sealed respiration chamber is described. It does not involve any external pumps or tubing. This system is easy to handle, and improved the maintenance of rheotactic pelagic species like the Northern krill (Meganyctiphanes norvegica, Crustacea) or small fishes (Gasterosteus aculeatus) under experimental conditions.     

Behavior of a viscoelastic valveless pump: a simple theory with experimental validation

Background  

A valveless pump generates a unidirectional net flow of fluid around a closed loop of soft viscoelastic tubing that is rhythmically compressed at one point. The tubing must have at least two sections with two different stiffnesses. When a short segment of the tube is squeezed asymmetrically at certain frequencies, net flow of fluid around the loop can occur without valves.     

Development of screening systems for evaluation of materials used in mammalian embryo transfer

Embryo transfer units use a wide variety of materials that come in contact with embryos. Studies were conducted to evaluate procedures that could be utilized to determine the toxicity of some commonly used materials in embryo collection, culture and transfer. Forty-five female mice were sacrificed on Day 3 or 4 of gestation (Day 1 = vaginal plug), and the uterus and oviducts were removed and minced. A total of 522 embryos was collected (4-cell to blastocyst stages). Four to 16 cell embryos were cultured in Phosphate Buffered Saline (PBS) plus 20% fetal bovine serum. Morula to blastocyst stage embryos were cultured in Nutrient Mixture F10 (HAM) plus 20% fetal bovine serum gassed with 5% CO(2), 5% O(2) and 90% N(2). In Experiment I, embryos and culture media were placed in a covered embryological watch glass (EWG, control) or sealed in the lumen of a siliconized Foley catheter or a section of 1) latex tubing, 2) tygon tubing or 3) silastic tubing. In Experiment II, embryos were placed in EWG and cultured alone (control) or cocultured with sections of 1) tygon tubing, 2) silastic tubing or 3) latex tubing. In Experiment III, embryos were cultured in covered plastic petri dishes containing 15 ml of media, alone (control) or co-cultured with two new plunger tips from sterile Monoject syringes. All embryos were cultured at 32 to 34 degrees C for 24 h. The Criterion used for development was two or more cellular divisions within the 24-h period. Embryo development in Experiment I was lower (P<0.05) in latex (0%) and tygon (24%) tubing and in the siliconized Foley catheter (2%) than in silastic tubing (51%) and the EWG (46%), which did not differ. Experiment II embryos that were co-cultured with latex tubing (5%) showed very little development as compared with those co-cultured with tygon tubing (76%), silastic tubing (76%) and EWG (93%), the last of which were not significantly different. Embryos co-cultured with Monoject syringe plunger tips had a reduced embryo development rate compared to embryos in the control group (0% vs 52%). Although the embryos did not remain in contact with these seemingly toxic materials for prolonged periods, our results indicate that a significant reduction in embryo viability may occur due to this exposure.     

Chlorine dioxide disinfection of single and dual species biofilms, detached biofilm and planktonic cells

Disinfection efficacy testing is usually done with planktonic cells or more recently, biofilms. While disinfectants are much less effective against biofilms compared to planktonic cells, questions regarding the disinfection tolerance of detached biofilm clusters remain largely unanswered. Burkholderia cepacia and Pseudomonas aeruginosa were grown in chemostats and biofilm tubing reactors, with the tubing reactor serving as a source of detached biofilm clusters. Chlorine dioxide susceptibility was assessed for B. cepacia and P. aeruginosa in these three sample types as monocultures and binary cultures. Similar doses of chlorine dioxide inactivated samples of chemostat and tubing reactor effluent and no statistically significant difference between the log(10) reductions was found. This contrasts with chlorine, shown previously to be generally less effective against detached biofilm particles. Biofilms were more tolerant and required chlorine dioxide doses ten times higher than chemostat and tubing reactor effluent samples. A second species was advantageous in all sample types and resulted in lower log(10) reductions when compared to the single species cultures, suggesting a beneficial interaction of the species.     

Theoretical considerations of the rate of dehydration by histological freezing-drying

The dependence of the rate of dehydration by freezing-drying on the temperature of the sample, the pressure over the sample, the partial pressure of water at the trap, the radius of the tubing of the freezing-drying unit, and the length of the path from the sample to the trap has been discussed. From the analysis it can be concluded that a freezing-drying apparatus will be very efficient if it has: 1) pumps capable of giving a pressure of 10^?5 mm Hg; 2) a sample temperature above ?40 °C; 3) a water condenser at approximately the temperature of liquid nitrogen; 4) a radius of the tubing of the freezing-drying unit greater than 3 cm; and 5) a path between the sample and the condenser less than 4 cm.     

The Effect of Equilibration Time and Tubing Material on Soil Gas Measurements

The collection of soil vapor samples representative of in-situ conditions presents challenges associated with the unavoidable disturbance of the subsurface and potential losses to the atmosphere. This article evaluates the effects of two variables that influence the concentration of volatile organic compounds in soil vapor samples: equilibration time and tubing material. The time for three types of soil vapor probes (i.e., macro-purge, mini-purge, and post-run tubing probes [PRT]) to equilibrate with subsurface conditions was assessed by installing probes and collecting multiple samples over a 72-hour period. The effect of tubing material was evaluated by collocating soil vapor probes constructed with different tubing material and collecting samples over several months. We recommend that soil vapor probes constructed with a sand filter-pack and bentonite seal (i.e., macro-purge probe) equilibrate for 24 to 48 hours prior to sample collection. Post-run tubing (PRT) probes equilibrated within one to two hours while a new probe design, (i.e., mini-purge probe) equilibrated and could be sampled after only 30 minutes for screening assessments. Nylaflow, Teflon®, polyetheretherketone (PEEK), and stainless-steel tubing had comparable trichloroethene (TCE) concentrations over all sampling time frames. We recommend that copper tubing be avoided and polyethylene only be used for screening assessments.     

Chlorine dioxide disinfection of single and dual species biofilms,detached biofilm and planktonic cells

Disinfection efficacy testing is usually done with planktonic cells or more recently, biofilms. While disinfectants are much less effective against biofilms compared to planktonic cells, questions regarding the disinfection tolerance of detached biofilm clusters remain largely unanswered. Burkholderia cepacia and Pseudomonas aeruginosa were grown in chemostats and biofilm tubing reactors, with the tubing reactor serving as a source of detached biofilm clusters. Chlorine dioxide susceptibility was assessed for B. cepacia and P. aeruginosa in these three sample types as monocultures and binary cultures. Similar doses of chlorine dioxide inactivated samples of chemostat and tubing reactor effluent and no statistically significant difference between the log₁₀ reductions was found. This contrasts with chlorine, shown previously to be generally less effective against detached biofilm particles. Biofilms were more tolerant and required chlorine dioxide doses ten times higher than chemostat and tubing reactor effluent samples. A second species was advantageous in all sample types and resulted in lower log₁₀ reductions when compared to the single species cultures, suggesting a beneficial interaction of the species.     

A simple system for the measurement of ion activities with solvent polymeric membrane electrodes.

A simple device for the application of ion-selective liquid membrane electrodes to biochemistry is described. K⁺- and Ca²⁺-selective membranes were sealed on polyvinyl chloride (PVC) tubing and inserted into the side wall of a Plexiglas reaction vessel, enabling simultaneous measurements of K⁺ and Ca²⁺. The vessel also permits the simultaneous detection of changes in pH and oxygen and is predisposed to work under a controlled atmosphere. The system is particularly suitable for the measurement of fast changes in ion activities, since the stirring system described has a mixing time below 0.1 s. The 95% response times of the ion-selective electrodes and of the oxygen electrode were below 0.5 s. The volume of the reaction vessel is 0.5–1.0 ml.     

The use of a silastic shield to protect an externalized biliary cannula

A simple shield made of a folded silastic sheet is described for the protection of the externalized portion of a permanent biliary cannula in rats. Advantages of this shield are its light weight, flexibility, transparency, and ease of resealing for repeated interruption of hepatobiliary circulation. Since the shield is positioned around rather than being a segment of the cannula, a single length of tubing can be used.     

Optimal design of the tubular microporous membrane aerator for shear-sensitive cell cultures.

In this paper, a theoretical analysis of oxygen transport across the tubular microporous membrane is described. This analysis has provided some insight into the optimal design of the membrane aerator. It was found in this study, at fixed inlet pressure, that the overall membrane oxygen transfer rate increases with increased tubing length only up to a certain length, i.e., the "critical length". When a large membrane surface area is required, the fiber should be divided into parallel segments to increase the overall oxygen transfer rate. A manifold or a gas distributor can then be used to distribute gas into segments of tubing. The length of each segment cannot exceed the critical length. In addition, shorter tube segments should give a higher oxygen transfer rate per unit tube length; however, this advantage is counterbalanced by the fact that gas distribution into huge numbers of parallel tubings may not be uniform.     

Ventilation of a rat with a large-animal respirator

Rats were effectively ventilated with 100% O2 mixed with room air utilizing a modified tracheostomy tube and a Bird Mark 7 respirator to maintain arterial blood gases within normal limits. A 3-cm segment of rubber pilot tubing was attached to a 15-mm respiratory connector and a 3-cm piece of polyethylene catheter tubing was fitted snugly into the other end. The catheter was inserted and secured into the trachea of 250- to 500-g Sprague-Dawley rats with the adaptor hose of the respirator fitted onto the 15-mm connector following tracheostomy. Manometer and inspiratory flow rate controls of the respirator were set to their minimum operating position. Appropriate rate control adjustments were made when necessary as determined by arterial blood gas measurements. By use of the above ventilation system, adequate arterial blood gases of anesthesized rats can be maintained for greater than 3 h.     

Preparative separation of proteins using centrifugal precipitation chromatography based on solubility in ammonium sulfate solution

A preparative modification of the centrifugal precipitation chromatography (CPC) is described. The sample-loading capacity is improved in the present system by the use of convoluted tubing containing dialysis tubing instead of a dialysis membrane placed between a pair of disks equipped with mirror-imaged spiral grooves as in the original design. The system uses, basically, the same principle of as the original CPC, in that a concentration gradient of precipitant is generated under a centrifugal force field. The protein sample injected into the CPC column is exposed to an increasing concentration of the precipitant where it precipitates at various portions of the column according to its solubility. The gradient is then gradually lowered so that the sample undergoes dissolution and precipitation many times within the column; the proteins finally elute from the column according to their solubilities. A basic study was performed using this machine to separate human albumin and 3-globulin using ammonium sulfate (AS) as precipitant. Preliminary results indicate that this method can separate 500 mg of protein.     

Semipermanent microscope slides of microfungi using a sticky tape technique

A technique is described for making semipermanent microscope slides of fungi using sticky tape. After being touched to a fungal colony, a modified segment of sticky tape is touched to ethyl alcohol and then immersed in a 50% glycerine solution containing cotton blue stain. Finally, it is transferred (sticky side up) to a microscope slide, covered with a cover with a cover glass, and sealed.     

A flow-through amperometric sensor based on dialysis tubing and free enzyme reactors.

A generic flow-through amperometric microenzyme sensor is described, which is based on semi-permeable dialysis tubing carrying the sample to be analyzed. This tubing (300 microm OD) is led through a small cavity, containing the working and reference electrode. By filling this cavity with a few microl of an appropriate enzyme solution, an amperometric enzyme sensor results. As the dialysis tubing is impermeable for large molecular species such as enzymes, this approach does not require any immobilization chemistry, and as a consequence the enzyme is present in its natural free form. Based on this principle, amperometric sensors for lactate, glucose, and glutamate were formed by filling cavities, precision machined in Perspex, with buffered solutions containing respectively, lactate-, glucose-, and glutamate-oxidase. All sensors showed a large linear range (0-35 mM for glucose, 0-3 mM for lactate, and 0-5 mM for glutamate) covering the complete physiological range. The lower detection limit was in the order of 15-50 microM. Applicability in flow injection analysis systems is demonstrated.     

Microdialysis in human skeletal muscle: effects of adding a colloid to the perfusate.

Microdialysis catheters (CMA-60 with a polyamide dialysis membrane; 20,000-molecular wt cutoff) were either immersed in an external medium or were inserted in the quadriceps femoris muscle of healthy subjects, using perfusate with or without dextran 70. Varying the position of the outflow tubing induced changes in hydrostatic pressure. The sample volumes were significantly smaller in catheters perfused without a colloid compared with those perfused with a colloid [11-50% (in vitro) and 8-59% (in vivo) lower than in colloid-perfused catheters with the same position of the outflow tubing]. The sample volumes were also significantly smaller when the dialysis membrane was influenced by maximal hydrostatic pressure (above position) compared with minimal hydrostatic pressure (below position) [7-38% (in vitro) and 3-46% (in vivo) lower than in catheters in the below position with the same perfusion fluid]. In vivo, glucose concentration at a perfusion flow rate of 0.33 microl/min was higher when the catheters were perfused without a colloid [18-28% higher than in colloid-perfused catheters with the same position of the outflow tubing (P < 0.001)] than with a colloid. A corresponding difference also tended to occur with lactate, glycerol, and urea. At 0.16 microl/min, the glucose concentration was the same irrespective of whether fluid loss had been counteracted by colloid inclusion or by lowering of outlet tubing. The mechanism behind the observed concentration difference is thought to be a higher effective perfusion flow rate when fluid loss is prevented at low-perfusion flows. This study shows that fluid imbalances can have important implications for microdialysis results at low-perfusion flow rates.     

An Improved Method of Making Tissue Carriers for TEM and SEM Fixation

Hazards in fixing small pieces of tissue for electron microscopy include damage, drying, or loss. Over the years, microstrainer tissue carriers have been developed to minimize these problems. Construction materials have included glass tubing, copper grids for electron microscopy, stainless steel screen, and bolting silk (Padawer 1951, Friend 1963, Bronskill 1970). Carriers made from plastic embedding molds (e.g., BEEM capsules) with either TEM grids attached to the conical tip (Buchanan 1965) or Nitex screen cloth held to one end by a retaining ring have proven to be inexpensive and popular, though the former has a very small filtration area and in the latter small tissues may be lost or crushed between the screen cloth and the bottom rim of the carrier. This note describes a carrier in which Nitex is permanently sealed to the bottom edee of a BEEM capsule cylinder.     

Dialysis technique for containment of microbial populations inoculated into food systems.

A technique utilizing dialysis tubing was developed for the containment of microbial populations introduced into a food system. The entrapment of the inoculum was accomplished while reducing interference with interactions between the sample and the surrounding environment.     

Dialysis technique for containment of microbial populations inoculated into food systems.

A technique utilizing dialysis tubing was developed for the containment of microbial populations introduced into a food system. The entrapment of the inoculum was accomplished while reducing interference with interactions between the sample and the surrounding environment.