Direct immunochemical sensing: basic chemical principles and fundamental limitations

Models describing the binding of antigens to surface immobilised antibodies have been developed. These models are applied to the assessment of the likely analytical utility of direct immunochemical sensors employing immobilised antibody layers. Fundamental limitations to the device response arising from the equilibrium and kinetic characteristics of the binding reaction and from mass transport constraints imply that measurement over the micromolar to nanomolar concentration range may be practical.     

On the merits of viable-cell immobilisation

Many advantages have been claimed over the years for the use of immobilised cells, both as enzyme systems and as whole viable cell systems for complete fermentation reactions. However, few of the claims have been fully substantiated, and may not even be entirely justified. Most research is involved with single applications and the best that can be hoped for is some evidence that immobilised cells in each of these individual cases display some advantage over the equivalent free cell system. The purpose of this review is to assess the merits of viable cell immobilisation in the light of published literature and to elucidate the underlying mechanisms. Particular attention is paid to the generally unanticipated, but widely observed enhanced stability of immobilised cell fermentation processes.     

Characterisation and optimisation of AC conductimetric biosensors

Urease, immobilised on interdigitated gold electrodes, is employed as a model enzyme for characterisation and optimisation of a.c. conductimetric sensors. The sensors' response is measured over a frequency range of 20 Hz to 300 kHz and an optimum operating frequency established. The activity of the urease, both in solution and immobilised states, is investigated and Km values obtained. The effect of method of immobilisation and enzyme loading on the sensors' performance are studied and urease electrodes are characterised as a function of temperature, pH and electrolyte concentration. An important finding, particularly for conductimetric sensors designed for clinical use, is that proper consideration of the effects of electrode polarisation must be taken into account in order to maintain high sensor sensitivity at physiological electrolyte concentrations. Measurements of urea concentration in untreated serum are described.     

Resting and osmotically induced basolateral K conductances in turtle colon

Two types of K conductance can be distinguished in the basolateral membranes of polyene-treated colonic epithelial cells (see Germann, W. J., M. E. Lowy, S. A. Ernst, and D. C. Dawson, 1986, Journal of General Physiology, 88:237-251). The significance of these two types of K conductance was investigated by measuring the properties of the basolateral membrane under conditions that we presumed would lead to marked swelling of the epithelial cells. We compared the basolateral conductance under these conditions of osmotic stress with those observed under other conditions where changes in cell volume would be expected to be less dramatic. In the presence of a permeant salt (KCl) or nonelectrolyte (urea), amphotericin-treated colonic cell layers exhibited a quinidine-sensitive conductance. Light microscopy revealed that these conditions were also associated with pronounced swelling of the epithelial cells. Incubation of tissues in solutions containing the organic anion benzene sulfonate led to the activation of the quinidine-sensitive gK and was also associated with dramatic cell swelling. In contrast, tissues incubated with an impermeant salt (K-gluconate) or nonelectrolyte (sucrose) did not exhibit a quinidine-sensitive basolateral conductance in the presence of the polyene. Although such conditions were also associated with changes in cell volume, they did not lead to the extreme cell swelling detected under conditions that activated the quinidine-sensitive gK. The quinidine-sensitive basolateral conductance that was activated under conditions of osmotic stress was also highly selective for K over Rb, in contrast to the behavior of normal Na transport by the tissue, which was supported equally well by K or Rb and was relatively insensitive to quinidine. The results are consistent with the notion that the basolateral K conductance measured in the amphotericin-treated epithelium bathed by mucosal K-gluconate solutions or in the presence of sucrose was due to the same channels that are responsible for the basolateral K conductance under conditions of normal transport. Conditions of extreme osmotic stress, however, which led to pronounced swelling of the epithelial cells, were associated with the activation of a new conductance, which was highly selective for K over Rb and was blocked by quinidine or lidocaine.     

Determination of heat changes in the proximity of immobilised enzymes with an enzyme thermistor and its use for the assay of metabolites.

A device, the enzyme thermistor, is described which is capable of measuring changes in heat due to enzymic reactions. The sensor, a thermistor, is in direct contact with the site of reaction through its placement in a microcolumn filled with an immobilised enzyme preparation. The substrate solution flows past the thermistor tip, and as much as approx. one half of the total heat evolved can be registered as temperature change, deltat. Glass-bound glucose oxidase (EC 1.1.3.4), penicillinase (EC 3.5.2.6), trypsin (EC 3.4.21.4) and urease (EC 3.5.1.5) were used for the determination of glucose, penicillin G, benzoyl-L-arginine ethyl ester and urea respectively. Linear relationships between the deltat recorded and the concentration of substrate were obtained in all cases.     

Studies on the accumulation of heavy metal elements in biological systems

Summary Cells of a Daucus carota suspension culture were entrapped in a matrix of calcium alginate. The immobilised cells, incubated in a buffer mixture of sucrose, nitrate, KCl, CaCl₂, 2-(N-morpholino)-ethane sulphonic acid at pH 5.5, hydroxylated digitoxigenin. When compared under the same incubation conditions, freely suspended cells biotransformed digitoxigenin at a faster rate. Periplogenin formation was maximal at pH 5.3 and temperatures of 26°–34°C. The hydroxylase activity of the entrapped cells adapted to the presence of 20 mM CaCl₂ over a 12 day incubation. The diffusion barrier established on entrapment of the cells could not be overcome by addition of detergents or methanol. Controlled addition of chloroform (at 1/4 and 1/2 saturation) did stimulate hydroxylation of digitoxigenin without adversely affecting cell viability. The rate of hydroxylation of digitoxigenin was linear over an immobilised cell concentration of 0–7 mg dry weight and a digitoxigenin concentration of 0–20 mg/L. Five consecutive batch bioconversions at a rate greater than 60% could be achieved before the biocatalyst was inactivated. The results are discussed in relation to improving the hydroxylation reaction by immobilised D. carota and other reactions performed by immobilised plant cells.     

Long-term storage and safe retrieval of DNA from microorganisms for molecular analysis using FTA matrix cards

We assessed the potential use of Whatman FTA paper as a device for archiving and long-term storage of bacterial cell suspensions of over 400 bacterial strains representing 61 genera, the molecular applications of immobilised DNA on FTA paper, and tested its microbial inactivation properties. The FTA paper extracted bacterial DNA is of sufficiently high quality to successfully carryout the molecular detection of several key genes including 16S rRNA, esp (Enterococcus surface protein), Bft (Bacteroides fragilis enterotoxin) and por (porin protein) by PCR and for DNA fingerprinting by random amplified polymorphic DNA-PCR (RAPD-PCR). To test the long-term stability of the FTA immobilised DNA, 100 of the 400 archived bacterial samples were randomly selected following 3 years of storage at ambient temperature and PCR amplification was used to monitor its success. All of the 100 samples were successfully amplified using the 16S rDNA gene as a target and confirmed by DNA sequencing. Furthermore, the DNA was eluted into solution from the FTA cards using a new alkaline elution procedure for evaluation by real-time PCR-based assays. The viability of cells retained on the FTA cards varied among broad groups of bacteria. For the more fragile gram-negative species, no viable cells were retained even at high cell densities of between 10(7) and 10(8) colony forming units (cfu) ml(-1), and for the most robust species such as spore-formers and acid-fast bacteria, complete inactivation was achieved at cell densities ranging between 10(1) and 10(4) cfu ml(-1). The inactivation of bacterial cells on FTA cards suggest that this is a safe medium for the storage and transport of bacterial nucleic acids.     

Single-wall carbon nanotubes with adsorbed antibodies detect live breast cancer cells

Monoclonal antibodies (mAb) specific to cell surface antigens overexpressed on cancer cells adsorbed to single-wall carbon nanotube (SWCNT) devices can bind to their antigens in a drop of buffer, resulting in a slight drop in conductance. Here we report detection of live breast cancer cells with a mAb-SWCNT device. We adsorbed mAb specific to insulin-like growth factor 1 receptor (IGF1R) onto interconnected SWCNT networks placed between lithographically patterned electrodes. Application of human BT474 breast cancer cells increased the conductance of the IGF1R-specific mAb-SWCNT devices by 3.0±0.1-fold, relative to nanotube devices with non specific mAb. Human MCF7 breast cancer cells, with greater IGF1R expression, increased the conductance by 8.0±0.2-fold, but R-cells lacking IGF1R did not. Receptor-specific mAb acted as specific nanoswitches that completed a circuit between the SWCNT and the cell surface receptors, elevating the device conductance. Such devices might detect circulating breast cancer cells in blood samples.     

A new photobioreactor for continuous marennin production with a marine diatom: influence of the light intensity and the immobilised-cell matrix (alginate beads or agar layer)

In oyster ponds, the marine diatom Haslea ostrearia synthesises and excretes a hydrosoluble pigment of commercial interest called marennin. During the benthic stage, when algal cells are naturally immobilised in their own polysaccharides, marennin production is higher. To optimise this production, axenic cultures of H. ostrearia were immobilised in a polysaccharidic matrix (alginate or agar) and introduced into a new photobioreactor device for continuous marennin production. Solute diffusion was improved using an alginate beads monolayer, leading to higher levels of cell growth (a 2-fold higher cell concentration) and marennin productivity (7.57-8.80 mg day(-1) l(-1)). An increase in the light intensity (from 3.0 to 8.5x10(16) quanta cm(-2) s(-1)) led to an earlier and 1.3-fold higher production of marennin. However, the higher light intensity led to a higher rate of cell death [0.29 instead of 0.40 ng chlorophyll a (10(6) cells)(-1)]. Due to the secondary nature of marennin metabolism, it would be necessary to alternate between culture conditions favouring cell growth (moderate light intensity and no limiting nitrate supply) and those promoting marennin production (high light intensity and limiting nitrate supply).     

Measurement of protein using an electrochemical bi-enzyme sensor.

A screen-printed three-electrode amperometric biosensor for the rapid and quantitative measurement of single protein solutions is described. A membrane immobilised protease preparation of broad specificity was used to digest sample protein liberating free amino acids that were subsequently oxidised at a working electrode by immobilised L-amino acid oxidase (L-AAO). The enzymatically generated hydrogen peroxide was determined amperometrically. The fully optimised device required 30 mU L-AAO and 3.94 U protease and had a limit of detection of 170 microg ml(-1) and linearity of response up to 1 mg ml(-1) for Casilan 90 protein. The analytical performance of the device was comparable to that of a commercially available standard photometric protein test kit and required only a 10 microl volume of sample and a single dilution step. Unlike with photometry, the sensor is able to determine the protein content of turbid samples and hence should find widespread applications. The device was simple to use, low-cost and could be mass-produced, yielding results within 4 min of sample addition with acceptable assay repeatability.     

Optimum design of a series of continuous stirred tank reactors containing immobilised growing cells

The optimum design of a series of continuously operated stirred-tank reactors containing immobilised growing cells is described. Optimal design is defined as the minimal total holding time over the reactor series to achieve a certain degree of conversion. The analysis is made under the assumptions that there is a constant and equal concentration of immobilised biomass in all bioreactors along the series, no diffusion limitation takes place, all growth of the immobilised biomass will lead to an increase in suspended biomass, and that maintenance of the immobilised cells can be neglected. It is shown that the use of more than three bioreactors in series is likely to be de trop.     

Combined immobilized cultures producing fibrinolytic proteinases

The authors obtained combined immobilised systems composed of a culture producing fibrinolytic proteinases and a stimulating strain. The optimal ratio between the two cultures in gel was selected at a high starting cell density. Highly stable immobilised cultures were produced by growing the cells in gel particles. The interrelationship of the partners was studied in the binary immobilised culture. The biosynthetic activity of the system fell down to the level of a monoculture when the cells of the stimulating strain were eliminated from gel. The producing and stimulating strains are at equilibrium in associative immobilised cultures obtained by growing the cells in gel, and Arthrobacter is not eliminated. The mechanism of biosynthesis stimulation in a combined immobilised culture has been studied. Apparently, the procedure of immobilisation and the action of a stimulating compound exert the synergistic effect.     

Design of an automated bioreactor system to screen immobilised whole cell catalysts

An automated CSTR system has been developed to study the stability of immobilised whole cell biocatalysts for ammonium acrylate production. Two potentially useful amidase-active rhodococci have been identified: One possesses an amidase of much higher activity than the other but of much lower stability. The activity and stability of each biocatalyst over a range of temperatures has been determined and used to compare the productivity of the biocatalysts in a bioconversion.     

A novel urea sensitive biosensor with extended dynamic range based on recombinant urease and ISFETs

A novel urea biosensor based on immobilised recombinant urease as sensitive element and ion sensitive field effect transistor as transducer was developed. Recombinant urease from E. coli with an increased Km was photoimmobilised in PVA/SbQ (poly(vinyl alcohol) containing styrylpyridinium) membrane and has demonstrated quite good performance as biosensitive element. Enzymatic field effect transistors based on such a bioselective element were studied in model buffer solutions. This biosensor demonstrated an extended dynamic range up to 80 mM, a quite good reproducibility (standard deviation of the sensor responses was approximately 2.5%, n= 20 for urea concentration 10 mM) and a high stability. Such characteristics fit with the analytical requirements needed for urea control in plasma and liquids used during renal dialysis.     

Growth of immobilised plant cells in reticulate polyurethane foam matrices

Summary An inoculum of initially freely suspended cell aggregates ofCapsicum frutescens was immobilised in porous polyurethane foam matrices. Subsequent growth and substrate consumption of these immobilised cells in batch culture were measured and compared with those of suspension cultures. The results showed that the maximum specific growth rate of freely suspended cells was slightly higher than that of immobilised cells but the overall growth patterns and final cell yields were similar.     

A novel full-scale flat membrane bioreactor utilizing porcine hepatocytes: cell viability and tissue-specific functions

When designing an extracorporeal hybrid liver support device, special attention should be paid to providing the architectural basis for reconstructing a proper cellular microenvironment that ensures highest and prolonged functional activity of the liver cells. The common goal is to achieve high cell density culture and to design the bioreactor for full-scale primary liver cell cultures under adequate mass transfer conditions. An important aim of this study was to evaluate the biochemical performance of a flat membrane bioreactor that permits high-density hepatocyte culture and simultaneously to culture cells under sufficient oxygenation availability conditions comparable to the in vivo-like microenvironment. In such a bioreactor pig liver cells were cultured within an extracellular matrix between oxygen-permeable flat-sheet membranes. In this investigation we used a novel scaled-up prototype consisting of up to 20 modules in a parallel mode. Each module was seeded with 2 x 10(8) cells. Microscopic examination of the hepatocytes revealed morphological characteristics as found in vivo. Cell concentration increased in the first days of culture, as indicated by DNA measurements. The performance of the bioreactor was monitored for 18 days in terms of albumin synthesis, urea synthesis, ammonia elimination, and diazepam metabolism. The ability of the hepatocytes to synthesize albumin and urea increased during the first days of culture. Higher rates of albumin synthesis were obtained at day 9 and remained at a value of 1.41 pg/h/cell until day 18 of culture. The rate of urea synthesis increased from 23 ng/h/cell to 28 ng/h/cell and then remained constant. Cells eliminated ammonia at a rate of about 56 pg/h/cell, which was constant over the experimental period. Hepatocytes in the bioreactor metabolized diazepam and generated three different metabolites: nordiazepam, temazepam, and oxazepam. The production of such metabolites was sustained until 18 days of culture. These results demonstrated that the scale-up of the bioreactor was assessed, and it could be demonstrated that the device design aimed at the reconstruction of the liver-specific tissue architecture supported the expression of liver-specific functions of primary pig liver cells.     

The dynamic performance of an immobilised-urease bioreactor in a recycle loop

Use of immobilised urease is a promising alternative for the removal of urea from blood plasma in association with an artificial kidney device. In such a device, carrier particles containing the immobilised enzyme are retained within an extracorporeal vessel through which blood perfuses. During the operation of the system, urea diffuses into the immobilisation matrix where it is hydrolysed by urease. This system is intrinsically dynamic, since the urea concentration changes continuously with time as the perfusing blood is progressively cleared of urea. Its design and optimisation is therefore a significant technical challenge. This paper presents a model for and a simulation study of the continuous operation of an immobilised urease artificial kidney device operating, in fluidized bed mode, in a recycle loop. The partial differential equations that describe the system account for axial backmixing, intraparticle and external mass transfer resistances and intraparticle urea hydrolysis. The performed simulations reveal the effect of key parameters, such as the liquid recirculation rate and the size of the enzyme carriers on the performance of the system. Based on those, optimum operating conditions for maximum efficiency have been determined. The presented mathematical model and methodology is of general nature and thus suitable for the design and optimisation of a variety of dynamic (batch or semi-batch) biochemical systems.List of Symbols B _m dimensionless number defined as B _m=k _eR/D_eff - C _L urea concentration in the bulk liquid - C _R urea concentration at the particle surface - C _R ^L urea concentration at the inner side of the stagnant film surrounding the particle; C _R=C _R ^L / - C _p intraparticle urea concentration - D _eff, D effective intraparticle diffusivity of urea - D _L axial dispersion coefficient in the bioreactor - F volumetric flowrate - k reaction rate constant - k _e external mass transfer coefficient - k _n parameter, k _n=D _eff(n/R)² - L bioreactor length - Pe Peclet number, defined as Pe=(uL/D _L) - R particle radius (2R=D _P) - R _h instantaneous urea hydrolysis rate - u axial superficial velocity in the reactor - V reactor volume - X dimensionless length Greek Letters partition coefficient - bed voidage - integration variable - dimensionless time; = tF/V     

Plasmodium falciparum polypeptides interacting with human red cell membranes show high affinity binding to Band-3

P. falciparum proteins were labelled with [35S]methionine and harvested at various asexual stages. A number of parasite proteins bound to uninfected red cell membranes (ghosts). Some of these proteins differentially partitioned when ghosts were extracted with detergent. Several of these proteins bound very strongly to immobilised whole ghost proteins or immobilised purified Band-3 in a stage-specific manner, but not to a sham-coupled matrix or to immobilised Band-3 extract from cells rendered refractory to invasion. Such specific binding of parasite proteins to immobilised Band-3 supports recent conjecture as to its role as a host receptor during parasite invasion. However, our results demonstrate the complex and multifactorial nature of the interaction between parasite and host proteins during invasion and development.     

Passive sodium movements across the opercular epithelium: The paracellular shunt pathway and ionic conductance

Summary The unidirectional Na⁺, Cl^–, and urea fluxes across isolated opercular epithelia from seawater-adaptedFundulus heteroclitus were measured under different experimental conditions. The mean Na⁺, Cl^–, and urea permeabilities were 9.30×10^–6 cm·sec^–1, 1.24×10^–6 cm·sec^–1, and 5.05×10^–7 cm·sec^–1, respectively. The responses of the unidirectional Na⁺ fluxes and the Cl^– influx (mucosa to serosa) to voltage clamping were characteristic of passively moving ions traversing only one rate-limiting barrier. The Na⁺ conductance varied linearly with, and comprised a mean 54% of, the total tissue ionic conductance. The Cl^– influx and the urea fluxes were independent of the tissue conductance. Triaminopyrimidine (TAP) reduced the Na⁺ fluxes and tissue conductance over 70%, while having no effect on the Cl^– influx or urea fluxes. Mucosal Na⁺ substitution reduced the Na⁺ permeability 60% and the tissue conductance 76%, but had no effect on the Cl^– influx or the urea fluxes. Both the Na⁺ and Cl^– influxes were unaffected by respective serosal substitutions, indicating the lack of any Na⁺/Na⁺ and Cl^–/Cl^– exchange diffusion.The results suggest that the unidirectional Na⁺ fluxes are simple passive fluxes proceeding extracellularly (i.e., movement through a cation-selective paracellular shunt). This pathway is dependent on mucosal (external) Na⁺, independent of serosal (internal) Na⁺, and may be distinct from the transepithelial Cl^– and urea pathways.