Supported bilayer lipid membranes modified with a phosphate ionophore.

This article reports the electrical responses of a phosphate ionophore, the cyclic polyamine 3-decyl-1,5,8-triazacyclodecane-2,4-dione (N3-cyclic amine) incorporated into metal supported bilayer lipid membranes (s-BLM). Teflon coated silver wire was used as a support. In a potentiometric mode, the ionophore had a response that was linearly related to the logarithm of HPO4(2-) concentration and was also dependant on pH. Selectivity coefficients for other anions compared to HPO4(2-) ions, determined by the separate solution method, fell within the range 1.73 x 10(-4) to 6.38 x 10(-2).

Molecular recognition in a reconstituted tumor cell membrane.

The design of an immunoliposome system for molecular recognition using reconstituted, hydrogel-supported bilayer lipid membranes (sb-BLMs) is described. By monitoring the electrical properties, two kinds of recognition are feasible: (i) the human bladder tumor cells, Ej and its antibody BDI-1, the lifetime of the reconstituted membrane is 42 min; and (ii) the human rectum tumor cells, LOVO, the life of the reconstructed membrane is more than 40 min, the same as conventional BLM. Further, the anticancer drug, Adriamycin (Anticancer Res., 20 (2000) 1391), was shown to be effective in such reconstituted systems, the life of which is less than 5 min. In these experiments, the active ingredients of the Ej and LOVO cells were determined on reconstituted sb-BLMs. The key point is that the component part being recognized on the BLM must be kept in its native state.

Photoelectric measurements of s-BLM/nucleoli: a new technique for studying apoptosis.

A new method based on photoelectric measurement for analyzing apoptosis of cell-free MCF-7 nucleoli is reported. Supported bilayer lipid membrane (s-BLM) was used to enclose nucleoli in biological environment. The s-BLM was self-assembled on the wall of a super-thin cell. During the apoptosis induced by Taxol, the photoelectric current of the self-assembled s-BLM/nucleoli was found decreasing with time, suggesting the degradation of nucleus DNA. Electron transfer along the DNA double helix and along nuclear skeleton is assumed in the interpretation. This novel photoelectric analytical method may provide a rapid and sensitive technique to evaluate apoptosis.

The preparation and drug-release behaviour of CTA/EC and PMS/EC composite microcapsules.

A cellulose triacetate (CTA) and three different molecular weights of poly(alpha-methyl styrene) (PMS) were used as co-wall materials to prepare composite microcapsules with ethylcellulose (EC). A non-solvent-addition phase-separation method was used. The core material was theophylline (TH) and the solvent-non-solvent pair was dichloromethane-n-hexane, and the drug-release rates of the microcapsules prepared from these two types of co-wall materials were compared. The effects of their phase-separation range on the properties of the microcapsules, such as particle size, release rate and the morphology of the microcapsules are also discussed. The release rate of microcapsules was also affected by the compatibility of the co-wall materials and the EC. The dissolution studies indicated that the drug-release time of CTA/EC and PMS/EC composite microcapsules was sustained to 10 and 3.5 times, respectively, in comparison with that for pure EC microcapsules.

Fabrication and photoelectric properties of self-assembled bilayer lipid membranes on conducting glass.

Supported bilayer lipid membranes (s-BLMs with and without the doping of fullerene C60) self-assembled on indium-tin oxide (ITO) glass were fabricated and characterized by cyclic voltammetry and electrochemical impedance spectroscopy using a three-electrode system. The photoelectric properties of the ITO supported planar lipid bilayers were studied. Light intensity of irradiation, bias voltage, and concentration of donors have been found to be limiting factors of the transmembrane photocurrent. The facilitation effect of C60 doping in s-BLMs on the photoinduced electron transfer across s-BLM is discussed. This novel self-assembled ITO/s-BLM system may provide a simple and mechanically stable model for the study of the photoelectric and photodynamic properties of biomembranes.

Charge-transfer processes and redox reactions in planar lipid monolayers and bilayers.

Supported bilayer lipid membranes (BLMs) and lipid monolayers have been known for quite sometime and are attracting sustained interest since they open new research vista and offer practical approaches in biosensor development and molecular device applications. Central to these areas of interest are electric processes and redox reactions where the movement of ions and electrons plays a pivotal role. In this paper an overview of the major findings in this field is presented. Further, we summarize the work on planar lipid bilayers and monolayers that have been done in the past few years in a number of laboratories. Supported planar BLMs and their closely related systems provide the foundation for a variety of lipid bilayer-based molecular sensors that are sensitive, versatile, as well as potentially inexpensive (i.e., disposable), and open to all sorts of experimentation.

Voltammetric study of charge transfer across supported bilayer lipid membranes (s-BLMs).

Stable bilayer lipid membranes on a metal support (s-BLMs) and on an agar gel salt bridge (sb-BLMs) have been formed and their potential usefulness as practical sensors demonstrated. This paper presents the preparation method of s-BLMs and sb-BLMs, and the application of cyclic voltammetry (CV) to their investigation. The instrument and data analysis of the CV are described. The application of CV to the C60-doped BLM system is presented. This technique is a basis for biosensor development, and a useful tool for membrane research.

A self-assembled pigmented BLM on a platinum support: the light-induced electrical effects.

The light-induced voltage and current changes under continuous illumination have been investigated in pigmented self-assembled lipid bilayer membranes deposited on a platinum electrode. Such self-organized pigmented bilayer-platinum system containing Zn-Phthalocyanine (ZnPc) as a photosensitizer and glycerol-dioleate (GDO) as a bilayer forming solution has been found to shift its electrode potential to more positive value on light irradiation as well as to increase the cathodic current across the membrane. The results indicate a direct electron transfer from the platinum electrode to hydrogen ion in the electrolyte solution. Furthermore, it has also been demonstrated a dramatic increase of the photocurrent over the time course of BLM formation visualizing a role of the bulk quenching processes which are significantly diminished in thin bilayer membrane.

Formation of a bilayer lipid membrane on rigid supports: an approach to BLM-based biosensors.

Sensory transduction in living cells is thought to involve a change of electrical parameters at the receptor membrane following specific binding events at the membrane surface. Because of the complexity of the biomembrane structure and the environmental factors associated with it, experimental bilayer lipid membranes (BLMs) have been employed for elucidation of processes at the membrane level. This is because the BLM system can be easily probed by a host of powerful and sensitive electrochemical methods. Further, recent advances in microelectronics and biotechnology suggest that the development of a BLM-based electrochemical biosensor may be possible. This paper describes the use of bilayer lipid membranes on solid substrates for analysis of sensor development problems, with relevance to a possible novel type of biomolecular device. Some electrical parameters of the new structure were measured and compared to usual BLM results. The advantages of the self-assembled structure, together with the measuring system, are discussed in terms of stability and sensitivity.

Lipid bilayer-based sensors and biomolecular electronics.

The lipid bilayer postulated as the basic structural matrix of biological membranes is widely accepted. Experiments in the early 1960s have made direct studies of lipid bilayers possible. At present, the planar bilayer lipid membrane (BLM) together with spherical lipid bilayers (liposomes), upon suitable modification, serves as a most appropriate model for biological membranes. In recent years, advances in microelectronics and interest in ultrathin organic films, including BLMs, have resulted in a unique fusion of ideas toward the development of biosensors and transducers. Furthermore, recent trends in interdisciplinary studies in chemistry, electronics, and biology have led to a new field of research: biomolecular electronics. This exciting new field of scientific-technological endeavor is part of a more general approach toward the development of a new, postsemiconductor electronic technology, namely, molecular electronics with a long-term goal of molecular computers. Experimental BLMs have been mainly used in the past as models of biological membranes. The methods of BLM studies may not be familiar to those outside biomedical research. Therefore, a brief description of the experimental techniques will be given in Section IV. Recently, it has been demonstrated that BLMs, after suitable modification, can function as electrodes and exhibit nonlinear electronic properties. These and other experimental findings relevant to sensor development and to "biomolecular electronic devices" (BED) will be covered in Section V, after a brief description of biomembranes which have been suggested as nature's molecular devices (Section III). In the last section, the potential use of the BLM system together with its modifications in the development of a new class of organic diodes, switches, biosensors, electrochemical photocells, and biofuel cells will be presented (Section VI). Additionally, this paper, besides presenting a review of our work and those of others on BLMs and liposomes in relation to biosensors and molecular electronics, reports a novel technique for obtaining BLMs (or lipid bilayers) on solid supports. The presence of solid support on one side of the BLM greatly enhances its mechanical stability, while retaining the dynamic properties of the lipid bilayer. Advantages of the new technique for self-assembling amphiphilic molecules on rigid substrates are discussed in terms of their possible uses. That is, the new BLM system (s-BLMs) is potentially useful for technological applications in the area of biosensors, enzyme electrodes, and molecular electronics as well as biochips (Section IV.C). The dividing line between the present microscopic and the future molecular electronics is 1 micron.(ABSTRACT TRUNCATED AT 400 WORDS)

Self-assembling bilayer lipid membranes on solid support.

Solid-supported bilayer lipid membranes (s-BLMs) that possess some properties similar to those of conventional BLMs can be self-assembled on a freshly cleaved metal wire by a two-step procedure: (i) The tip of a Teflon-coated platinum wire, while immersed in a lipid solution, is cut off with a scalpel; (ii) the new tip of the wire, having become coated with lipid solution, is transferred into 0.1 M KCl. After a few minutes, a stable lipid bilayer forms spontaneously on the tip of the wire, as verified by electrical measurements. An application of such a supported BLM (s-BLM) is reported for the detection of Pb2+ ions. The s-BLM is liquid-crystalline in structure, which makes it amenable to modification for basic studies, as well as for technological applications such as biosensors and molecular electronic devices.

Deposition of a photosensitive complex within a lecithin bilayer lipid membrane.

In this paper the phenomenon of a photosensitive ion complex of Brilliant Yellow and ferric ions formation in the electrolyte phase and its subsequent deposition within a bilayer lipid membrane (BLM) is described. Deposition of light sensitive complex into the BLM considerably increases its mechanical stability and drastically changes its electrochemical and photoelectrical properties as well.

Hydrogen generation from artificial sea water in a semiconductor septum electrochemical photovoltaic cell.

Visible light of the solar spectrum is directly converted to stored chemical energy of hydrogen from artificial sea water in a novel electrochemical photovoltaic cell. The principal element of the cell, modeled after the photosynthetic thylakoid membrane, is a semiconductor septum made of polycrystalline n-CdSe thin film deposited on nickel foil, which separates two aqueous solutions. Under short-circuit conditions, vigorous hydrogen evolution was seen at the Ni surface and continued as long as the cell was operated. The novel cell, the concept of which was derived from pigmented bilayer lipid membrane studies, is easy to construct, simple to operate, and appears to be a practical approach to the photochemical conversion and storage of solar energy.

Influence of dolichyl phosphate on permeability and stability of bilayer lipid membranes.

The ionic permeability coefficients, ionic transference numbers, activation energy of ion transport and breakdown voltage of bilayer lipid membranes made from dioleoylphosphatidylcholine or its mixtures with dolichyl 12-phosphate have been studied. The electrical measurements showed that dolichyl phosphate in phospholipid bilayers decreases membrane permeability, changes membrane ionic selectivity and increases membrane stability. These results are discussed in light of the aggregation behavior and the intramolecular clustering of a dolichyl phosphate molecule in phospholipid membranes. From our data we suggest that the hydrophilic part of dolichyl phosphate molecules regulates their behavior in membranes.

Ca2+ channels from brain microsomal membranes reconstituted in patch-clamped bilayers.

Single Ca2+ channels from brain microsomal membranes were reconstituted in bilayers made at the tips of patch-clamp micropipettes. The single-channel conductance was defined to be 107 pS in 50 mM Ca2+. The channel activity was stimulated by nucleotides and inositol 1,4,5-trisphosphate (Ins-P3), and was inhibited by ruthenium red. Na+ added asymmetrically to the membrane bilayer induced an increase in the Ca2+-channel activity. The described characteristics of these Ca2+ channels suggest that they may be responsible for the Ca2+ transport across the membranes of the endoplasmic reticulum system triggering and modulating various neurosecretory and excitatory processes in nerve cells.

Changes in calcium channel activity in membranes from cis-diammine-dichloroplatinum(II)-resistant and -sensitive L1210 cells.

Ca2+ channels from lipid and proteolipid fractions of cisplatin-sensitive and cisplatin-resistant cells were reconstituted and characterized in bilayer lipid membranes formed at the tips of patch-clamp micropipets. The characteristics of the Ca2+ channels were typical for the endoplasmic reticulum membrane channel activity. They had a relatively large unit conductance and were modified by typical activators (nucleotides) and inhibitors (ruthenium red, verapamil). Different doses of nifedipine did not inhibit Ca2+ channel activity. A substantial difference between the single-channel properties of the two types of investigated membranes was observed. The mean open time and the open state probability of channels reconstituted in bilayer lipid membranes from the membrane components of cisplatin-resistant cells were larger than those in bilayer lipid membranes made from components of cisplatin-sensitive cells. Ruthenium red (7 X 10(-7) M) inhibited the channel activity in both types of membranes to the same level. The observed effects could be related to an increased Ca2+ release from the intracellular Ca2+ stores (endoplasmic reticulum system) accompanied by an enhanced intracytoplasmic Ca2+ concentration in cisplatin-resistant cells. These changes in the Ca2+ concentration level may be responsible for the higher antitumor drug efflux rate and the development of the drug resistance. The suggestion is made that specific inhibitors of the Ca2+ transport across the membranes of the subcellular Ca2+-storing organelles may be tested as agents for overcoming the antitumor drug resistance.

Cell-mediated tumor-killing effect studied by using bilayer lipid membranes.

The bilayer lipid membrane (BLM) system was used to investigate the tumor killing effect of natural killer (NK) cells under various experimental conditions. It was found that NK cells interact specifically with BLMs made from lipids and proteolipids isolated from target K562 cells inducing an increase of the membrane conductance. This effect was more pronounced when the NK cells were pretreated with interferon. A similar effect was observed when NK cells were pretreated with sodium selenite. The results suggest that changes in membrane conductance and permeability are involved in the mechanism of the tumor-killing effect mediated by NK cells.