Functional Organic Material
Highly stable molecular layers prepared by the selfassembling method have been used for the development of electrochemical, optical, and various other detection systems. Self-assembled monolayers (SAMs) are crystalline, chemisorbed, organic single layers formed on a solid substrate by the spontaneous organization of molecules. Thiol compounds and gold is a well established combination1). Carboxylic acids, organosilicon derivatives, and diphosphonates on various metal oxide surfaces have also been explored in recent years in an effort to find a good model for such adhesive processes (Fig. 1). SAMs are easily modified at the single molecular and assembled levels. They are very useful research models to promote our understanding of the self organization mechanism of molecules, molecular structure and property relationships, and phenomena at the interface between different phases. The high flexibility of SAMs has allowed us to study the electron transfer mechanism of proteins, molecular layers, and biosensors.
Self-Assembling Process of Alkanelthiols
self-assembling process of alkanethiols on gold is initiated by the strong chemical interactions between the sulfur and gold surface. This interaction is a result of chemisorption that forces the thiolate molecule to adsorb to a gold lattice. The tail-to-tail interactions of the alkanethiolate molecules (created by lateral, interchain, nonbonded interactions, such as van der Waals, steric, repulsive, and electrostatic forces), are strong enough that the molecules align parallel on the gold surface and create a crystalline film.1,2) (Fig. 2). Therefore, the packing and ordering of molecules is controlled by a chemisorption mechanism.3,4) In practice, the solid surface is simply dipped into a solution containing adsorbing molecules. Organic disulfides, thiols, and sulfides are widely used for the preparation of stable SAMs on gold surfaces. The selfassembling process and the orientation of the molecular layer on a gold surface have been investigated thoroughly using Fourier transform infrared spectroscopy (FT-IR),5,6) scanning tunneling microscopy (STM),1) atomic force microscopy (AFM),7) X-ray photoelectron spectroscopy (XPS),8,9) electrochemistry, 4,10) Raman spectroscopy,11) Ellipsometry,12,13) and quartz crystal microbalance (QCM).14,15) Please refer to the papers by Dr. Ulman for extensive reviews about the selfassembly process.3),4)
Electrochemical Sensing by SAMs-Modified Electrodes
A common application of SAMs is in the creation of sensors with molecular recognition properties. Many groups have studied the electrochemical characteristics of alkylthiols for ion detection and molecular recognition. For example, Turyan and others used SAMs composed of ω-mercapto-carboxylic acids on mercury film and gold electrodes for very sensitive and selective analyses of cadmium(II).16) Taniguchi and others created a membrane model with molecular gating by incorporating Meldola’s Blue into self-assembled decanethiol monolayer-coated electrodes.17) Katayama and Maeda reported the electrochemical detection of cyclic AMP by a 17-mer oligopeptide-coated gold electrode. They showed that this response was dependent on the cyclic AMP concentration, but not ATP, using cyclic voltammograms of ferrocyanide/ ferricyanide redox coupled with the electrode.18) Wang and others reviewed the behavior, utility, and advantages of an amperometric flow detector coated with unsubstituted n-alkylthiols. They indicated that a hydrophilic alkylthiol monolayer has a high selectivity toward lipophilic drugs such as chloropromazine and dipamine.19)
Detection of Histidine-Tagged Protein Using NTA-Attached SAMs
The use of a short peptide as an affinity tag is one of the most common methods for the detection and purification of recombinant proteins. These tag proteins are mostly antibody epitopes that are detected with their antibodies.20) Sigal and others prepared a self-assembled monolayer that selectively binds protein with a stretch of six histidines (His-tag). They prepared two alkanethiols, one with a nitrilotriacetic acid (NTA) group that forms a tetravalent chelate with Ni(II) ion and the other with a triethyleneglycol group that is capable of avoiding nonspecific adsorption of protein (Fig. 3). This membrane can only recognize a His-tag protein through the nickel(II) ion chelated with NTA on the SAM. This technique is useful for immobilization of His-tag proteins for study using surface plasmon resonance (SPR).21)
Surface Plasmon Resonance Studies for Interactions of SAMs and Proteins
Surface plasmon resonance (SPR) is commonly used to measure the kinetics of association and dissociation of ligands and proteins in aqueous solution. It is particularly powerful for the observation of processes occurring at or near interfaces. The sensing element is a thin (40-50 nm) gold or silver film deposited on a glass surface. The back of the gold-coated glass slide is irradiated with p-polarized light, with the reflection angles controlled to minimize the intensity of the reflection. Since the value of this reflection angle linearly depends on the amount of protein adsorbed on the surface, the protein can be monitored by SPR (Fig. 4).20-22)
Mrksich and others studied the thermodynamic and kinetic mechanism between benzenesulfonamide-attached SAM and bovine carbonic anhydrase (EC 188.8.131.52) using the SPR technique.22,23) Ringsdorf and others prepared protein triple layers on biotin-attached SAMs on gold surface using streptavidin and anti-chorionic gonadotropin-Fab (anti-hCGFab) fragments (Fig. 5). They investigated the hinge, or linkage region, of the Fab fragment; the second layer formation (streptavidin, Fab fragment); the third layer formation by antigen hCG; and quantification of these processes. SPR coupled with SAM is an excellent method for determining surface phenomena. The SPR method has been used for the determination of epitopes of monoclonal antibodies, development of immuno-detection systems, research on signal transfer mechanisms, and other studies.
Electrochemical Studies of Proteins on SAMs-Modified Electrodes
Protein-coated electrodes provide suitable systems for the development of devices using protein layer interfaces.24) Cytochrome c, ferredoxin, and myoglobin are particularly interesting proteins for interfacial electrochemical studies. For example, Niki’s group has been studying diffusionless standard electron transfer rate constants of cytochrome c immobilized on a carboxylic acid-attached SAM with an electroreflectance spectroscope.25) Several researchers have used electrochemical techniques for characterizing the absorption of poly(L-lysine)-coated SAMs. Poly(L-lysine) was fixed to carboxylic acid-attached SAMs through an electrostatic binding between a negative charge of carboxylate and a positive charge of amine residue. The poly(L-lysine)-coated SAMs were used to develop a detection system for glucose and for research on the electron transfer mechanism of cytochrome c.24),26),27),28) Nakashima’s group prepared polyethyleneglycolattached SAMs and reported that a supramolecular structure was formed by the interaction between poly(ethyleneglycol) and acyclodextrin.29)
DNA Sensor Using Electrochemical and Quartz Crystal Microbalance Method
Electrochemical DNA sensors may be useful devices for the sequence-specific detection and quantification of DNA or RNA in solutions. The amount of DNA or RNA in solution can be measured as an amperometric or voltammetric signal.24) Katayama and others prepared a calf thymus DNA-coated gold electrode to detect anti-DNA antibody. They demonstrated that this system could be useful for the development of biosensors for DNA-binding proteins.30) Okahata’s group used frequency changes in quartz crystal microbalance (QCM) to detect oneto- one hybridization between oligonucleotides immobilized on gold electrodes of the QCM and target M13 phage DNA in aqueous solution. They prepared a 10-mer deoxynucleotide with a mercaptopropyl group at the 5’-phosphate end whose sequence was complementary with the EcoR1 binding site of single-stranded M13 phage DNA.31,32) The QCM method is very sensitive because its resonance frequency decreases upon the increase of the mass on the QCM. The QCM method is useful for the study of molecular kinetics of base-pair hybridization in oligonucleotides and to detect various biological materials.
Table 1 Solubility Data
1. C. Schonenberger, J. Jorritsma, J. A. M. Sondag-Huethorst and L. G. J. Fokkink, J. Phys. Chem., 1995, 99, 3259.
2. A. Ulman, “Introduction to Ultrathin Organic Films, San Diego”, Academic Press, 1991.
3. A. Ulman, MRS Bulletin, 1995, 46.
4. Y. Sato, S. Ye, T. Haba and K. Uosaki, Langmuir, 1996, 12, 2726.
5. Y. Sato, B. L. Frey, R. M. Corn and K. Uosaki, Bull. Chem. Soc. Jpn., 1994, 67, 21.
6. J. L. Wibur, Langmuir, 1995,11, 825.
7. C. D. Bain and G. M. Whitesides, J. Am. Chem. Soc., 1998, 110, 3665.
8. P. E. Laibinis, C. D. Bain and G. M. Whitesides, J. Phys. Chem., 1991, 95, 7017.
9. C. A. Widrig, C. Chung and M. D. Porter, J. Electroanal. Chem., 1991, 310, 335-359.
10. M. A. Bryan and J. E. Pemberton, J. Am. Chem. Soc., 1991, 113, 8284.
11. C. E. D. Chidsey and D. N. Loiacono, Langmuir, 1990, 6, 682.
12. T. Ohtsuka, Y. Sato and K. Uosaki, Langmuir, 1994, 10, 3658.
13. T. W. Schneider and D. A. Buttry, J. Am. Chem. Soc., 1993, 115, 12391.
14. I. Turyan and D. Mandler, Anal. Chem., 1994, 66, 58.
15. J. Wang, H. Wu and L. Angnes, Anal. Chem., 1993, 65, 1893.
16. S. Hashimoto, Bunseki, 1997, 5, 362.
17. G. B. Sigal, C. Bamdad, A. Barberis, J. Strominger and G. M. Whitesides, Anal. Chem., 1996, 68, 490.
18. M. Mrksich, J. Grunwell and G. J. Whitesides, J. Am. Chem. Soc., 1995, 117, 12009.
19. M. Mrksich, G. Sigal and G. Whitesides, Langmuir, 1995, 11, 4383.
20. J. L. Anderson and E. F. Bowden, Pickup, P. G. Anal. Chem., 1996, 68, 379R.
21. Z. Q. Feng, S. Imabayashi, T. Kakiuchi and K. Niki, J. Electroanal. Chem., 1995, 394, 149.
22. C. E. Jordan, B. L. Frey, S. Kornguth and R. Corn, Langmuir, 1994, 10, 3642.
23. J. D. H. Glenn and E. F. Bowden, Chem. Lett., 1996, 399.
24. F. Mizutani, Y. Sato, S. Yabuki and Y. Hirata, Chem. Lett., 1996, 251.
25. N. Nakashima, Y. Miyata and M. Tominaga, Chem. Lett., 1996, 731.
26. Y. Okahata, Y. Matsunobu, K. Ijiro, M. Mukai, A. Murakami and K. Makino, J. Am. Chem. Soc., 1992, 114, 8299.
- Alkanethiol Derivative
Code Product name Unit size A423 Self Assembled Monolayer Reagent
A424 Self Assembled Monolayer Reagent
A425 Self Assembled Monolayer Reagent
A458 Self Assembled Monolayer Reagent
A483 Self Assembled Monolayer Reagent
10 mg A505 Self Assembled Monolayer Reagent
10 mg A515 Self Assembled Monolayer Kit
Amine Coupling Kit
2 ml x 4 B564 Self Assembled Monolayer Reagent
Biotin-SAM Formation Reagent
1 μmol x3 C385 Self Assembled Monolayer Reagent
C386 Self Assembled Monolayer Reagent
C387 Self Assembled Monolayer Reagent
C429 Self Assembled Monolayer Reagent
C445 Self Assembled Monolayer Reagent
C463 Self Assembled Monolayer Reagent
10 mg C488 Self Assembled Monolayer Reagent
Carboxylic acid-SAM Formation Reagent
1 μmol x3 D537 Cross-Linker
10 mg D550 Chelate Labeling Reagent
F246 Self Assembled Monolayer(SAM)研究用試薬
F247 Self Assembled Monolayer Reagent
F269 Self Assembled Monolayer Reagent
H337 Self Assembled Monolayer Reagent
10 mg H338 Self Assembled Monolayer Reagent
10 mg H339 Self Assembled Monolayer Reagent
10 mg H354 Self Assembled Monolayer Reagent
H355 Self Assembled Monolayer Reagent
H394 Self Assembled Monolayer Reagent
10 mg H395 Self Assembled Monolayer Reagent
10 mg H396 Self Assembled Monolayer Reagent
10 mg N475 Self Assembled Monolayer Reagent
NTA-SAM Formation Reagent
2 μmol x3 S350 Self Assembled Monolayer Reagent
- Phosphonic Acid Derivatives
Code Product name Unit size A517 Self Assembled Monolayer Reagent
C490 Self Assembled Monolayer Reagent
F329 Self Assembled Monolayer Reagent
F330 Self Assembled Monolayer Reagent
F340 Self Assembled Monolayer Reagent
H399 Self Assembled Monolayer Reagent
M457 Self Assembled Monolayer Reagent
O407 Self Assembled Monolayer Reagent