WO1998001221A1 - Electrochemical solid phase synthesis of polymers - Google Patents
Electrochemical solid phase synthesis of polymers Download PDFInfo
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- WO1998001221A1 WO1998001221A1 PCT/US1997/011463 US9711463W WO9801221A1 WO 1998001221 A1 WO1998001221 A1 WO 1998001221A1 US 9711463 W US9711463 W US 9711463W WO 9801221 A1 WO9801221 A1 WO 9801221A1
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
- B01J19/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
- B01J19/0046—Sequential or parallel reactions, e.g. for the synthesis of polypeptides or polynucleotides; Apparatus and devices for combinatorial chemistry or for making molecular arrays
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B82—NANOTECHNOLOGY
- B82Y—SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
- B82Y30/00—Nanotechnology for materials or surface science, e.g. nanocomposites
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- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07K—PEPTIDES
- C07K1/00—General methods for the preparation of peptides, i.e. processes for the organic chemical preparation of peptides or proteins of any length
- C07K1/04—General methods for the preparation of peptides, i.e. processes for the organic chemical preparation of peptides or proteins of any length on carriers
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- C—CHEMISTRY; METALLURGY
- C07—ORGANIC CHEMISTRY
- C07K—PEPTIDES
- C07K1/00—General methods for the preparation of peptides, i.e. processes for the organic chemical preparation of peptides or proteins of any length
- C07K1/04—General methods for the preparation of peptides, i.e. processes for the organic chemical preparation of peptides or proteins of any length on carriers
- C07K1/047—Simultaneous synthesis of different peptide species; Peptide libraries
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- B01J2219/00274—Sequential or parallel reactions; Apparatus and devices for combinatorial chemistry or for making arrays; Chemical library technology
- B01J2219/00277—Apparatus
- B01J2219/00497—Features relating to the solid phase supports
- B01J2219/00527—Sheets
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- B01J2219/00583—Features relative to the processes being carried out
- B01J2219/00596—Solid-phase processes
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
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- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
- B01J2219/00274—Sequential or parallel reactions; Apparatus and devices for combinatorial chemistry or for making arrays; Chemical library technology
- B01J2219/00583—Features relative to the processes being carried out
- B01J2219/00603—Making arrays on substantially continuous surfaces
- B01J2219/00605—Making arrays on substantially continuous surfaces the compounds being directly bound or immobilised to solid supports
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
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- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
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- B01J2219/00583—Features relative to the processes being carried out
- B01J2219/00603—Making arrays on substantially continuous surfaces
- B01J2219/00605—Making arrays on substantially continuous surfaces the compounds being directly bound or immobilised to solid supports
- B01J2219/0061—The surface being organic
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- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
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- B01J2219/00583—Features relative to the processes being carried out
- B01J2219/00603—Making arrays on substantially continuous surfaces
- B01J2219/00605—Making arrays on substantially continuous surfaces the compounds being directly bound or immobilised to solid supports
- B01J2219/00612—Making arrays on substantially continuous surfaces the compounds being directly bound or immobilised to solid supports the surface being inorganic
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- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
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- B01J2219/00603—Making arrays on substantially continuous surfaces
- B01J2219/00605—Making arrays on substantially continuous surfaces the compounds being directly bound or immobilised to solid supports
- B01J2219/00614—Delimitation of the attachment areas
- B01J2219/00617—Delimitation of the attachment areas by chemical means
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- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
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- B01J2219/00623—Immobilisation or binding
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- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
- B01J2219/00274—Sequential or parallel reactions; Apparatus and devices for combinatorial chemistry or for making arrays; Chemical library technology
- B01J2219/00583—Features relative to the processes being carried out
- B01J2219/00603—Making arrays on substantially continuous surfaces
- B01J2219/00605—Making arrays on substantially continuous surfaces the compounds being directly bound or immobilised to solid supports
- B01J2219/00623—Immobilisation or binding
- B01J2219/0063—Other, e.g. van der Waals forces, hydrogen bonding
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- B—PERFORMING OPERATIONS; TRANSPORTING
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- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
- B01J2219/00274—Sequential or parallel reactions; Apparatus and devices for combinatorial chemistry or for making arrays; Chemical library technology
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- B01J2219/00603—Making arrays on substantially continuous surfaces
- B01J2219/00605—Making arrays on substantially continuous surfaces the compounds being directly bound or immobilised to solid supports
- B01J2219/00632—Introduction of reactive groups to the surface
- B01J2219/00637—Introduction of reactive groups to the surface by coating it with another layer
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- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
- B01J2219/00274—Sequential or parallel reactions; Apparatus and devices for combinatorial chemistry or for making arrays; Chemical library technology
- B01J2219/00583—Features relative to the processes being carried out
- B01J2219/00603—Making arrays on substantially continuous surfaces
- B01J2219/00639—Making arrays on substantially continuous surfaces the compounds being trapped in or bound to a porous medium
- B01J2219/00641—Making arrays on substantially continuous surfaces the compounds being trapped in or bound to a porous medium the porous medium being continuous, e.g. porous oxide substrates
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- B—PERFORMING OPERATIONS; TRANSPORTING
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- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
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- B01J2219/00653—Making arrays on substantially continuous surfaces the compounds being bound to electrodes embedded in or on the solid supports
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- B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
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- B01J2219/00274—Sequential or parallel reactions; Apparatus and devices for combinatorial chemistry or for making arrays; Chemical library technology
- B01J2219/00709—Type of synthesis
- B01J2219/00713—Electrochemical synthesis
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- B01J2219/00274—Sequential or parallel reactions; Apparatus and devices for combinatorial chemistry or for making arrays; Chemical library technology
- B01J2219/00718—Type of compounds synthesised
- B01J2219/0072—Organic compounds
- B01J2219/00722—Nucleotides
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- C—CHEMISTRY; METALLURGY
- C40—COMBINATORIAL TECHNOLOGY
- C40B—COMBINATORIAL CHEMISTRY; LIBRARIES, e.g. CHEMICAL LIBRARIES
- C40B40/00—Libraries per se, e.g. arrays, mixtures
- C40B40/04—Libraries containing only organic compounds
- C40B40/06—Libraries containing nucleotides or polynucleotides, or derivatives thereof
Definitions
- the present invention is directed to the synthesis and placement of materials at select locations on a substrate.
- the present invention is directed to a method for providing separate sequences of chemical monomers at select locations on a substrate.
- the present invention may be applied in the field of, but is not limited to, the preparation of peptide, oligomer, polymer, oligosaccharide, nucleic acid, ribonucleic acid, porphyrin, and drug congeners.
- the present invention may be used as a method to create sources of chemical diversity for use in screening for biological activity, for example, for use in the rapidly developing field of combinatorial chemistry.
- a peptide is a sequence of amino acids.
- the twenty naturally occurring amino acids can be condensed into polymeric molecules. These polymeric molecules form a large variety of three-dimensional spatial and electronic structures. Each structure arises from a particular amino acid sequence and solvent condition.
- the number of possible hexapeptides of the twenty naturally occur ⁇ ng ammo acids for example, is 20 6 or 64 million different peptides
- the small peptide molecules are useful in target- binding studies, and sequences as short as a few ammo acids are recognized with high specificity by some antibodies
- a tubular reactor system may be used to synthesize a linear polymer on a solid phase support by automated sequential addition of reagents This method, however, also does not enable the synthesis of a sufficiently large number of polymer sequences for effective and economical screening
- Another method of preparing a plurality of polymer sequences uses a porous container enclosing a known quantity of reactive particles, larger in size than pores of the container The particles in the containers may be selectively reacted with desired materials to synthesize desired sequences of product molecules
- this method is not practical for the synthesis of a sufficient variety of polypeptides for effective screening
- Pirrung method Another drawback of the Pirrung method is that the photolabile protecting groups used cannot be removed as effectively as conventional acid or base labile protecting groups can be removed and are plagued by contamination due to undesired side reactions Consequently, using Pirrung's method, the purity of the chemical array is often compromised due to incomplete removal of the protecting groups and subsequent failure of the underlying functional groups to react with the desired monomer, as well as contamination from undesired side reactions
- Southern describes a method for synthesizing polymers at selected sites by electrochemically modifying a surface, this method involves providing an electrolyte overlaying the surface and an array of electrodes adjacent to the surface
- an array of electrodes is mechanically placed adjacent the points of synthesis, and a voltage is applied that is sufficient to produce electrochemical reagents at the electrode
- the electrochemical reagents are deposited on the surface themselves or are allowed to react with another species, found either in the electrolyte or on the surface, in order to deposit or modify a substance at the desired points of synthesis
- the array of electrodes is then mechanically removed and the surface is subsequently contacted with selected monomers For subsequent reactions, the array of electrodes is again mechanically placed adjacent the surface and a subsequent set of selected electrodes activated
- This method requires that a large amount of control be exercised over the distance that exists between the electrode array and the surface where synthesis occurs Control over the distance between the electrodes and the surface for modification is required to ensure precise alignment between the electrodes and the points of synthesis and to limit the extent of diffusion of electrochemically generated reagents away from the desired points of synthesis
- the inherent difficulty in positioning electrodes repeatedly and accurately within a few microns of the surface frequently results in the production of electrochemically generated reagents at undesirable synthesis points
- the diffusion of the electrochemically generated reagents from desired sites of reaction to undesired sites of reaction results in "chemical cross-talk" between synthesis sites. This cross-talk severely compromises the purity of the final product, as undesired binding reactions occur at unselected sites.
- Heller A more recent attempt to automate the synthesis of polymers is disclosed by Heller in International patent application WO 95/12808, published May 1 1 , 1995.
- Heller describes a self-addressable, self-assembling microelectronic system that can carry out controlled multi-step reactions in microscopic environments, including biopolymer synthesis of oligonucleotides and peptides.
- the Heller method employs free field electrophoresis to transport analytes or reactants to selected micro-locations where they are effectively concentrated and reacted with the specific binding entities.
- Each micro-location of the Heller device has a derivatized surface for the covalent attachment of specific binding entities, which includes an attachment layer, a permeation layer, and an underlying direct current micro-electrode.
- the presence of the permeation layer prevents any electrochemically generated reagents from interacting with or binding to either the points of synthesis or to reagents that are electrophoretically transported to each synthesis site Thus, all synthesis is due to reagents that are electrophoretically transported to each site of synthesis
- the Heller method is severely limited by the use of electrophoretic transport
- electrophoretic transport requires that the reactants be charged in order to be affected by the electric fields, however conventional reactants of interest for combinatorial chemistry are usually uncharged molecules not useable in an electrophoretic system
- the Heller method does not, and cannot, address the large amount of chemical crosstalk that inherently occurs because of the spatial distribution of the electric fields involved in the electrophoretic transport of the reagents for binding
- the combination of the lack of protecting groups and the spatial distribution of the electric fields inherent to electrophoresis allow such binding reactions to occur randomly, compromising the fidelity of any polymer being synthesized
- a method for electrochemical placement of a material at a specific location on a substrate comprises the steps of providing a substrate having at its surface at least one electrode that is proximate to at least one molecule bearing at least one protected chemical functional group applying a potential to the electrode sufficient to generate electrochemical reagents capable of deprotecting at least one of the protected chemical functional groups of the molecule, and bonding the deprotected chemical functional group with a monomer or a pre-formed molecule
- the present invention also includes a method for electrochemical synthesis of an array of separately formed polymers on a substrate, which comprises the steps of placing a buffering or scavenging solution in contact with an array of electrodes that is proximate to a substrate surface, said surface being proximate to one or more molecules bearing at least one protected chemical functional group attached thereto, selectively deprotectmg at least one protected chemical functional group on at least one of the molecules, bonding a first monomer having at least one protected chemical functional group to one or more deprotected chemical functional groups of the molecule, selectively deprotectmg a chemical functional group on the bonded molecule or another of the molecules bearing at least one protected chemical functional group, bonding a second monomer having at least one protected chemical functional group to a deprotected chemical functional group of the bonded molecule or the other deprotected molecule, and repeating the selective deprotection of a chemical functional group on a bonded protected monomer or a bonded protected molecule and the subsequent bonding of an additional monomer to the
- Another embodiment of the present invention also includes a method for electrochemical synthesis of an array of separately formed oligonucleotides on a substrate, which comprises the steps of placing a buffering or scavenging solution in contact with an array of electrodes that is proximate to a substrate surface, said surface being proximate to one or more molecules bearing at least one protected chemical functional group attached thereto, selectively deprotectmg at least one protected chemical functional group on at least one of the molecules bonding a first nucleotide having at least one protected chemical functional group to one or more deprotected chemical functional groups of the molecule, selectively deprotectmg a chemical functional group on the bonded molecule or another of the molecules bearing at least one protected chemical functional group, bonding a second nucleotide having at least one protected chemical functional group to a deprotected chemical functional group of the bonded molecule or the other deprotected molecule, and repeating the selective deprotection of a chemical functional group on a bonded protected nucleotide or a
- FIGURES 1a and 1b illustrate selective deprotection by electrochemically generated reagents (protons) generated at electrodes 1 and 4 to expose reactive functionalities (NH 2 ) on linker molecules (L) proximate electrodes 1 and 4
- the substrate is shown in cross section and contains 5 electrodes
- FIGURES 2a and 2b illustrate the bonding of monomers (A) bearing protected chemical functional groups (P) with the deprotected linker molecules (bearing reactive functionalities) proximate electrodes 1 and 4
- FIGURES 3a and 3b illustrate selective deprotection by protons generated at electrodes 2 and 4 of a second set of reactive functionalities on the molecule and monomer proximate electrodes 2 and 4, respectively
- FIGURES 4a and 4b illustrate the bonding of monomers (B) bearing protected chemical functional groups (P) with the deprotected molecule and monomer proximate electrodes 2 and 4, respectively
- FIGURE 5 illustrates a 5 electrode substrate bearing all possible combinations of monomers (A) and (B)
- the linker molecule proximate electrode 1 has a protected dimer, e g , a dipeptide, containing two (A) monomers bonded thereto
- the linker molecule proximate electrode 2 has a protected dimer containing a (B) monomer bonded to the linker molecule (L) and a protected (A) monomer bonded to said (B) monomer
- the linker molecule proximate electrode 3, which represents a control electrode, demonstrates a linker molecule where no synthesis occurs because no potential is applied to the proximate electrode
- the linker molecule proximate electrode 4 has a protected dimer containing an (A) monomer bonded to a linker molecule (L) and a protected (B) monomer bonded to said (A) monomer
- the linker molecule proximate electrode 5 has a protected dimer containing two (B) monomers
- FIGURE 6 illustrates a top view diagram of a substrate having at its surface a 10x10 electrode array, having 100 electrodes
- a side view of an exemplary electrode at the surface of the substrate is also shown
- FIGURE 7 illustrates a substrate having a permeable attachment layer or membrane having CBZ-protected leucme monomers (L) bonded thereto The layer/membrane overlays the electrodes at the surface of the substrate
- FIGURE 9 illustrates modification of monomers proximate electrodes 2, 3, 5, 6, and 7 following CBZ-protected phenylalanine monomers (F) have bonded with the reactive amine functionalities on the leucme monomers proximate these electrodes (a dipeptide is formed)
- FIGURE 10 illustrates modification of the substrate surface by CBZ- protected tnpeptides, glycine-phenylalanine-leucme (G-F-L) proximate electrodes 3, 5, 6, and 7
- FIGURE 11 illustrates modification of the substrate surface by CBZ- protected pentapeptides, tyrosine-glycine-glycme-phenylalanine-leucine (Y-G-G-F-L) proximate electrodes 6 and 7
- FIGURE 12 illustrates a protected leu-enkephalin epitope proximate electrode 7 and counter electrodes 1 and 10, and a deprotected leu-enkephalin epitope proximate electrode 6
- FIGURE 13 illustrates representative results as would be observed using an epifluorescent microscope following exposure to the antibody and fluorescent conjugate in accordance with Example 1
- FIGURE 14 is a digitally captured white light photomicrograph of an uncoated electrode array chip showing approximately seventy electrodes This photomicrograph was taken using a 4x objective by an Olympus BX60 microscope with a Pulnix TM-745 integrating CCD camera Note, there is electrical circuitry associated with these independently addressable electrodes
- FIGURE 15 is a digitally captured epifluorescent photomicrograph of the same array of electrodes pictured in FIGURE 14, at the same magnification This photomicrograph shows that on an uncoated electrode array chip, without any fluorescent coating material thereon, the electrodes are dark The darkness of the electrodes is explained by the metal of the electrode (platinum) quenching any fluorescence present
- FIGURE 16 is a digitally captured epifluorescent photomicrograph of electrodes in the same array as in FIGURES 14 and 15, but taken using a 10x objective and showing only sixteen electrodes
- This photomicrograph is of a chip that is coated with a fluorescent membrane material, i e , there are fluorescent labeled molecules attached to a membrane overlaying the electrodes
- This photomicrograph shows that when the electrodes are coated with a membrane containing florescent material, the area proximate/over the electrodes is bright
- the fluorescent material used for this photomicrograph was streptavidm molecules labeled with Texas Red dye
- FIGURE 17 is a digitally captured white light photomicrograph similar to FIGURE 14, except that these electrodes are hard wired, as shown by the leads connecting the electrodes to the electrical source located off the micrograph In addition, this photomicrograph was taken using a 10x objective These hardwired electrodes are located on the side of the electrode array chips Note, there is no circuitry associated with these hard wired-electrodes
- FIGURES 18a and 18b depict the chip/pin grid array (PGA) package assembly
- the chip is attached to the PGA package with glue on the opposite side of the chip from the active area (active area is the area having electrodes at its surface), which leaves the active electrode area protruding from the end of the PGA package in a manner that allows the active area of the chip to be dipped or immersed into solutions
- active area is the area having electrodes at its surface
- the electrical wires that connect the bond pads on the chip to the bond pads on the PGA package are encased in epoxy
- the pins shown in FIGURE 18b are located on the opposite side of the PGA package shown in FIGURE 18a
- FIGURES 19a and 19b represent digitally captured epifluorescent photomicrographs showing an electrode array chip before (FIGURE 19a) and after (FIGURE 19b) application of voltage and performance of a deprotection step
- a 0 05M aqueous sodium phosphate buffer at a pH of 8 0 was placed in contact with all the electrodes of the array to enable production of electrochemical reagents
- FIGURE 19b shows the electrode array after all of the electrodes in the array were exposed to the same voltage and deprotection occurred at each electrode in the array A voltage of 2 8 volts was applied for 10 minutes This photomicrograph was taken using a 4x objective and using a 1 second integration time
- FIGURE 20 represents a digitally captured epifluorescent photomicrograph showing a hardwired electrode array chip wherein the anodes (the dark electrodes) and the cathodes were alternating electrodes
- the depicted checkerboard pattern was obtained following application of 2 8 volts for 10 minutes
- the objective used to obtain this photomicrograph was 4x and the integration time was 1 seconds Note, the localization of the acid at the anodes
- the precision of the localization achieved in accordance with the present invention allowed the checkerboard pattern to be obtained
- FIGURE 21 represents a digitally captured epifluorescent photomicrograph showing the same hardwired electrode array chip as in FIGURE 20, but this photomicrograph was taken using a 10x objective with a 700 millisecond integration time
- FIGURE 22 is a digitally captured epifluorescent photomicrograph of an uncoated electrode array chip showing an array of hardwired electrodes (The neighboring electrode array is also shown in this figure ) The orientation of the array shown allows accurate reading of the brightness of the electrodes The electrodes shown are dark The three electrodes to which electrical connection was provided, and of which brightness or darkness observations were made, are labeled "Tl”, "T2", and "T4"
- FIGURE 23 is a digitally captured epifluorescent photomicrograph of a chip that is coated with a fluorescent membrane containing Texas Red labeled streptavidm molecules that are attached to the electrodes via t ⁇ tyl linker molecules Electrodes T2 and T4 have a strong bright signal Electrode T1 is dark No voltage has been applied to the electrodes yet
- FIGURE 24 is a digitally captured epifluorescent photomicrograph of the chip shown in FIGURE 23 after positive voltage has been applied to electrodes T2 and T4 Positive voltage produced protons at these electrodes Electrodes T2 and T4 are dark because the tntyl linker molecule has dissociated from the membrane overlaying the electrodes Electrode T1 was used as the counter electrode Note that the dark areas are confined to electrodes T2 and T4, i e , there is very little chemical cross talk occurring between neighboring electrodes
- FIGURES 25a and 25b represent digitally captured epifluorescent photomicrographs showing hardwired electrodes before (FIGURE 25a) and after (FIGURE 25b) a deprotection step performed in accordance with the reaction conditions, i e , electrolyte, of the prior art, Southern WO 93/22480
- the large areas of black-out and white-out surrounding the electrodes in these photomicrographs represent the excursion of the electrochemical reagents (protons) away from the electrode at which they were generated
- FIGURES 26a and 26b represent digitally captured epifluorescent photomicrographs taken through a 20x objective with a 100 millisecond integration time of the same hardwired electrodes as shown in FIGURES 25a and 25b
- the present invention provides methods for the preparation and use of a substrate having one or a plurality of chemical species in selected regions
- the present invention is described herein primarily with regard to the preparation of molecules containing sequences of am o acids, but could be readily applied to the preparation of other polymers , as well as to the preparation of sequences of nucleic acids
- Such polymers include, for example, both linear and cyclic polymers of nucleic acids, polysacchandes, phospholipids, and peptides having either alpha-, beta-, or omega-ammo acids, polyurethanes, polyesters, polycarbonates, polyureas, polyamides, polyethyleneimines, polyarylene sulfides, polysiloxanes, polyimides, polyacetates, or other polymers which will be apparent upon review of this disciosure
- the invention herein is used in the synthesis of peptides
- the present invention is used for the synthesis of oligonucleotides and/or DNA
- the present invention is directed to placing molecules, selected generally from monomers, linker molecules and pre-formed molecules, including, in particular, nucleic acids, at a specific location on a substrate
- the present invention is more particularly directed to the synthesis of polymers at a specific location on a substrate, and in particular polypeptides, by means of a solid phase polymerization technique, which generally involves the electrochemical removal of a protecting group from a molecule provided on a substrate that is proximate at least one electrode
- the present invention is also particularly directed to the synthesis of oligonucleotides and/or DNA at selected locations on a substrate, by means of the disclosed solid phase polymerization technique
- Electrochemical reagents capable of electrochemically removing protecting groups from chemical functional groups on the molecule are generated at selected electrodes by applying a sufficient electrical potential to the selected electrodes
- Removal of a protecting group, or "deprotection,” in accordance with the invention occurs at selected molecules when a chemical reagent generated by the electrode acts to deprotect or remove, for example, an acid or base labile protecting group from the selected molecules.
- a terminal end of a or linker molecule i.e., a molecule which "links," for example, a monomer or nucleotide to a substrate
- a or linker molecule i.e., a molecule which "links," for example, a monomer or nucleotide to a substrate
- the protecting group(s) is exposed to reagents electrochemically generated at the electrode and removed from the monomer, nucleotide or linker molecule in a first selected region to expose a reactive functional group
- the substrate is then contacted with a first monomer or pre-formed molecule, which bonds with the exposed functional group(s)
- This first monomer or pre-formed molecule may also bear at least one protected chemical functional group removable by an electrochemically generated reagent
- the monomers or pre-formed molecules can then be deprotected in the same manner to yield a second set of reactive chemical functional groups
- a second monomer or pre-formed molecule which may also bear at least one protecting group removable by an electrochemically generated reagent, is subsequently brought into contact with the substrate to bond with the second set of exposed functional groups Any unreacted functional groups can optionally be capped at any point during the synthesis process
- the deprotection and bonding steps can be repeated sequentially at this site on the substrate until polymers or oligonucleotides of a desired sequence and length are obtained
- the substrate having one or more molecules bearing at least one protected chemical functional group bonded thereto is proximate an array of electrodes, which array is in contact with a buffering or scavenging solution Following application of an electric potential to selected electrodes in the array sufficient to generate electrochemical reagents capable of deprotectmg the protected chemical functional groups, molecules proximate the selected electrodes are deprotected to expose reactive functional groups, thereby preparing them for bonding
- Another sufficient potential is subsequently applied to select electrodes in the array to deprotect at least one chemical functional group on the bonded molecule or another of the molecules bearing at least one protected chemical functional group
- a second monomer or pre-formed molecule having at least one protected chemical functional group is subsequently bonded to a deprotected chemical functional group of the bonded molecule or the other deprotected molecule
- the selective deprotection and bonding steps can be repeated sequentially until polymers or oligonucleotides of a desired sequence and length are obtained
- the selective deprotection step is repeated by applying another potential sufficient to effect deprotection of a chemical functional group on a bonded protected monomer or a bonded protected molecule
- the subsequent bonding of an additional monomer or pre-formed molecule to the deprotected chemical functional group(s) until at least two separate polymers or oligonucleotides of desired length are formed on the substrate
- FIGURES 1 -5 genencally illustrate the above-discussed embodiments
- Preferred embodiments of the present invention use a buffering or scavenging solution in contact with each electrode, which is buffered towards the electrochemically generated reagents, in particular, towards protons and/or hydroxyl ions, and which actively prevents chemical cross-talk caused by diffusion of the electrochemically generated ions from one electrode to another electrode in an array
- a buffering or scavenging solution in contact with each electrode, which is buffered towards the electrochemically generated reagents, in particular, towards protons and/or hydroxyl ions, and which actively prevents chemical cross-talk caused by diffusion of the electrochemically generated ions from one electrode to another electrode in an array
- protons or hydroxyl ions
- Protons for example, are useful for removing electrochemical protecting groups from several molecules useful in combinatorial synthesis, for example, peptides, nucleic acids, and polysaccharides
- the present invention advantageously minimizes, and preferably eliminates, chemical cross-talk between nearby areas of polymer or nucleic acid sequence synthesis on a substrate, thus enabling the synthesis of separate arrays of pure polymers or nucleic acid sequences in a small specified area on a substrate using conventional electrochemically generated reagents and known electrochemical reactions
- inventive methods to place materials at specific locations on a substrate enables the inventive method to be used in several areas of synthesis in addition to polymer synthesis Several examples of this synthesis include DNA and oligonucleotide synthesis, monomer decoration, which involves the addition of chemical moieties to a single monomer, and inorganic synthesis, which involves the addition of, for example, metals to porphynns
- inventions contemplate an array of electrodes of small micron size, for example, ranging from 1 to 100 microns in diameter, and separated by many microns However, it is also contemplated that electrodes separated by only submicron distances can be used, if desired
- This arrangement affords a large quantity of separate and pure polymers or nucleic acid sequences to be synthesized simultaneously in a small area on a substrate in accordance with the inventive method
- This capability renders the inventive method easily automated
- the ability of the present invention to be automated easily while retaining the capability of producing separate and diverse arrays of pure polymers and nucleic acid sequences makes the present invention ideal for use in the rapidly developing areas of combinatorial chemistry and functional genomics
- any conceivable substrate may be employed in accordance with the present invention
- the substrate may be biological, nonbiological, organic, inorganic, or a combination of any of these, existing as particles strands, precipitates, gels, sheets, tubing, spheres, containers, capillaries, pads, slices, films, plates, slides, etc
- the substrate may have any convenient shape, such as a disc, square, sphere, circle, etc
- the substrate is preferably flat, but may take on a variety of alternative structure configurations
- the substrate may contain raised or depressed regions on which synthesis may take place
- the substrate and its surface preferably form a rigid support on which to carry out the reactions described herein
- the substrate and the area for synthesis of each individual polymer or small molecule may be of any size and shape
- a substrate may comprise different materials at different regions
- Contemplated materials which are preferably used as substrates and which are capable of holding and insulating electrically the electrodes, include undoped semiconductors, such as silicon nitride, silicon oxide, silicon, diamond, chalcopy tes, wurtzites, sphalerites, halites, Group lll-V compounds, and Group ll-VI compounds, glass, such as, cobalt glass, pyrex glass vycor glass, borosilicate glass and quartz, ceramics, such as, alumina, porcelain, zircon, cordente, titanates, metal oxides, clays, and zeolites, polymers, such as, paralyene, high density polyethylene, teflons, nylons, polycarbonates polystyrenes, polyacylates, polycyanoacrylates, polyvmyl alcohols, polyimides, polyamides, polysiloxanes, polysilicones, polynitnles, polyvmyl chlorides alkyd polymers, celluloses, expoxy polymers,
- the substrate of the invention is proximate to at least one electrode, i e , an electrically conducting region of the substrate that is substantially surrounded by an electrically insulating region
- the electrode(s) by being "proximate" to the substrate, can be located at the substrate, i e , embedded in or on the substrate, can be next to, below, or above the substrate, but need to be in close enough proximity to the substrate so that the reagents electrochemically generated at the electrode(s) can accomplish the desired deprotection of the chemical functional groups on the monomer(s) and/or molecule(s)
- the substrate has on a surface thereof, at least one molecule, and preferably several molecules, bearing at least one chemical functional group protected by an electrochemically removable protecting group
- these molecules bearing protected chemical functional groups also need to be proximate to the electrode(s)
- the molecules on the surface of the substrate need to be in close enough proximity to the electrode(s) so that the electrochemical reagents generated at the electrode can remove the protecting group from at least one protected functional group on the proximate molecule(s)
- the molecules bearing a protected chemical functional group that are attached to the surface of the substrate may be selected generally from monomers, linker molecules and pre-formed molecules
- the molecules attached to the surface of the substrate include monomers, nucleotides, and linker molecules All of these molecules generally bond to the substrate by covalent bonds or ionic interactions Alternatively, all of these molecules can be bonded, also by covalent bonds or ionic interactions, to a layer overlaying the substrate, for example, a permeable membrane layer, which layer can be adhered to the substrate surface in several different ways, including covalent bonding, ionic interactions, dispersive interactions and hydrophiiic or hydrophobic interactions
- a monomer or pre-formed molecule may be bonded to a linker molecule that is bonded to either the substrate or a layer overlaying the substrate
- the monomers, linker molecules and pre-formed molecules used herein are preferably provided with a chemical functional group that is protected by a protecting group removable by electrochemically generated reagents If a chemical functional group capable of being deprotected by an electrochemically generated reagent is not present on the molecule on the substrate surface, bonding of subsequent monomers or pre-formed molecules cannot occur at this molecule
- the protecting group is on the distal or terminal end of the linker molecule, monomer, or pre-formed molecule, opposite the substrate That is the linker molecule preferably terminates in a chemical functional group, such as an ammo or carboxy acid group, bearing an electrochemically removable protective group
- Chemical functional groups that are found on the monomers, linker molecules and pre-formed molecules include any chemically reactive functionality Usually, chemical functional groups are associated with corresponding protective groups and will be chosen or utilized based on the product being synthesized The molecules of the invention bond to deprotected chemical functional groups by covalent bonds or ionic interactions
- Monomers used in accordance with the present invention to synthesize the various polymers contemplated include all members of the set of small molecules that can be joined together to form a polymer
- This set includes but is not limited to, the set of common L-ammo acids, the set of D-amino acids the set of synthetic ammo acids, the set of nucleotides and the set of pentoses and hexoses
- monomers include any member of a basis set for synthesis of a polymer
- trimers of L-ammo acids form a basis set of approximately 8000 monomers for synthesis of polypeptides
- Different basis sets of monomers may be used at successive steps in the synthesis of a polymer using the inventive method
- the number of monomers that can be used in accordance with the inventive synthesis methods can vary widely, for example from 2 to several thousand monomers can be used, but in more preferred embodiments, the number of monomers will range from approximately 4 to approximately 200, and, more preferably, the number of monomers will range from 4-20
- Additional monomers that can be used in accordance with the invention also include the set of monomers that can be decorated, i e , monomers to which chemical moieties can be added, such as prostaglandms, benzodiazapines, thromboxanes and leukotrienes Combinations of monomers useful for polymer synthesis and monomers that can be decorated are also contemplated by the invention
- the above-discussed monomers may be obtained in unprotected form from most any chemical supply company, and most, if not all, can be obtained in protected form from Bachem, Inc , Torrance, California Phosphoramidite monomers for nucleic acid synthesis can be obtained from Applied Biosystems, Inc , Foster City, California
- the monomers are ammo acids containing a protective group at its am o or carboxy terminus that is removable by an electrochemically generated reagent
- a polymer in which the monomers are alpha ammo acids and are joined together through amide bonds is a peptide, also known as a polypeptide
- the ammo acids may be the L-optical isomer or the D-optical isomer or a mixture of the two Peptides are at least two ammo acid monomers long, and often are more than 20 am o acid monomers long
- any pre-formed molecule can be bonded to the substrate, a layer overlaying the substrate, a monomer or a linker molecule
- Pre-formed molecules include, for example, proteins, including in particular, receptors, enzymes, ion channels, and antibodies, nucleic acids, polysaccharides, porphynns, and the like
- Pre-formed molecules are, in general, formed at a site other than on the substrate of the invention
- a pre-formed molecule is bonded to a deprotected functional group on a molecule, monomer, or another pre-formed molecule
- a pre-formed molecule that is already attached to the substrate may additionally bear at least one protected chemical functional group to which a monomer or other pre-formed molecule may bond, following deprotection of the chemical functional group
- Protective groups are materials that bind to a monomer, a linker molecule or a pre-formed molecule to protect a reactive functionality on the monomer, linker molecule or pre-formed molecule, which may be removed upon selective exposure to an activator, such as an electrochemically generated reagent
- Protective groups that may be used in accordance with the present invention preferably include all acid and base labile protecting groups
- peptide amine groups are preferably protected by t- butyloxycarbonyl (BOC) or benzyloxycarbonyl (CBZ), both of which are acid labile, or by 9-fluorenylmethoxycarbonyl (FMOC), which is base labile
- hydroxy groups on phosphoramidites may be protected by dimethoxytrityl (DMT), which is acid labile
- Exocyclic amine groups on nucleosides, in particular on phosphoramidites are preferably protected by dimethylformamidme on the adenosme and
- Additional protecting groups that may be used in accordance with the present invention include acid labile groups for protecting ammo moieties tert- butyioxycarbonyl, tert-amyloxycarbonyl, adamantyloxycarbonyl, 1- methylcyclobutyloxycarbonyl, 2-(p-b ⁇ phenyl)propyl(2)oxycarbonyl, 2-(p- phenylazophenylyl)propyl(2)oxycarbonyl, ⁇ , ⁇ -d ⁇ methyl-3,5- dimethyloxybenzyloxy-carbonyl 2-phenylpropyl(2)oxycarbonyl, 4- methyloxybenzyloxycarbonyl, benzyloxycarbonyl, furfuryloxycarbonyl, t ⁇ phenylmethyl (tntyl), p-toluenesulfenylammocarbonyl, dimethylphosphinothioyl, diphenylphosph othioyl, 2-benzoyl-1 -methylv
- any unreacted deprotected chemical functional groups may be capped at any point during a synthesis reaction to avoid or prevent further bonding at such molecule
- Capping groups "cap" deprotected functional groups by, for example, binding with the unreacted ammo functions to form amides
- Capping agents suitable for use in the present invention include acetic anhydride, n-acetyhmidizole, isopropenyl formate, fluorescamine, 3-n ⁇ trophthal ⁇ c anhydride and 3-sulfopropon ⁇ c anhydride Of these, acetic anhydride and n-acetylimidizoie are preferred
- the surface of the substrate is preferably provided with a layer of linker molecules
- Linker molecules allow for indirect attachment of monomers or pre-formed molecules to the substrate or a layer overlaying the substrate
- the linker molecules are preferably attached to an overlaying layer via silicon-carbon bonds, using, for example, controlled porosity glass (CPG) as the layer material
- CPG controlled porosity glass
- the linker molecules are preferably chosen based upon their hydrophilic/hydrophobic properties to improve presentation of synthesized polymers to certain receptors For example, in the case of a hydrophilic receptor, hydrophilic linker molecules will be preferred so as to permit the receptor to approach more closely the synthesized polymer
- the linker molecules are preferably of sufficient length to permit polymers on a completed substrate to interact freely with binding entities exposed to the substrate
- the linker molecules when used, are preferably 6- 50 atoms long to provide sufficient exposure of the functional groups to the binding entity
- the linker molecules which may be advantageously used in accordance with the invention include, for example, aryl acetylene, ethylene glycol oligomers containing from 2 to 10 monomer units, diamines, diacids ammo acids, and combinations thereof
- Other linker molecules may be used in accordance with the different embodiments of the present invention and will be recognized by those skilled in the art in light of this disclosure
- linker molecules may be provided with a cleavable group at an intermediate position, which group can be cleaved with an electrochemically generated reagent
- This group is preferably cleaved with a reagent different from the reagent(s) used to remove the protective groups
- This enables removal of the various synthesized polymers or nucleic acid sequences following completion of the synthesis by way of electrochemically generated reagents
- derivatives of the acid labile 4,4'-d ⁇ methyoxytr ⁇ tyl molecules with an exocyclic active ester can be used in accordance with the present invention
- These linker molecules can be obtained from Perseptive Biosystems, Framingham, Massachusetts More preferably, N-succ ⁇ n ⁇ m ⁇ dyl-4-[b ⁇ s-(4-methoxyphenyl)-chloromethyl]-benzoate is used as a cleavable linker molecule during DNA synthesis The synthesis and use of this molecule is described in A Versa
- cleavable linker groups affords dissociation or separation of synthesized molecules, e g , polymers or nucleic acid sequences, from the electrode array at any desired time
- This dissociation allows transfer of the, for example, synthesized polymer or nucleic acid sequence, to another electrode array or to a second substrate
- the second substrate could contain bacteria and serve to assay the effectiveness of molecules made on the original electrode array at killing bacteria
- the second substrate could be used to purify the materials made on the original electrode array Obviously those skilled in the art can contemplate several uses for transferring the molecules synthesized on the original electrode to a second substrate
- the molecules of the invention can be attached directly to the substrate or can be attached to a layer or membrane of separating material that overlays the substrate
- Materials that can form a layer or membrane overlaying the substrate, such that molecules can be bound there for modification by electrochemically generated reagents include, controlled porosity glass (CPG), generic polymers, such as, teflons, nylons, polycarbonates, polystyrenes, polyacylates, poiycyanoacrylates, polyvmyl alcohols, polyamides, polyimides, polysiloxanes, polysilicones, polynit ⁇ les, polyelectrolytes, hydrogels, epoxy polymers, melamines, urethanes and copolymers and mixtures of these and other polymers, biologically derived polymers, such as, polysaccharides polyhyalu ⁇ c acids, celluloses, and chitons, ceramics, such as, alumina, metal oxides
- Reagents that can be generated electrochemically at the electrodes fall into two broad classes oxidants and reductants There are also miscellaneous reagents that are useful in accordance with the invention
- Oxidants that can be generated electrochemically include iodine, i ⁇ date, periodic acid, hydrogen peroxide, hypochlo ⁇ te, metavanadate, bromate dichromate, cerium (IV), and permanganate Reductants which can be generated electrochemically include chromium (II), ferrocyanide, thiols, thiosulfate, titanium (III), arsenic (III) and iron (II)
- the miscellaneous reagents include bromine, chloride, protons and hydroxyl ions Among the foregoing reagents, protons, hydroxyl ions, iodine, bromine, chlorine and the thiols are preferred
- a buffering and/or scavenging solution is in contact with each electrode
- the buffering and/or scavenging solutions that may be used in accordance with the invention are preferably buffered toward, or scavenge, protons and/or hydroxyl ions, although other electrochemically generated reagents capable of being buffered and/or scavenged are clearly contemplated
- the buffering solution functions to prevent chemical cross-talk due to diffusion of electrochemically generated reagents from one electrode in an array to another electrode in the array, while a scavenging solution functions to seek out and neutralize/deactivate the electrochemically generated reagents by binding or reacting with them
- the spatial extent of excursion of electrochemically generated reagents can be actively controlled by the use of a buffering solution and/or a scavenging solution
- the buffering and scavenging solutions may be used independently or together
- a buffering solution is used
- Buffering solutions that can be used in accordance with the present invention include all electrolyte salts used in aqueous or partially aqueous preparations
- Buffering solutions preferably used in accordance with the present invention include acetate buffers, which typically buffer around pH 5, borate buffers, which typically buffer around pH 8, carbonate buffers, which typically buffer around pH 9, citrate buffers, which typically buffer around pH 6, glycine buffers, which typically buffer around pH 3, HEPES buffers, which typically buffer around pH 7, MOPS buffers, which typically buffer around pH 7, phosphate buffers, which typically buffer around pH 7, TRIS buffers, which typically buffer around pH 8, and 0 1 M Kl in solution, which buffers the iodine concentration by the equilibrium reaction l 2 + I « l 3 , the equilibrium coefficient for this reaction being around 10 2
- a scavenging solution may be used that contains species such as ternary amines that function as hydroxyl ion scavengers or sulfonic acids that function as proton scavengers in nonaqueous media
- species such as ternary amines that function as hydroxyl ion scavengers or sulfonic acids that function as proton scavengers in nonaqueous media
- the rate at which a reagent species is scavenged depends both on the intrinsic rate of the reaction occurring and on the concentration of the scavenger For example, solvents make good scavengers because they are frequently present in high concentrations Most molecules scavenge in a nonselective way, however, some molecules, such as superoxide dismutase and horseradish peroxidase, scavenge in a selective manner
- scavenger molecules that can scavenge the different reactive species commonly generated, for example, by water hydrolysis at electrodes, including hydroxyl radicals, superoxides, oxygen radicals, and hydrogen peroxide Hydroxyl radicals are among the most reactive molecules known, their rate of reaction is diffusion controlled, that is, they react with the first reactant species they encounter When hydroxyl radicals are generated by water hydrolysis, the first molecule they usually encounter is a water molecule For this reason, water is a rapid and effective scavenger of hydroxyl radicals Superoxides are also a relatively reactive species, but can be stable in some nonaqueous or partially aqueous solvents In aqueous media, superoxides rapidly react with most molecules including water In many solvents, they can be scavenged selectively with superoxidase dismutase
- Oxygen radicals are a family of oxygen species that exist as free radicals They can be scavenged by a wide variety of molecules such as water or ascorbic acid
- Hydrogen peroxide is a relatively mild reactive species that is useful, in particular, in combinatorial synthesis
- Hydrogen peroxide is scavenged by water and many types of oxidizing and reducing agents The rate at which hydrogen peroxide is scavenged depends on the redox potential of the scavenger molecules being used
- Hydrogen peroxide can also be scavenged selectively by horseradish peroxidase
- Another electrochemically generated species that can be scavenged is iodine
- Iodine is a mild oxidizing reagent that is also useful for combinatorial synthesis
- Iodine can be scavenged by reaction with hydroxyl ions to form iodide ions and hypoiodite
- the rate at which iodine is scavenged is pH dependent
- the buffering solutions are preferably used in a concentration of at least 0 01 mM More preferably, the buffering solution is present in a concentration ranging from 1 to 100mM, and still more preferably, the buffering solution is present in a concentration ranging from 10 to 100mM Most preferably, the buffering solution concentration is approximately 30 mM
- a buffering solution concentration of approximately 0 1 molar will allow protons or hydroxyl ions to move approximately 100 angstroms before buffering the pH to the bulk values
- Lower buffering solution concentrations, such as 0 00001 molar will allow ion excursion of approximately several microns, which still may be acceptable distance depending on the distance between electrodes in an array
- the concentration of scavenger molecules in a solution will depend on the specific scavenger molecules used since different scavenging molecules react at different rates The more reactive the scavenger, the lower the concentration of scavenging solution needed, and vice versa Those skilled in the art will be able to determine the appropriate concentration of scavenging solution depending upon the specific scavenger selected
- the at least one electrode proximate the substrate of the invention is preferably an array of electrodes Arrays of electrodes of any dimension may be used including arrays containing up to several million electrodes Preferably, multiple electrodes in an array are simultaneously addressable and controllable by an electrical source More preferably, each electrode is individually addressable and controllable by its own electrical source, thereby affording selective application of different potentials to select electrodes in the array In this regard, the electrodes can be described as "switchable"
- the arrays need not be in any specific shape, that is, the electrodes need not be in a square matrix shape
- Contemplated electrode array geometries include squares, rectangles, rectilinear and hexagonal grid arrays with any sort of polygon boundary, concentric circle grid geometries wherein the electrodes form concentric circles about a common center, and which may be bounded by an arbitrary polygon, and fractal grid array geometries having electrodes with the same or different diameters Interlaced electrodes may also be used in accordance with the present invention
- the array of electrodes contains at least 100 electrodes in a 10x10 matrix
- FIGURE 6 A side view of an electrode at the surface of the substrate is also shown
- the array of electrodes contains at least 400 electrodes in, for example, an at least 20x20 matrix Even more preferably, the array contains at least 2048 electrodes in, for example, an at least 64x32 matrix and still more preferably, the array contains at least 204,800 electrodes in, for example, an at least 640x320 array
- the array of electrodes contains at least 400 electrodes in, for example, an at least 20x20 matrix
- the array contains at least 2048 electrodes in, for example, an at least 64x32 matrix
- the array contains at least 204,800 electrodes in, for example, an at least 640x320 array
- Other sized arrays that may be used in accordance with the present invention will be readily apparent to those of skill in the art upon review of this disclosure
- Electrode arrays containing electrodes ranging in diameter from approximately less than 1 micron to approximately 100 microns (0 1 millimeters) are advantageously used in accordance with the present invention Further, electrode arrays having a distance of approximately 10-1000 microns from center to center of the electrodes, regardless of the electrode diameter, are advantageously used in accordance with the present invention More preferably, a distance of 50-100 microns exists between the centers of two neighboring electrodes
- the electrodes may be flush with the surface of the substrate
- the electrodes are hemisphere shaped, rather than flat disks
- the profile of the hemisphere shaped electrodes is represented by an arctangent function that looks like a hemisphere
- Hemisphere shaped electrodes help assure that the electric potential is constant across the radial profile of the electrode That is, hemisphere shaped electrodes help assure that the electric potential is not larger near the edge of the electrode than in the middle of the electrode, thus assuring that the generation of electrochemical reagents occurs at the same rate at all parts of the electrode
- Electrodes that may be used in accordance with the invention may be composed of, but are not limited to, noble metals such as indium and/or platinum, and other metals, such as, palladium, gold, silver, copper, mercury nickel, zinc, titanium, tungsten, aluminum, as well as alloys of various metals, and other conducting materials, such as, carbon, including glassy carbon reticulated vitreous carbon, basal plane graphite, edge plane graphite and graphite Doped oxides such as indium tin oxide, and semiconductors such as silicon oxide and gallium arsenide are also contemplated Additionally, the electrodes may be composed of conducting polymers, metal doped polymers, conducting ceramics and conducting clays Among the noble metals, platinum and palladium are especially preferred because of the advantageous properties associated with their ability to absorb hydrogen, i e , their ability to be "preloaded" with hydrogen before being used in the methods of the invention
- the electrode(s) used in accordance with the invention may be connected to an electric source in any known manner Preferred ways of connecting the electrodes to the electric source include CMOS switching circuitry, radio and microwave frequency addressable switches, light addressable switches, and direct connection from an electrode to a bond pad on the perimeter of a semiconductor chip
- CMOS switching circuitry involves the connection of each of the electrodes to a CMOS transistor switch
- the switch is accessed by sending an electronic address signal down a common bus to SRAM (static random access memory) circuitry associated with each electrode
- SRAM static random access memory
- Radio and microwave frequency addressable switches involve the electrodes being switched by a RF or microwave signal This allows the switches to be thrown both with and/or without using switching logic
- the switches can be tuned to receive a particular frequency or modulation frequency and switch without switching logic Alternatively, the switches can use both methods
- Light addressable switches are switched by light
- the electrodes can also be switched with and without switching logic
- the light signal can be spatially localized to afford switching without switching logic This is accomplished, for example, by scanning a laser beam over the electrode array, the electrode being switched each time the laser illuminates it Alternatively, the whole array can be flood illuminated and the light signal can be temporally modulated to generate a coded signal However switching logic is required for flood illumination
- the electrodes are formed from semiconductor materials
- the semiconductor electrodes are then biased below their threshold voltage At sufficiently low biases, there is no electrochemistry occurring because the electrons do not have enough energy to overcome the band gap
- the electrodes that are "on" will already have been switched on by another method
- the electrodes When the electrodes are illuminated, the electrons will acquire enough energy from the light to overcome the band gap and cause electrochemistry to occur
- an array of electrodes can be poised to perform electrochemistry whenever they are illuminated With this method, the whole array can be flood illuminated or each electrode can be illuminated separately This technique is useful for very rapid pulsing of the electrochemistry without the need for fast switching electronics
- Direct connection from an electrode to a bond pad on the perimeter of the semiconductor chip is another possibility, although this method of connection could limit the density of the array
- Electrochemical generation of the desired type of chemical species requires that the electric potential of each electrode have a certain minimum value That is to say, a certain minimum potential is necessary, which may be achieved by specifying either the voltage or the current
- a certain minimum potential is necessary, which may be achieved by specifying either the voltage or the current
- the necessary minimum potential value will be determined by the type of chemical reagent chosen to be generated
- One skilled in the art can easily determine the necessary voltage and/or current to be used based on the chemical species desired
- the maximum value of potential that can be used is also determined by the chemical species desired If the maximum value of potential associated with the desired chemical species is exceeded, undesired chemical species may be resultantly produced
- the substrates prepared in accordance with the present invention will have a variety of uses including, for example, screening large numbers of polymers for biological activity To screen for biological activity, for example, in the fieid of pharmaceutical drug discovery, the substrate is exposed to one or more receptors such as antibodies, whole cells, receptors on vesic
- the present invention can also be used for therapeutic materials development, i e , for drug development and for biomate ⁇ al studies, as well as for biomedical research, analytical chemistry and bioprocess monitoring
- An exemplary application of the present invention includes diagnostics in which various ligands for particular receptors can be placed on a substrate and for example, blood sera can be screened
- Another exemplary application includes the placement of single or multiple pre-formed receptor molecules at selected sites on a substrate and, for example, drug screening could be conducted by exposing the substrate to drug candidate molecules to determine which molecules bind to which pre-formed receptor molecules
- Yet another application includes, for example, sequencing genomic DNA by the technique of sequencing by hybridization
- Another contemplated application includes the synthesis and display of differing quantities of molecules or ligands at different spatial locations on an electrode array chip and the subsequent performance of dilution series experiments directly on the chip Dilution series experiments afford differentiation between specific and non-specific binding of, for example, ligands and receptors
- Non-biological applications are also contemplated, and include the production of organic materials with varying levels of doping for use, for example in semiconductor devices
- Other examples of non-biological uses include anitcorrosives, antifoulants, and paints
- Endorphins are naturally occurring small peptides, e g , including approximately 20-40 ammo acids, that bind to opiate receptors in the brain It has been discovered that most of the activity of endorphins is due to the last five am o acids on the peptides These terminal pentapeptides are called enkephalins
- the immunofluorescent technique for detecting the leu-enkephalin epitope follows standard detection protocols See for example F M Ausubel et al , Short Protocols in Molecular Biology, Third edition, Unit 14 pgs 14-23ff (1995)
- This assay requires a primary antibody, e g , the 3-E7 monoclonal antibody, and a secondary antibody-fluorochrome conjugate specific to the source species of primary antibody, e g , the goat anti-mouse fluorescent conjugate
- the 3-E7 antibody is a mouse monoclonal antibody against ⁇ - endorphins that bind to leu-enkephahns Both of the antibodies for this technique can be obtained from Boehrmger Mannheim Biochemicals, Indianapolis, Indiana
- FIGURE 6 An 10x10 platinum electrode array is used, as is shown in FIGURE 6 Columns 1 and 10 are used as counter electrodes The active columns of the array are columns 2, 3, 5, 6 and 7 Columns 4, 8 and 9 are never activated in this synthesis
- the surface of the array is modified with a permeable membrane layer formed from controlled porosity glass (CPG) that is applied to the array by deposition of silicon dioxide under appropriate conditions in the semiconductor manufacturing process
- CPG controlled porosity glass
- the CPG forms a chemically inert membrane that is permeable to ions
- This membrane is functionalized by silanation with chloromethyl silane
- the chloromethyl silane groups are further modified by ethylene glycol linker molecules containing ten ethylene glycol moieties by reacting the silanized CPG membrane with a molecule containing ten ethylene glycol moieties and two am o groups at each end
- This membrane provides a layer overlaying the surface of the array that is functionalized by amine groups that are, in turn, attached to the CPG matrix via a silane moiety
- the diamino ethylene glycol molecules act as linker molecules (spacer groups) between the membrane and the epitope molecules which are formed
- the functionalized CPG membrane covered electrode array is exposed to a DMF solution of benzyloxycarbonyl (CBZ) protected l-leuc ⁇ ne containing coupling reagents, such as, but not limited to, dicyclohexylcarbodiimide (DCC) or diisopropylcarbodiimide, at room temperature for approximately two hours
- CBZ benzyloxycarbonyl
- DCC dicyclohexylcarbodiimide
- diisopropylcarbodiimide dicyclopropylcarbodiimide
- a preconditioning step is performed columns 2, 3, 5, 6, and 7 are biased negative with respect to columns 1 and 10, which serve as counter electrodes There is no reference electrode in this system The potential difference is approximately 3 volts, which voltage is applied for approximately 10 seconds
- This preconditioning step causes hydroxyl ions to be formed at the electrodes with a negative bias and protons to be formed at the counter electrodes having a positive bias
- This preconditioning step also causes protons to be reduced to hydrogen molecules at electrodes with a negative bias
- the platinum electrodes absorb and hold some of these hydrogen molecules in the bulk metal
- the bias is then reversed
- the electrodes of columns 1 and 10 (counter electrodes) are biased negative with respect to columns 2, 3, 5, 6, and 7
- the potential difference is approximately 2 6 volts, which voltage is applied for approximately three seconds
- This step causes protons to be formed at the electrodes with a positive bias both from hydrolysis of water and from oxidation of hydrogen molecules that are absorbed into the platinum electrodes during the preconditioning step
- the CBZ protecting groups are removed from the leucme am o acid moieties at the electrodes in columns 2, 3, 5, 6, and 7
- the deprotection and coupling steps are then repeated at columns 6 and 7 while the electrode array is again exposed to an aqueous 0 1 M phosphate buffer solution having a pH of 7 4
- the electrode array is then exposed to a DMF solution of CBZ-protected-l-tyros ⁇ ne and coupling reagents for approximately two hours at room temperature
- the deprotectmg step is then repeated at columns 2, 3 5 and 6 without a preconditioning step, to remove the CBZ protecting groups from the terminal ammo acids of the combinatorial sequences This procedure produces the following sequences
- the monomer units for combinatorial synthesis of DNA are called phosphoramidites
- Phosphoramidites are linked together into a single strand nucleic acid polymer through phosphodiester bonds Since the phosphorous is protected by a cyanoethyl ether moiety during synthesis, the bonds are phosphotnester bonds
- the cyanoethyl group can be removed by a base at the end of synthesis to give the phosphodiester linkage
- Phosphoramidites have two ends that are called 3' and 5' ends
- the 3' end of one phosphoramidite will couple with the 5' end of another Usually the 3' end is attached to a solid support and the 5' end is modified by another phosphoramidite to start the synthesis cycle
- the 5' end is a hydroxy group that can be protected by a molecule called dimethylt ⁇ tyl (DMT)
- DMT groups are acid labile protecting groups
- DNA polymers There are four naturally occurring deoxynbonucleotide monomers that form DNA polymers They are adenosine (A), thymidine (T), cytosine (C), and guanosine (G) DNA is considered an acid because the phosphodiester groups that bind the monomers together are acidic
- the nucleosides (A, T, C, G) are organic bases DNA in nature is normally tens of millions to billions of base units long A fifteen base unit long piece of DNA will be prepared in the following example A piece of DNA of this length is known as a oligonucleotide DNA molecules should be at least this long, otherwise it is very difficult to distinguish between them
- the nucleosides are protected because the exocyclic amine bases (A, C, G) are susceptible to depu ⁇ nation by acids
- the protecting groups on these bases are base labile
- There are three kinds of protecting groups on phosphoramidites They are the DMT groups, which protect the 5" hydroxyl groups the cyanoethyl ether groups, which protect the phosphorous, and the FOD (fast oligonucleotide deprotection) groups, which protect the exocyclic amines on the nucleoside bases
- the DMT groups are acid labile and the others are base labile DNA is found in nature mostly as the "duplex" form having the famous double helix structure This means that two single strands of DNA are bound together by interactions between the nucleoside bases
- the nucleoside base T interacts with the nucleoside base A to form an A-T linkage
- the nucleoside base C interacts with the nucleoside base G to form a C-G linkage
- probe strands of DNA that are complimentary with the strands that presumably were synthesized at that site
- These probe strands are labeled covalently with a fluorescent dye
- the probe strands will bind to DNA molecules on the surface with both the correct sequence and the incorrect sequence
- the melting temperatures are much lower for the DNA duplexes that contain mismatches, i e non A-T and C-G links, than those that are complimentary, i e , A-T and C-G links
- the probes forming duplexes with the incorrect DNA strands will denature first By increasing the temperature to a level where all of the mismatched DNA duplexes have denatured, it is possible to detect only the DNA molecules with the correct sequence by observing the fluorescent dye using epifluorescent microscopy Alternatively, the test surface can be washed with low ionic strength aqueous solutions This has the same effect as raising the temperature and is more convenient experimentally
- the electrode array is first modified with an acrylate/polyvmyl alcohol copolymer layer or membrane
- the copolymer layer contains numerous pendant hydroxyl groups that are reactive toward phosphoramidites
- the polymer modified electrode array is then exposed to DMT- protected cytid e phosphoramidite and tetrazole at a concentration of 0 05 M in an anhydrous acetonitnle for 30 seconds at room temperature
- the cytosine base and all of the other bases used in this example are protected using the FOD protecting scheme (FOD protecting groups afford the best protection against depu ⁇ nation of exocyclic amines )
- the array is then washed with anhydrous acetonitnle Any unreacted hydroxyl groups on the surface are then capped by exposing the surface to an anhydrous acetonitnle solution of acetic anhydride and 1-methyl ⁇ m ⁇ d ⁇ zole for thirty seconds This results in a surface modified everywhere with DMT protected C base units
- the tnvalent phosphtte linkage between the polymer and the phosphoramidite is oxidized to the more stable pentavalent phosphot ⁇ ester linkage by electrochemically generated iodine
- the iodine is produced electrochemically by the oxidation of iodide ions in an aqueous THF solution of potassium iodide Iodine can be confined to the local area where it is formed by both an iodine buffering reaction and a scavenging reaction Iodine is buffered by an equilibrium reaction with iodide ions to form the tniodide ion
- the t iodide ion is not a useful reagent
- the solution can be buffered with respect to hydroxyl ions such that it is slightly basic Iodine reacts with hydroxyl ions to form iodide ions and hypoiodite Both of these chemical species are unreactive
- hydroxyl ions serve
- the electrode array is next exposed to an aqueous 0 1 M sodium phosphate solution A positive potential is applied for one second to first selected areas and the DMT protecting groups are removed from the cytidme phosphoramidites in first selected areas The array is then washed with anhydrous acetic anhydride The reactive array is then exposed to a 0 05 M solution of thymidine phosphoramidite, T, and tetrazole in anhydrous acetonitnle for 30 seconds The T nucleotides react with the C nucleotides at the first selected sites to form a C-T dimer The remaining unreacted C nucleotides are capped and the phosphite linkages are reduced to phosphotnester linkages as outlined above
- the photomicrographs were taken using an Olympus BX60 microscope with a Pulnix TM-745 integrating CCD camera
- the camera was controlled by, and the images were captured by, a Data Translation DT3155 video capture card run by a Pentium-based personal computer
- the software that controlled the DT3155 card can easily be written by one of ordinary skill in the art
- Epifluorescent microscopy involves illuminating the electrode array chip from a position above the chip surface, along a path normal to the chip surface The illuminating beam is filtered to obtain a narrow band centered at the excitation wavelength of the fluorescent dye being used
- the fluorescent dye used in the following example and comparative example was Texas Red which has an absorption maximum at 595 nm This dye emits a fluorescent light with an emission maximum at 615 nm when it is excited with light of approximately 595 nm Texas Red can be obtained from Molecular Probes, Eugene Oregon Filters in the Olympus BX60 microscope prevent the excitation light from traveling to the optical detector of the CCD camera
- the Olympus BX60 microscope is equipped with an ancillary art-recognized instrumentation module to perform epifluorescent microscopy using Texas Red dye
- FIGURES 14-16 Exemplary photomicrographs taken using white illumination and epifluorescent illumination are shown in FIGURES 14-16
- FIGURES 14 and 15 depict an uncoated electrode array chip
- FIGURE 16 depicts an electrode array chip coated with a fluorescent membrane
- the chips prepared and used in the following example and comparative example were rectangular devices with a 16 (in the x-direction) by 64 (in the y- direction) array of 100 micron diameter platinum electrodes The total number of electrodes in these arrays was 1024 The dimensions of the chips were approximately 0 5 cm (x-direction) by 2 3 cm (y-direction), and the total surface area of the chips was approximately 1 square centimeter The electrodes in each array were approximately 250 microns apart in the x-direction and approximately 350 microns apart in the y-direction, measured from the center of the electrodes
- Each electrode in the array was capable of being addressed independently using an SRAM cell (static random access memory), a standard art-recognized way to independently address electric circuitry in an array
- SRAM cell static random access memory
- the SRAM cell was located next to the electrodes in the electrical circuitry associated with electrode
- Each electrode in the array had four separate switchable voltage lines that attached to it allowing each electrode in the array to be switched independently from one voltage line to another
- the voltage was arbitrary and was set by an external voltage source
- the chips were made by a 3 micron process using hybrid digital/analog very large scale integration (VLSI)
- VLSI very large scale integration
- One skilled in the art would be familiar with such a process and could easily prepare a chip for use in accordance with the present invention See, Mead, C . Analog VLSI and Neural Systems. Addison- Wesley (1989)
- the circuitry used was CMOS (complimentary metal-oxide silicon) based and is also well known to those of ordinary skill in the art
- the chips were controlled by at least one Advantech PCL-812 digital I/O card (in the computer) that was driven by a Pentium based personal computer
- These digital I/O cards can be obtained from Cyber Research, Branford, Connecticut
- the chip is connected through interface hardware, i e , an interface card, to the I/O card
- the software for driving the I/O card can easily be written by one of ordinary skill in the art DC voltage for powering the chips was provided by the PCL-812 and/or a Hewlett-Packard E3612A DC power supply Voltage for the electrodes was supplied by the PCL-812 card and/or by an external Keithley 2400 source-measure unit
- the electrode array chips were designed so that the bond pads for all of the on-chip circuitry were located at one end of the long side of the chips See FIGURES 18a and 18b
- the chips were attached to a standard 121 pin PGA (pin grid array) package that had been sawn in half so that approximately 2 cm of the chip extended out from the end, analogous to a diving board See FIGURE 18b PGA packages can be obtained from Spectrum Semiconductor Matenals, San Jose, California Connecting wires ran between the bond pads on the chip and the contacts (bond pads) on the PGA package
- the bond pads on the chip, the connecting wires, and the contacts on the PGA package were covered with epoxy for protection and insulation See cut away in FIGURE 18a
- the section of the chips that extended into the air contained the electrode array and was not covered by epoxy This section of the chips was available for dipping into solutions of interest for chemical synthesis at the electrodes at the surface of the chip
- One of ordinary skill in the art could easily set up and design chips appropriate for use in accordance with the present invention
- One of the above described electrode array chips comprising 16x64 platinum electrodes was used for this example As indicated above, the chip contained 13 hardwired electrodes located at one end of the long side of the chip, however, these hardwired electrodes were not involved in this example
- the model chemical system used in this example to demonstrate localization and selective deprotection using electrochemically generated reagents involved attaching fluorescent labeled streptavidin molecules, a well- known variety of avidin, obtainable from Vector Laboratories, Burlingame California, to a membrane overlaying the electrode array chip via a trityl linker molecule
- the overlaying membrane used was polysacchande-based
- the trityl linker molecule used was acid labile, i e , labile to protons, and detached from the overlaying membrane in the presence of protons, taking with it the attached fluorescent labeled streptavidin molecule More specifically, the trityl linker molecule used was a modified 44'd ⁇ methoxytr ⁇ tyl molecule with an exocyclic active ester obtained from Perseptive Biosystems, Frammgham Massachusetts Experimental Procedure Preparation of the chip for attachment of molecules
- the chip was coated/mod if led with an overlaying membrane of a polysaccha ⁇ de-based material Specifically, a polygalactoside was used as the overlaying membrane material in this example The polygalactoside membrane was dip coated onto the chip Attachment of the trityl linker molecules
- the trttyl linker molecule used for this example was a modified 4 4'-d ⁇ methoxytr ⁇ tyl molecule with an exocyclic active ester, specifically the molecule was N-succ ⁇ n ⁇ m ⁇ dyl-4- [b ⁇ s-(4-methoxyphenyl)-chloromethyl]-benzoate
- the synthesis and use of this molecule is described in A Versatile Acid-Labile Linker for Modification of Synthetic Biomolecules, by Brian D Gildea, James M Coull and Hubert Koester, Tetrahedron Letters. Volume 31 , No 49, pgs 7095-7098 (1990)
- the trityl linker molecules were attached to the polysacchande membrane via immersion of the polysacchande membrane coated chip in a DMF solution containing 0 5M of tertbutyl ammonium perchlorate, 0 75M of 2,4,6-coll ⁇ d ⁇ ne and 0 2M of the trityl linker
- the immersion of the polysacchande membrane coated chip in the DMF linker solution lasted for 30 minutes at ambient temperature
- dipping or coating according to any method known to one of ordinary skill in the art would be acceptable
- the trityi linker coated chip was then washed with DMF to remove any remaining reactants
- the trityl linker coated chip was washed in an aqueous 0 1 M sodium phosphate buffer that was adjusted to pH 8 0, and dried Attachment of the fluorescent dye labeled molecules
- the trityl linker coated chip was then immersed in an aqueous solution of fluorescent dye (Texas Red) labeled streptavidin molecules having a concentration of 50 micrograms per milhliter and allowed to remain in this solution for one hour at ambient temperature. During this immersion, the linker molecule was derivatized and the fluorescent dye labeled streptavidin molecules were attached to the linker molecules.
- fluorescent dye Texas Red
- the chip containing fluorescent dye labeled streptavidin molecules was then washed with an aqueous 0.1M sodium phosphate buffer that was adjusted to pH 8.0 to remove remaining reactants, and dried.
- the chip was now ready for use in the electrochemical process of the invention, i.e., the selective deprotection step.
- the prepared chip was immersed in a 0.05M aqueous sodium phosphate buffer solution to enable electrochemical generation of reagents.
- a voltage difference of 2.8 volts was applied to select electrodes (alternating in a checkerboard pattern) for approximately 10 minutes, causing protons to be generated electrochemically at the anodes.
- the anodes became dark because the trityl linker previously bound proximate to the anodes dissociated from the anodes and the fluorescent labeled streptavidin molecules were washed away.
- the extent to which this occurred at the anodes and not at the cathodes in the checkerboard pattern, is a measure of the chemical crosstalk occurring between the electrodes in the array. That is, if chemical crosstalk were occurring, the cathodes would also be dark because the protons would have migrated and dissociated the trityl linkers at the cathodes.
- the bright electrodes indicate the presence of a Texas Red labeled streptavidin molecule bound to a linker molecule at the electrode and the dark electrodes (anodes) indicate the lack of a Texas Red labeled streptavidin molecule bound to a linker molecule at the electrode
- FIGURES 20 and 21 FIGURE 20 having been taken using a 4x objective with an integration time of 2 seconds
- FIGURE 21 having been taken using a 10x objective with a 500 millisecond integration time
- one chip was processed using the selective deprotection procedure in accordance with the present invention using a buffering solution, and the second chip was processed using a selective deprotection procedure varying only in that the electrolyte used in the Examples of Southern (WO 93/22480, filed November 1 1 , 1993) replaced the buffering solution of the present invention
- FIGURE 17 is a photomicrograph taken under the same conditions as FIGURE 14, but showing the hard wired electrodes used in this example Deprotection in accordance with the invention
- the attaching of the fluorescent dye labeled streptavidin molecules and the deprotection steps were also performed in accordance with Example 3, but a 20 mM aqueous sodium phosphate buffer solution was used instead of the 0.05M solution used in Example 3, to enable the electrochemical generation of reagents.
- the voltage that was applied between selected electrodes was 2 8 volts, which was applied for approximately 30 seconds
- FIGURE 22 shows the hardwired electrodes involved in this process, labeled as T1 , T2 and T4
- T1 was the counter electrode, i.e , the cathode
- T2 and T4 were the anodes where protons were generated upon the application of the electric current or voltage No voltage had been applied to the electrodes shown in FIGURE 22
- FIGURE 23 shows the same electrodes following denvatization or bonding with the fluorescent labeled streptavidin molecules. As is shown, electrodes T2 and T4 are bright, indicating the presence of a Texas Red labeled streptavidin molecule bound to a linker molecule proximate each of these electrodes
- FIGURE 24 shows the condition of anodes T2 and T4 following application of the voltage causing electrochemical generation of protons at the anodes and resultant dissociation of the trityl linker at these positions. Once dissociation occurred, the fluorescent labeled streptavidin molecules were washed away, leaving the anodes dark Notably, anodes T2 and T4 are darker than the neighboring electrodes, indicating no chemical crosstalk was occurring. As is shown by FIGURES 23 and 24, localization and selective deprotection were achieved at anodes T2 and T4, as was desired Deprotection using electrolyte of Southern (WO 93/24480)
- electrode T1 represented the cathode and electrode T4 represented the anode
- FIGURES 25a, 25b, 26a and 26b show that the membrane exhibited random and imprecise bright and dark areas These bright and dark areas indicate that the protons generated at the anode (electrode T4) are not confined or localized to the area proximate the electrode, causing significant dissociation of the trityl linker over the entire field of the photomicrograph T1 appears to have retained most of the fluorescence directly above the electrode This is explained by the base that is generated at the T1 cathode, which neutralized the acid generated proximate the T4 anode
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DK97932422T DK0910467T3 (en) | 1996-07-05 | 1997-07-03 | Electromechanical solid phase synthesis of polymers |
EP97932422A EP0910467B1 (en) | 1996-07-05 | 1997-07-03 | Electrochemical solid phase synthesis of polymers |
AU35884/97A AU734511B2 (en) | 1996-07-05 | 1997-07-03 | Electrochemical solid phase synthesis of polymers |
IL12789897A IL127898A0 (en) | 1996-07-05 | 1997-07-03 | Electrochemical solid phase synthesis of polymers |
CA002259523A CA2259523C (en) | 1996-07-05 | 1997-07-03 | Electrochemical solid phase synthesis of polymers |
DE69703841T DE69703841T2 (en) | 1996-07-05 | 1997-07-03 | ELECTROCHEMICAL SOLID PHASE SYNTHESIS OF POLYMERS |
AT97932422T ATE198427T1 (en) | 1996-07-05 | 1997-07-03 | ELECTROCHEMICAL SOLID PHASE SYNTHESIS OF POLYMERS |
JP50526298A JP4303319B2 (en) | 1996-07-05 | 1997-07-03 | Electrochemical solid-phase synthesis of polymers. |
HK99104849A HK1020540A1 (en) | 1996-07-05 | 1999-10-27 | Electrochemical solid phase synthesis of polymers |
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Also Published As
Publication number | Publication date |
---|---|
CA2259523A1 (en) | 1998-01-15 |
US6444111B1 (en) | 2002-09-03 |
ATE198427T1 (en) | 2001-01-15 |
IL127898A0 (en) | 1999-11-30 |
DE69703841D1 (en) | 2001-02-08 |
JP2000514802A (en) | 2000-11-07 |
TW593334B (en) | 2004-06-21 |
ES2156000T3 (en) | 2001-06-01 |
CA2259523C (en) | 2010-01-12 |
EP0910467B1 (en) | 2001-01-03 |
HK1020540A1 (en) | 2000-05-12 |
DK0910467T3 (en) | 2001-05-21 |
JP4303319B2 (en) | 2009-07-29 |
AU734511B2 (en) | 2001-06-14 |
DE69703841T2 (en) | 2001-08-09 |
AU3588497A (en) | 1998-02-02 |
EP0910467A1 (en) | 1999-04-28 |
JP2006291359A (en) | 2006-10-26 |
JP4740020B2 (en) | 2011-08-03 |
ZA975891B (en) | 1998-07-23 |
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