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SuperAldehyde Microarray Substrate Slides (Box of 5)


Price: $144.00
Item Number: SMAF

Quantity Discounts - Order a quantity in the range below to receive the discount

QuantityAmount
4 to 19$136.80
20 to 39$129.60
40 to 199$122.40
200 to 1000$115.20
Arrayit SuperAldehyde Microarray Substrate Slides provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, high covalent binding capacity using Arrayit’s widely-published original aldehyde surface chemistry and low background fluorescence, 1 x 25 x 76 mm, box of 5.

Microarray Slides - SuperAldehyde, SuperAldehyde 2, MirrorAldehyde, and MirrorAldehyde 2 Microarray Substrate Slides for Research, Life Sciences and Microarray Testing Applications

microarray-aldehyde
Arrayit is pleased to offer SuperAldehyde, SuperAldehyde 2, MirrorAldehyde, and MirrorAldehyde 2 Microarray Substrate Slides featuring highly reactive aldehyde groups for Schiff's base coupling of DNA and protein molecules, as well as highly reflective mirror backing and barcode options for customer convenience and versatility. Arrayit substrate slides offer polished atomically smooth glass surfaces (±20 angstroms) for the ultimate in silicon dioxide homogeneity and data precision. Arrayit SuperAldehyde and MirrorAldehyde series slides are manufactured to “open platform” dimensions (1 x 25 x 76 mm) for compatibility with a wide range of commercial microarray printers and scanners, and cleaned at the atomic level and treated with ultra-pure aldehyde surface chemistry for superior covalent coupling efficiency and low background. Heat-sealing in anti-static packaging improves shelf life and eliminates electrostatic accumulation. Arrayit SuperAldehyde series slides have a proprietary corner chamfer for unambiguous side and end orientation, which greatly improves usability during printing, processing and scanning. These surfaces provide a surface of choice for high-density DNA and protein microarray manufacturing applications using contact and non-contact printing methods.

Table of Contents

  • Introduction
  • Quality Control
  • Product Description
  • Technical Notes
  • Glass Specifications
  • Short Protocols
  • Complete Protocols
  • Protein SuperAldehyde Short Protocol
  • Protein SuperAldehyde Complete Protocol
  • Recommended Equipment and Reagents
  • Technical Assistance
  • Troubleshooting Tips
  • Scientific Publications
  • Ordering Information
  • Warranty

Introduction
Congratulations on taking a big step towards improving the affordability, quality and speed of your genomics, biomedical, pharmaceutical and agricultural research. This booklet contains all of the information required to take full advantage of Arrayit Super Microarray Substrate Slides.

Quality Control
Arrayit takes every measure to assure the quality of our Arrayit microarray substrate slides. The finest microarray biochip cleanroom research was used to develop these products. Rigorous quality control monitoring on a substrate-by-substrate basis guarantees that each these products conforms to the highest industry standards.

Product Description
Arrayit microarray substrate slides provide the highest quality glass microarray printing substrates at an affordable price. All of our substrate slides are manufactured in cleanrooms with 0.1 µm filtered air, and temperature and humidity control. A cleanroom setting provides a quality of custom microarray substrate slides that conform to the highest industry standards.

Users will appreciate the following:

  • Polished to atomic surface smoothness of ±20 angstroms over 1.0 µm2 (series 2)
  • Superior substrate flatness of ±0.036 mm over 25 x 76 mm
  • Polished glass sets a standard in the microarray industry
  • Homogenous SiO2 groups provide superior silane reactivity
  • Reactive aldehyde density of 1 x 10^13 groups per mm^2
  • Vastly superior to unpolished optical quality glass and microscope slides
  • Ultimate surface for ultra-high density DNA and protein microarray manufacturing including micro-mirror, photolithography and contact printing
  • Used by high-volume microarray manufacturing companies
  • Used by overseas companies for microarray testing
  • Topological smoothness ensures uniform hybridization layer and scanning
  • Manufactured in cleanrooms
  • Ultra-low intrinsic fluorescence and background noise
  • Can be used as a starting point for gel and membrane coatings (e.g. polyacrylamide and nitrocellulose)
  • Used by major academic core facilities
  • Open platform dimensions (1 x 25 x 76 mm) compatible with all major brands of microarrayers and scanners
  • Precise physical dimensions (0.940 mm ± 0.025 mm x 25 ± 0.2 mm x 76 ± 0.3 mm)
  • Proprietary corner chamfer (1.4 mm) provides unambiguous side and end orientation to simplify printing and processing
  • Finished edges enhance user safety
  • Excellent refractive index, transmission and hardness specifications
  • Anti-static packaging improves usability
  • Offered with or without barcodes
  • Custom laser and chrome fiducials available upon request
  • Product arrives “ready to print” with no additional processing required
  • High-volume 100,000 piece per month manufacturing capabilities

Technical notes
The “substrate slide noise” is the sum of all non-sample and non-instrument contributions to the background reading including intrinsic fluorescence of the substrate and reflection off the substrate surface. Because substrate slide noise is measured using a scanning or imaging device, as a practical matter substrate noise typically includes intrinsic fluorescence and reflection, as well as all of the sources of instrument noise (e.g. dark current, shot noise, electronic noise and optical noise). Most modern scanners and imagers have very low instrument noise, which means that intrinsic fluorescence and reflection dominate the substrate noise reading. Substrate slide noise is obtained by measuring the fluorescent reading of the substrate slide “right out of the box” and prior to reacting the substrate slide with a fluorescent sample. Please do not confuse substrate slide noise (i.e. background before the substrate is reacted with a sample) and microarray noise (i.e. background after the substrate has been reacted with a sample), as these two readings are very different. For nearly all applications and assays, microarray noise greatly exceeds substrate noise and therefore concerns about substrate noise are entirely academic because the latter does not contribute to the total background reading observed when the product is used in real experiments (see below).

The table below summarizes the substrate noise (actually intrinsic fluorescence + reflection + instrument noise) observed with our substrates. Substrate noise readings were taken at very high sensitivity (90% laser and 90% photomultiplier tube or PMT), settings that are well beyond those used for most biological experiments. Typical instrument settings for biological experiments with the ScanArray Express are 20-40% laser power and 80% PMT. The ScanArray Express has 20- to 30-fold greater sensitivity than the ScanArray 3000, and correspondingly the substrate noise readings are up to 30-fold higher on the Express compared to the 3000. Unmodified glass substrate slides (i.e. SuperClean) produce the lowest substrate noise readings, followed SuperEpoxy, SuperAmine, and SuperAldehyde. Organic treatments (e.g. epoxy, amine and aldehyde) increase substrate noise compared to naked glass because organic molecules formed during derivation fluoresce at an extremely low but detectable level. For nearly all applications and assays, the non-sample contributions to background noise (intrinsic fluorescence, reflection, and instrument noise) are much less than the background noise contributed when the substrate or microarray is reacted with a fluorescent sample. In these cases, substrate noise (though it exists) is irrelevant to the use of our products, because it does not contribute in any measurable way to the background reading of the reacted chip. In rare cases involving extremely low background samples or gene expression measurements of rare transcripts, substrate noise may approach sample noise in magnitude.

For best results, please test our products in the context of real experiments rather than simply taking note of the fact that our substrate slides manifest noise that is greater than plain glass. All substrate slides that contain an organic treatment or coating will produce some intrinsic fluorescence and reflection. Please also test our product “right out of the box” rather than waiting hours or days to measure the noise. Fluorescent contaminants present in non-cleanroom air produced by cleaning agents, solvents, hydrocarbons and instruments can elevate the noise. Airborne particles including dust and other particulates greatly elevate the background reading because these particles are highly reflective in the presence of laser and white excitation light. Understanding the technical details of our products is important and we recommend that you commit these concepts to working memory as you proceed with your experiments.

Table 1. Substrate slide noise

Product

Average substrate noise (ScanArray 3000)

Maximum allowable substrate noise (ScanArray 3000)

Average substrate noise (ScanArray Express)

Maximum allowable substrate noise (ScanArray Express)

SuperAldehyde

278

500

729

2,000

MirrorAldehyde

217

375

568

1,500

Average substrate noise readings are expressed as average fluorescent counts over 1.0 cm^2 areas measured on an average of 100 different substrates from at least 10 different production lots. The maximum allowable substrate noise is the highest reading that is permissible for a lot to pass this step in our quality control process. Instruments were set at 90% photomultiplier tube (PMT) and 90% laser for all readings. ScanArray Instruments were provided courtesy of PerkinElmer (Boston, MA).

Glass Specifications:
The glass used for these substrates has been manufactured exclusively for this application. These are not treated microscope slides. Glass substrate slides of this optical quality and smoothness are offered at much higher prices by most commercial providers.

1. Standard substrate slide format (1 x 25 x 76 mm)
2. Chamfer at upper right corner allows unambiguous substrate slide orientation
3. Polished to atomic smoothness of <50 Å
4. Low refractive index (400-700 nm)
5. High light transmission efficiency (380-700 nm)
6. Proprietary glass formulation much harder than normal glass

background-hybridization
Figure 1. Improved hybridization results with probe pre-heating and BSA addition. Shown are two microarrays of PCR products printed on SuperAldehyde Substrate Slides (Arrayit) with Stealth microarray printing pins (SMP3B) and a Cartesian 5500 robot. Printed microarrays were washed to remove unbound material and the double-stranded DNAs were denatured by boiling for 3 min in distilled water. The microarrays were hybridized in hybridization cassettes (Arrayit) for 5 hrs at 42°C under 18 mm x 18 mm optically flat cover slips with 5.0 µl probe solution containing 5X SSC + 0.2% SDS + 0.2 mg/ml bovine serum albumin (BSA) + 2 µM 15-mer oligonucleotide. The 15-mer oligonucleotide contained a Cy3 label on the 5' end. Hybridized microarrays were washed twice for 5 min each in 2X SSC + 0.2% SDS at 25°C, once for 1 min in 2X SSC at 25°C and spun dry for 1 min at 500 x g. Microarrays were scanned at 100% photomultiplier tube (PMT) and 100% laser settings with a ScanArray 3000 (Packard Instruments). (Left) Probe solution at 25°C applied to microarray and (Right) Probe solution pre-heated to 42°C and applied IMMEDIATELY to microarray. Improved results are easily observed in the right image compared to left image, including stronger signals, reduced background and increased uniformity. Probe pre-heating and BSA addition can both improve microarray data.

atomic-force-microscopy.6
Figure 2. Atomic Force Microscopy (AFM) analysis. Shown are AFM scans for SuperClean (left), SuperAmine (center) and SuperAldehyde (right) microarray substrate slides. Data are coded to a rainbow intensity scale such that red data represents 5.0 nm or 50 angstroms. The substrate slides have an average smoothness of 2.0 nm or 20 angstroms, which corresponds to the about 10 silicon dioxide bonds.

Technical Assistance
Please contact us if you have any comments, suggestions, or if you need technical assistance. By electronic mail: arrayit@arrayit.com (under the subject heading please type "Arrayit technical assistance"). By email: arrayit@arrayit.com, Monday–Friday PST 8:00am - 8:00pm. Please remember that we want to hear about your successes!

Short Protocol (SuperAldehyde)
1. (Optional) Use an oil-free air stream to remove particles from anti-static packaging exterior.
2. (Optional) Transport de-contaminated product into cleanroom.
3. Cut the anti-static bag above the zip-lock seal.
4. Place the slide box on the lab bench and open carefully.
5. Print microarrays using either contact printing or non-contact printing.
6. Process the printed microarrays.
7. React printed microarray with a labeled sample.
8. Scan microarray with a fluorescence detection device.

schiffs-base
Figure 3. SuperAldehyde Coupling Chemistry. SuperAldehyde Substrate Slides contain primary aldehyde groups attached covalently to the glass surface (rectangles). Primary amino linkers (NH2) on the DNA (red ribbons) attack the aldehyde groups (left panel) forming covalent bonds (center panel). Attachment is stabilized by a dehydration reaction (drying in low humidity) which leads to Schiff base formation (right panel). Specific and covalent end attachment provide highly stable and accessible attachment of DNA for gene expression and genotyping applications. Proteins can also be attached to SuperAldehyde, though the SuperEpoxy surface is generally preferred for protein microarrays.

Complete Protocol (SuperAldehyde)
1. (Optional) Use an oil-free air stream to remove particles from the anti-static packaging exterior. This step is optional and only required for users who manufacture microarrays in a cleanroom environment. Shipping material can contaminate the exterior packaging material with particulates that can be transferred into the cleanroom. These particulates can be removed from the sealed plastic shipping envelope using a stream of pressurized air from an oil-free source. Arrayit offers a Microarray Air Jet (Cat. MAJ) that works well for this purpose.

2. (Optional) Transport the de-contaminated product into the cleanroom. This step is optional and only required for users who manufacture microarrays in a cleanroom environment. Carry the de-contaminated SuperAldehyde Microarray Substrate Slides in the sealed anti-static shipping envelope into the cleanroom changing area. Change into cleanroom attire and enter the cleanroom facility.

3. Open the anti-static shipping envelope by cutting with scissors just above the zip-lock. Open the anti-static shipping envelope and remove the slide box.

4. Carefully open the slide box after placing it on a lab bench. Use the notch at the base of the slide box to gently lift the cover upward. Do not attempt to open the slide box upside down as this will cause the slides to empty into the lid of the box and may damage or break the glass.

5. Print the microarrays using either contact printing or ink-jet type technology. Load the SuperAldehyde Microarray Substrate Slides onto the printing deck of the microarrayer, with the corner chamfer located at the upper right corner as shown in Figure 5. Because the SuperAldehyde coating is applied preferentially to the top side of the slide, do not attempt to print on the back side of the slide. The printing convention places spot number one in the upper left corner opposite the corner chamfer (see Figure 5). Print the microarrays until all of the samples have been deposited. The maximum recommended printing area is 24 mm x 75 mm.

6. Chemically couple the biomolecules to the SuperAldehyde surface, process the printed microarrays to remove unbound material, and block unreacted aldehyde groups to reduce non-specific binding of labeled reactants. Optimal protocols for proteins, small molecules, extracts, cells and other molecules have been developed. One protocol that works well for printing and attaching single- and double-stranded nucleic acids to the SuperAldehyde surface uses DNA modified with primary amines that form Schiff base covalent bonds with reactive aldehydes on the Substrate surface. (1) attach a C6 amino modification (Glen Research) to the 5' end of each oligonucleotide; amino modifications can be added to double stranded DNAs by PCR with primers that contain amino modifications, (2) re-suspend the amino-linked DNAs in 1X Micro Spotting Solution Plus, (3) print the amino-linked DNAs onto SuperAldehyde Microarray slide Substrates with Stealth microarray printing pins, (4) allow the slides to dry for 12 hrs at room temperature (~25°C) at <30% relative humidity, (5) rinse the printed slides twice in 0.1% SDS and once in dH2O for 2 min each wash at room temperature (22-25°C) to remove unbound DNA, (6) rinse the slides once in dH2O for 2 min at room temperature with vigorous agitation, (7) transfer the slides into boiling dH2O at 100°C for 3 min to denature the DNA (8) plunge the substrates into ice cold 100% ethanol for 30 sec to fix the denatured DNA, and (9) dry the processed slides by centrifugation for 10 sec in a Microarray High Speed Centrifuge or for 1 min at 500 x g in a traditional centrifuge (e.g Savant). A 1 hour pre-hybridization treatment with BlockIt buffer prior to hybridization can be used to reduce background in all fluorescent DNA and protein based assays. Additionally, for DNA microarrays only, treatment with sodium borohydride (NaBH4) can be used to reduce unreacted aldehyde groups to alcohols. This can lower fluorescent background in some assays. For sodium borohydride reduction, follow Steps 1-6 exactly as written above, and then proceed as follows: (7) reduce for 5 min with gentle mixing in 500 ml sodium borohydride reducing solution [dissolve 1.5 g NaBH4 in 350 ml phosphate buffered saline (PBS) and add 150 ml 100% ethanol after the NaBH4 dissolves to improve reducing efficiency], (8) rinse 2 times for 1 min each in 500 ml dH2O, (9) rinse 2 times for 1 min each in 500 ml 0.1% SDS, (10) transfer the Substrates into boiling dH2O at 100°C for 3 min to denature the DNA (11) plunge the substrates into ice cold 100% ethanol for 30 sec to fix the denatured DNA, and (12) dry the processed slides by centrifugation for 10 sec in a Microarray High Speed Centrifuge or for 1 min at 500 x g in a traditional centrifuge (e.g Savant). High Throughput Wash Stations work well for all wash steps except those involving elevated temperatures (e.g. boiling).

7. React the processed microarray with a labeled probe sample. Probes can be complex mixtures of labeled or fluorescent nucleic acids, proteins, antibodies, extracts and other substances. Microarray reactions are best performed under glass cover slips at a volume of 2.0 µl per cm^2 of cover slip. Pre-heating the probe to 42-65°C just prior to hybridization can greatly reduce background. For nucleic acid reactions, buffers typically contain 5X SSC or 6X SSPE and 0.1% SDS and are preformed at 37-65°C depending on the nature of the targets and probes. The addition of 0.2 mg/ml BSA (Worthington) to the hybridization reaction reduces background. UniHyb Hybridization Solution (Arrayit) also works well at a wide range of temperatures and reduces background hybridization is many cases. Hybridization Cassettes (Arrayit) provide a convenient reaction environment, and automation can also be used. Following the microarray reaction, unbound probe material is removed by several successive washes in dilute buffers at room temperature (~25°C).

8. Scan the microarray with a fluorescence detection device. Suitable detection systems accommodate the 1 x 25 x 76 mm format and have a pixel resolution corresponding to ~1/10 the diameter of each microarray feature. Popular detection systems are available from Arrayit.

protein-coupling
Figure 4. Protein coupling to the SuperAldehyde surface. SuperAldehyde Substrate Slides contain primary aldehyde groups attached covalently to the glass surface. Primary amino linkers (NH2) on proteins attack the aldehyde groups (left) forming covalent bonds (right panel). Attachment is stabilized by a dehydration reaction (drying in low humidity) that leads to Schiff base formation. Covalent attachment provides highly stable and accessible attachment of protein for various protein assays including protein-protein interactions studies, protein profiling, and sandwich assays. Proteins can also be attached to SuperEpoxy.

slide-orientation
Figure 5. Correct Substrate Slide Orientation. Shown is a graphic of two Arrayit Microarray Substrate Slides, showing the correct and incorrect orientation for use. In the correct orientation (blue graphic), the chamfer is located in the upper right corner and samples should be printed on the side facing upward, which is the same side that contains the word “Correct!”. In the incorrect orientation (red graphic), the chamfer is located in the upper left corner, placing the backside facing upward, which is the side that contains the word “Incorrect!”. Only one side of Arrayit Microarray Substrate Slides should be used for printing. Please print on the correct side only.

supermask_microarray
Figure 6. SuperAldehyde 2 surface chemistry can be purchased in the SuperMask hydrophobic mask format. A wide variety of well patterns are available.

SuperAldehyde Protein Microarray Short Protocol (Steps 1-7):
1. Suspend protein samples in Protein Printing Buffer at 0.1-0.5 µg/µl.
2. Print protein samples onto SuperAldehyde Substrate Slides.
3. Block using BlockIt buffer and process the microarrays.
4. React the processed microarrays with fluorescent samples.
5. Wash the microarrays to remove unreacted fluorescent material.
6. Scan the microarrays to produce a fluorescent image.
7. Quantitate and model the fluorescent data.

SuperAldehyde Protein Microarray Complete Protocol (Steps 1-7):
1. Suspend protein samples in Protein Printing Buffer. Obtain 0.2-1.0 µg/µl protein samples in 1X phosphate buffered saline (PBS) and add an equal volume of 2X Protein Printing Buffer. Mix the samples by pipetting up and down 10 times. Protein samples should be free of aggregates and particulates that can clog printing devices and impair attachment to the microarray substrate. Aggregates and particulates can be removed by centrifugation or filtration. A 50kD protein at 1 µg/µl concentration has a concentration of 20 µM. At 30% coupling efficiency, a 20 µM protein will produce a target density of 10^11 proteins per mm^2 of substrate slide. Certain proteins or protein extracts are more stable at 4°C. Keeping the protein samples cool may improve protein stability. Stability can also be improved in some cases by the addition of protease and phosphatase inhibitors, or by the use of SpotBot 4 Personal Microarrayers or NanoPrint 2 Microarrayers equipped with a cooled platen and/or plate cooling. Make sure protein samples are mixed thoroughly before printing.

2. Print protein samples onto SuperAldehyde Substrate Slides. The surface couples proteins extremely efficiently owing to the high reactivity of the aldehyde groups to primary amines (see Fig. 4). To complete coupling of protein to the surface wait several hours to overnight after printing at low humidity prior to using the microarrays. Proteins retain protein-protein binding activity after the spots have dried. Printed microarrays should be stored unprocessed to protect coupled molecules. Protein Printing Buffer contains components that stabilize printed proteins. Processing should be performed just prior to use for best performance.

3. Block and process the printed protein microarrays. Once the printing process is complete, wash the printed microarrays to remove unbound protein molecules and buffer components from the surface. Protein binding is extremely stable and the microarrays can be washed, blocked and reacted without sufficient loss of coupled protein. For best results block the surface for 1 hour using BlockIt blocking buffer. If BlockIt is not immediately available, a 1 hour incubation at room temperature in a buffer containing 1X PBS + 1% bovine serum albumin (BSA) can be used with satisfactory results. A High Throughput Wash Station or an equivalent device can be used for washes. Blocking can be performed with very gentle buffer agitation and the stir plate set on a low speed or under a coverslip. The blocking step will couple reactants to the aldehydes on the surface and prevent background fluorescence. After blocking, wash the microarrays to remove the excess blocking buffer. Washing three times for 2 min each at room temperature with 1X PBS in a High Throughput Wash Station works well.

4. React the processed microarrays with fluorescent samples. Processed microarrays containing coupled target proteins can be reacted with fluorescent samples to study protein-protein interactions or for gene expression monitoring. Binding reactions can be performed in 1X BlockIt buffer for best results. Alternatively 1X PBS + 0.5% BSA + fluorescent proteins diluted 1:1,000 or labeled cellular extracts. Fluorescent samples can be incubated as a droplet on the printed microarray, underneath a cover slip, or in a microfluidics chamber. A 60-minute incubation at room temperature is usually sufficient to obtain strong binding and intense fluorescent signals. A Hybridization Cassette can be used to prevent sample evaporation during prolonged (1-12 hour) binding reactions.

5. Wash the microarrays to remove un-reacted fluorescent material. Once the binding reaction between the bound target proteins and the fluorescent protein probe molecules is complete, wash the microarray to remove the unbound fluorescent material. Washes can be performed three times for 5 min each at room temperature in 1X PBS. After the wash procedure, excess buffer should be removed from the surface by tapping the substrate on a lint-free cloth or by centrifugation with a Microarray High-Speed Centrifuge.

6. Scan the microarray to produce a fluorescent image. The fluorescent protein microarray can be scanned or imaging using any of a number of high quality commercial detection instruments from Arrayit, Molecular Devices, Agilent and other commercial providers. Instrument settings can be adjusted to optimize the imagine process.

7. Quantitate and model the fluorescent data. Protein microarray data from the fluorescent image can be quantified, mined and modeled using many different commercial software packages including Arrayit MAPIX®.

barcodeSuperAldehyde substrate slides are offered with barcodes:
ArrayIt® barcodes are 12 mm x 19 mm and are affixed just above the bottom edge of the 1 x 25 x 76 mm substrate slide (smaller custom barcodes are available upon request).

Recommended Equipment and Reagents
NanoPrint™ 2 Microarrayers
SpotBot® 4 Personal Microarrayers
InnoScan® Microarray Scanners
Array Plate Multi-Well Hybridization Stations
Microarray Hybridization Cassettes
High Throughput Wash Station
Microarray High-Speed Centrifuge
Protein Printing Buffer
BlockIt Blocking Buffer
Microarray Air Jet
Microarray Cleanroom Wipes
PCR Purification Kits
Micro-Total RNA Extraction Kit
MiniAmp mRNA Amplification Kit
Indirect Amino Allyl Fluorescent Labeling Kit
Universal Reference mRNA
Green540 and Red640 Reactive Fluorescent Dyes
Hybridization Buffers

Technical Assistance

Please contact us if you have any comments, suggestions, or if you need technical assistance. We can be reached at all hours by electronic mail (arrayit@arrayit.com) from Monday-Friday 8:00 AM-8 PM PST. Please remember that we want to hear about your successes!

 

Troubleshooting Tips
Weak signal - poor coupling of printed material to the slides or poor labeling of probe sample

High background fluorescence - drying of labeled sample during reaction or washes or improper reaction or wash conditions

 

Scientific Publications

Click here and here for Arrayit aldehyde scientific publications.

 

Ordering Information

Product

Description

Catalog ID

SuperAldehyde Microarray Substrate Slides (Box of 25)

Arrayit SuperAldehyde Microarray Substrate Slides provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, high covalent binding capacity using Arrayit’s widely-published original aldehyde surface chemistry and low background fluorescence, 1 x 25 x 76 mm, box of 25.

SMA

SuperAldehyde Microarray Substrate Slides Barcoded (Box of 25)

Arrayit SuperAldehyde Microarray Substrate Slides Barcoded provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, high covalent binding capacity using Arrayit’s widely-published original aldehyde surface chemistry and low background fluorescence, 1 x 25 x 76 mm, box of 25 with barcodes.

SMABC

SuperAldehyde Microarray Substrate Slides (Box of 5)

Arrayit SuperAldehyde Microarray Substrate Slides provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, high covalent binding capacity using Arrayit’s widely-published original aldehyde surface chemistry and low background fluorescence, 1 x 25 x 76 mm, box of 5.

SMAF

SuperAldehyde Microarray Substrate Slides Barcoded (Box of 5)

Arrayit SuperAldehyde Microarray Substrate Slides Barcoded provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, high covalent binding capacity using Arrayit’s widely-published original aldehyde surface chemistry and low background fluorescence, 1 x 25 x 76 mm, box of 5 with barcodes.

SMAFBC

MirrorAldehyde Microarray Substrate Slides (Box of 25)

Arrayit MirrorAldehyde Microarray Substrate Slides provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, high covalent binding capacity using Arrayit’s widely-published original aldehyde surface chemistry and low background fluorescence, and a highly reflective backside mirror coating for 2-10X signal enhancement, 1 x 25 x 76 mm, box of 25.

MRA

MirrorAldehyde Microarray Substrate Slides Barcoded (Box of 25)

Arrayit MirrorAldehyde Microarray Substrate Slides Barcoded provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, high covalent binding capacity using Arrayit’s widely-published original aldehyde surface chemistry and low background fluorescence, and a highly reflective backside mirror coating for 2-10X signal enhancement, 1 x 25 x 76 mm, box of 25 with barcodes.

MRABC

MirrorAldehyde Microarray Substrate Slides (Box of 5)

Arrayit MirrorAldehyde Microarray Substrate Slides provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, high covalent binding capacity using Arrayit’s widely-published original aldehyde surface chemistry and low background fluorescence, and a highly reflective backside mirror coating for 2-10X signal enhancement, 1 x 25 x 76 mm, box of 5.

MRAF

MirrorAldehyde Microarray Substrate Slides Barcoded (Box of 5)

Arrayit MirrorAldehyde Microarray Substrate Slides Barcoded provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, high covalent binding capacity using Arrayit’s widely-published original aldehyde surface chemistry and low background fluorescence, and a highly reflective backside mirror coating for 2-10X signal enhancement, 1 x 25 x 76 mm, box of 5 with barcodes.

MRAFBC

SuperAldehyde 2 Microarray Substrate Slides (Box of 25)

Arrayit SuperAldehyde 2 Microarray Substrate Slides provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, ultra-high covalent binding capacity using Arrayit’s series 2 enhanced aldehyde surface chemistry and extremely low background fluorescence, 1 x 25 x 76 mm, box of 25.

SMA2

SuperAldehyde 2 Microarray Substrate Slides Barcoded (Box of 25)

Arrayit SuperAldehyde 2 Microarray Substrate Slides Barcoded provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, ultra-high covalent binding capacity using Arrayit’s series 2 enhanced aldehyde surface chemistry and extremely low background fluorescence, 1 x 25 x 76 mm, box of 25 with barcodes.

SMA2BC

SuperAldehyde 2 Microarray Substrate Slides (Box of 5)

Arrayit SuperAldehyde 2 Microarray Substrate Slides provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, ultra-high covalent binding capacity using Arrayit’s series 2 enhanced aldehyde surface chemistry and extremely low background fluorescence, 1 x 25 x 76 mm, box of 5.

SMA2F

SuperAldehyde 2 Microarray Substrate Slides Barcoded (Box of 5)

Arrayit SuperAldehyde 2 Microarray Substrate Slides Barcoded provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, ultra-high covalent binding capacity using Arrayit’s series 2 enhanced aldehyde surface chemistry and extremely low background fluorescence, 1 x 25 x 76 mm, box of 5 with barcodes.

SMA2FBC

MirrorAldehyde 2 Microarray Substrate Slides (Box of 25)

Arrayit MirrorAldehyde 2 Microarray Substrate Slides provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, ultra-high covalent binding capacity using Arrayit’s series 2 enhanced aldehyde surface chemistry and extremely low background fluorescence, and a highly reflective backside mirror coating for 2-10X signal enhancement, 1 x 25 x 76 mm, box of 25.

MRA2

MirrorAldehyde 2 Microarray Substrate Slides Barcoded (Box of 25)

Arrayit MirrorAldehyde 2 Microarray Substrate Slides Barcoded provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, ultra-high covalent binding capacity using Arrayit’s series 2 enhanced aldehyde surface chemistry and extremely low background fluorescence, and a highly reflective backside mirror coating for 2-10X signal enhancement, 1 x 25 x 76 mm, box of 25 with barcodes.

MRA2BC

MirrorAldehyde 2 Microarray Substrate Slides (Box of 5)

Arrayit MirrorAldehyde 2 Microarray Substrate Slides provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, ultra-high covalent binding capacity using Arrayit’s series 2 enhanced aldehyde surface chemistry and extremely low background fluorescence, and a highly reflective backside mirror coating for 2-10X signal enhancement, 1 x 25 x 76 mm, box of 5.

MRA2F

MirrorAldehyde 2 Microarray Substrate Slides Barcoded (Box of 5)

Arrayit MirrorAldehyde 2 Microarray Substrate Slides Barcoded provide an advanced aldehyde surface for the microarray market, featuring polished atomically smooth glass surface, corner chamfer for easy side orientation, ground edges, nucleophile-reactive aldehyde surface chemistry for binding to DNA and other molecules with reactive primary amines, uniformly-spaced reactive groups, ultra-high covalent binding capacity using Arrayit’s series 2 enhanced aldehyde surface chemistry and extremely low background fluorescence, and a highly reflective backside mirror coating for 2-10X signal enhancement, 1 x 25 x 76 mm, box of 5 with barcodes.

MRA2FBC

 

Warranty

Arrayit life sciences microarray substrate slides are sold for research purposes only and are good for six months after receipt of product if stored in a sealed slide box at room temperature. Arrayit brand products have been scientifically developed and are sold for research purposes. Extreme care and exact attention should be practiced in the use of the materials described herein. All Arrayit brand products are subject to extensive quality control and are guaranteed to perform as described when used properly. Any performance issues should be reported to Arrayit immediately. Arrayit’s liability is limited to the replacement of the product, or a full refund. Any misuse of this product is the full responsibility of the user, and Arrayit makes no warranty or guarantee under such circumstances. Pricing may vary up to 30% due to costs associated with distribution, import taxes, duties, customs clearance and shipping.

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