How Gene Microarrays Work & How Our Program Saves You Time & Money
Our microarray reader leasing program includes the following benefits:
- Leasing reduces the upfront cost of buying equipment and allows you to make payments over time
- Payments may be 100% tax deductible*, which yields you additional savings
- Instrument downtime is eliminated with our comprehensive repair coverage
- We handle the admin work associated with equipment purchasing and maintenance
- With the cash saved through our program, companies are better able to reinvest in their core business and operations (staffing, inventory, marketing/sales, etc.)
*Please consult your tax advisor to determine the full tax implications of leasing equipment.
All equipment brands/models are available
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Detection & Types
The core principle behind microarrays is hybridization between two DNA strands, the property of complementary nucleic acid sequences to specifically pair with each other by forming hydrogen bonds between complementary nucleotide base pairs. A high number of complementary base pairs in a nucleotide sequence means tighter non-covalent bonding between the two strands. After washing off non-specific bonding sequences, only strongly paired strands will remain hybridized. Fluorescently labeled target sequences that bind to a probe sequence generate a signal that depends on the hybridization conditions (such as temperature), and washing after hybridization. Total strength of the signal, from a spot (feature), depends upon the amount of target sample binding to the probes present on that spot. Microarrays use relative quantitation in which the intensity of a feature is compared to the intensity of the same feature under a different condition, and the identity of the feature is known by its position.
Many types of arrays exist and the broadest distinction is whether they are spatially arranged on a surface or on coded beads:
- The traditional solid-phase array is a collection of orderly microscopic “spots”, called features, each with thousands of identical and specific probes attached to a solid surface, such as glass, plastic or silicon biochip (commonly known as a genome chip, DNA chip or gene array). Thousands of these features can be placed in known locations on a single DNA microarray.
- The alternative bead array is a collection of microscopic polystyrene beads, each with a specific probe and a ratio of two or more dyes, which do not interfere with the fluorescent dyes used on the target sequence.
DNA microarrays can be used to detect DNA (as in comparative genomic hybridization), or detect RNA (most commonly as cDNA after reverse transcription) that may or may not be translated into proteins. The process of measuring gene expression via cDNA is called expression analysis or expression profiling.
Applications include: Gene expression profiling, comparative genomic hybridization, geneID, chromatin immunoprecipitation, damID, SNP detection, alternative splicing detection, fusion genes microarray, tiling array, double-stranded B-DNA microarrays, double-stranded Z-DNA microarrays, and multi-stranded DNA microarrays.
Microarrays can be manufactured in different ways, depending on the number of probes under examination, costs, customization requirements, and the type of scientific question being asked. Arrays may have as few as 10 probes or up to 2.1 million micrometre-scale probes from commercial vendors.
Spotted vs. in situ Synthesized Arrays
Microarrays can be fabricated using a variety of technologies, including printing with fine-pointed pins onto glass slides, photolithography using pre-made masks, photolithography using dynamic micromirror devices, ink-jet printing, or electrochemistry on microelectrode arrays.
In spotted microarrays, the probes are oligonucleotides, cDNA or small fragments of PCR products that correspond to mRNAs. The probes are synthesized prior to deposition on the array surface and are then “spotted” onto glass. These arrays may be easily customized for each experiment, because researchers can choose the probes and printing locations on the arrays, synthesize the probes in their own lab (or collaborating facility), and spot the arrays. They can then generate their own labeled samples for hybridization, hybridize the samples to the array, and finally read the arrays with their own microarray scanner.
In oligonucleotide microarrays, the probes are short sequences designed to match parts of the sequence of known or predicted open reading frames. Although oligonucleotide probes are often used in “spotted” microarrays, the term “oligonucleotide array” most often refers to a specific technique of manufacturing. Oligonucleotide arrays are produced by printing short oligonucleotide sequences designed to represent a single gene or family of gene splice-variants by synthesizing this sequence directly onto the array surface instead of depositing intact sequences.
Two-Channel vs. One-Channel Detection
Two-color microarrays or two-channel microarrays are typically hybridized with cDNA prepared from two samples to be compared (e.g. diseased tissue versus healthy tissue) and that are labeled with two different fluorophores. Fluorescent dyes commonly used for cDNA labeling include Cy3, which has a fluorescence emission wavelength of 570 nm (corresponding to the green part of the light spectrum), and Cy5 with a fluorescence emission wavelength of 670 nm (corresponding to the red part of the light spectrum). The two Cy-labeled cDNA samples are mixed and hybridized to a single microarray that is then scanned in a microarray scanner to visualize fluorescence of the two fluorophores after excitation with a laser beam of a defined wavelength. Relative intensities of each fluorophore may then be used in ratio-based analysis to identify up-regulated and down-regulated genes.
In single-channel microarrays or one-color microarrays, the arrays provide intensity data for each probe or probe set indicating a relative level of hybridization with the labeled target. However, they do not truly indicate abundance levels of a gene but rather relative abundance when compared to other samples or conditions when processed in the same experiment. Each RNA molecule encounters protocol and batch-specific bias during amplification, labeling, and hybridization phases of the experiment making comparisons between genes for the same microarray uninformative. The comparison of two conditions for the same gene requires two separate single-dye hybridizations.
We Provide a Wide Variety of DNA Microarray Reader Leases
This off-balance sheet financing structure provides three options at the end of the term. The lessee has the option to return the equipment to the lessor, renew at a discounted rate, or purchase the instrument for the fair market value. Monthly payments are also 100% tax deductible which yields additional cash savings.
If you recently purchased equipment, Excedr can offer you cash for your instrument and convert your purchase into a long-term rental. This is called a sale leaseback. If you’ve paid for equipment within the last ninety days, we can help you recoup your investment and allow you to make low monthly payments. This also frees up cash in your budget rather than tying it down to the instrument.
MICROARRAY SCANNER MANUFACTURERS AND MODELS ON THE MARKET
- Molecular Devices: GenePix, GenePix 4300A, GenePix 4400A, GenePix 400B, GenePix 4100A
- ThermoFisher Scientific & Affymetrix: GeneChip Scanner 3000 7G System, GeneChip Scanner 3000 7G Whole-Genome Association System, GeneChip Scanner 3000 TG System, GeneChip System 3000Dx, GeneTitan Multi-Channel (MC) Instrument, Axiom Analysis Suite, GeneChip miRNA 4.0 Assay, GeneChip Hybridization Oven 640 and 645, GeneChip Fluidics Station 450
- Illumina: NexSeq 550 System, iScan System
- Agilent: G2565 Series, SureScan DX Microarray Scanner, G5761AA, SureScan Microarray Scanner, G4900DA
- Roche: NimbleGen MS200 Microarray Scanner
- Applied Microarrays: Vidia, Crocodile miniWorkstation
- Innopsys: InnoScann 300, InnoScan 710, InnoSCann 710-IR, InnoScan 910, InnoScan 1100, Mapix, Mapix-CS
- Arrayit: ArrayPix Plate Microarray Scanner, SpotLight CCD Microarray Scanner, Spotware Colometric Microarray Scanner
- Berthold Technologies: bScreen LB991, Label-Free Microarray System
- PerkinElmer: ScanRI MDx Scanner
- Bio-Rad: Bio-Plex 3D Suspension Array System
- Tecan: PowerScanner
- and more!
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Effect on Credit & Operating Capital
Leasing/renting does not hinder your future borrowing ability and allows you to keep your business credit line open for expansions, staffing, and other operational expenses. Additionally, it strengthens the cash flow of your business and keeps cash reserves free for business development opportunities.
Unlike traditional financing and leasing companies, the Excedr program can accommodate refurbished/reconditioned equipment in addition to demo units. If you are looking for additional cost-savings, we recommend considering this option.
Speed of Approval
Excedr’s program allows you to respond quickly as your need for equipment and technology arises. You can be approved with minimal documentation and have the equipment you need in operation and generating revenue for your business quickly.