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The Microplate Market:Layout 1 26/3/09 14:28 Page 85 The microplate market:Layout 1 26/3/09 14:28 Page 85 Microplates The microplate market past, present and future microplates today – the global market Microplates and the peripheral markets of liquid handling and detection technologies exist within almost all laboratories performing assays. This article discusses what, if any, are their growth expectations and whether there are new technologies on the horizon that could make the microplate obsolete. oday, microplates are one of the most com- range, from hand-held pipettors that can address By Dr Peter Banks monplace of all disposable labware. Its either individual or multiple wells simultaneously T most common format consists of 96 indi- to semi- to full-automation solutions that dispense vidual wells arranged in eight rows and 12 multiple reagents and/or aspirate contents from columns with dimensions defined by the American full columns of microplate wells or complete National Standards Institute1 through an initiative microplates simultaneously. This market is slightly sponsored by the Society for Biomolecular Sciences larger than the microplate market itself and is esti- in 1996. There are a myriad of microplate types, mated to be $600 million. Numerous companies including different well densities from several wells provide products into this market including Tecan, to several thousand wells per microplate; coloured Eppendorf, Mettler-Toledo, PerkinElmer and microplates for different optical readouts (ie black Beckman Coulter. for fluorescence; white for luminescence); solid Microplate readers range from single mode bottom wells or clear bottom wells for top- or bot- detection devices akin to the first absorbance read- tom-reading fluorescence, respectively; different ers that appeared on the market more than 30 plastics (polystyrene, polypropylene, etc); various years ago to highly sophisticated multi-mode read- coatings (ie reduction of non-specific binding, tis- ers capable of performing absorbance, lumines- sue-culture treated, etc) and so on. cence and a wide range of fluorescence-based The annual global market for microplates is modes including intensity, fluorescence resonance approaching $500 million globally and dominated energy transfer (FRET), time-resolved fluores- by several large companies such as Corning, cence (TRF), the variant TR-FRET and fluores- Greiner Bio-One, NUNC and a large number of cence polarisation. Some readers have been smaller companies focusing on specialty products designed to process microplates in a matter of sec- or microplates designed for specific applications. onds for applications such as high throughput In addition to this market, peripheral markets drug screening. This market is slightly smaller focus on the provision of instrumentation, in the than the microplate market at about $300 million. form of liquid handling devices and microplate The top five companies in this market are readers, specifically designed to use microplates as PerkinElmer, Inc, Thermo Fisher Scientific, MDS analysis vessels. Analytical Technologies, Tecan and BioTek The liquid handling market encompasses a wide Instruments, Inc. Drug Discovery World Spring 2009 85 The microplate market:Layout 1 26/3/09 14:28 Page 86 Microplates Figure 1 The beginning and growth of the had performed them manually with his wire loops Timeline of microplate and market2 more than a decade earlier. complementary instrument The first microplate was hand-made in 1951 by Enzyme-linked immunosorbent assays (ELISA) development Hungarian physician, scientist and inventor were developed in the mid-1970s as an alternative Gyula Takátsy. A serious influenza epidemic in to radio-immunoassay (RIA) techniques. ELISAs Hungary required physicians to find a fast, eco- fuelled growth of the use of immunoassays in both nomic and reliable test method for the identifi- research and clinical markets, and microplates cation of the influenza virus. Standard test meth- were considered the best vessels in which to per- ods involving reagent tubes and dilution series form the assays. This growth also created the need were too unreliable, tedious, expensive and for microplate readers. LabSystems (now part of time-consuming. Using a side-by-side arrange- Thermo Fisher Scientific) developed the Multiskan ment of wire metering loops, Takátsy was able photometer specifically for reading 96-well to fill multiple sample tubes with a defined sam- microplates used in this market. This device marks ple volume at the same time, thus significantly the beginning of the microplate reader market that increasing the sample throughput of his labora- we know today. tory. This model was soon replaced with an easy The microplate, liquid handling and reader mar- to use geometry with 8 x 12 wells – the first 96- kets grew rapidly in the 1980s with numerous well microplate (Figure 1). companies offering products ranging from differ- These acrylic plates were individually machined ent coatings on microplates, filter plates and a wide and thus difficult to produce in large quantities. array of instrumentation. BioTek Instruments Injection moulding of plastics was developed in the entered the market at this time with the EL310 1960s and was the manufacturing basis of the first microplate absorbance reader and the EL402 commercial 96-well microplate, Microtiter, offered microplate washer (Figure 2), both specifically by Cooke Labs (now known as Dynex designed for performing ELISAs. The 1980s also Technologies) in 1965. Moulded acrylic saw the development of new enabling technologies microplates quickly were replaced with poly- such as the polymerase chain reaction (PCR) by styrene, the most common plastic used in Kary Mullis. This again led to the development and microplates today. Microplate usage was largely use of new microplates, specifically designed for driven by applications in virology and serology, for performing PCR. example in hemaglutination inhibition where the With the advent of high throughput screening microplates were useful vessels for performing seri- (HTS) for small molecule drug discovery in the al dilutions. The first automated liquid handling 1990s, the market demanded microplates with device, the Autotiter, was developed in 1967 by higher well densities for increased sample through- Astec Inc (now known as Tomtec), and simply put. The pharmaceutical industry widely adopted automated serial dilutions much the way Takátsy HTS methodologies in the early 1990s where large 86 Drug Discovery World Spring 2009 The microplate market:Layout 1 26/3/09 14:28 Page 88 Microplates libraries of small molecules (up to 106 compounds Difficulties, particularly in liquid handling, limited at the time) were screened for binding to putative early adoption of microplates with higher densities drug targets, typically as recombinant purified pro- than 384-well, which could still use devices teins. The explosion of genomic technology at the designed for 96-well operation. By the time liquid time created a vast number of possible drug targets dispensing technologies could deliver sub- leading to a bottleneck in the drug discovery microlitre volumes with adequate precision neces- process at HTS. To alleviate this bottleneck, the sary for operation in 1536-well densities, the need 384-well microplate was developed which for ultra high throughput was limited to a small increased the number of wells by a factor of four segment of the market. However, the benefits in on the same footprint as a 96-well microplate. miniaturisation available with higher well density, These 384-well microplates were rapidly adopted, namely smaller assay volumes leading to reduction and spurred the development of even higher well in costs of reagents, fuelled the development of low densities such as 1,536- and 3,456-well volume 96- and 384-well microplates. microplates by Whatman (now part of GE In this decade, other scientific advances and new Healthcare), and by a collaboration between technologies have led to new uses of microplates. Whatman and Aurora Biosciences (now known as For example, the development of RNAi technology Vertex Pharmaceuticals), respectively in 1996. has led to genomic screening efforts on a scale sim- ilar to HTS. The old HTS paradigm of screening large libraries of small molecules against purified proteins has been replaced, in large part, with assays of greater biological relevance using cells where the drug target is in a milieu more represen- tative of what would occur in the human body. This has driven the need for specialty microplates for cell usage, liquid handling devices that can dis- pense and wash cells and microplate readers that can measure optical readouts from the bottom of the microplate well. In addition, many researchers want more information per well through multi- plexing efforts. A number of technologies have been developed to achieve this including Luminex Corporation’s xMAP technology that can measure up to 100 different analytes per well The future for microplates and peripheral markets In 2008, most industry pundits forecast continued Figure 2 (above) growth for the microplate and peripheral markets EL402 and EL310 microplate instruments from BioTek at least in the next few years. The current global Instruments, circa 1984 recession may confuse these forecasts somewhat, yet the stimulus package from President Obama, Figure 3 (right) which provides a bonus of $21.5 billion in science Human Genome U133 Plus 2.0 and research spending3, should relieve at least US array. Courtesy of Affymetrix markets. Economic
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