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2012 — CFX96 Touch Deep Well™ Real-Time PCR Detection System
The CFX96 Touch Deep Well system offers industry-leading performance with easy-to-use software for large-volume reactions. |
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2011 — CFX96 Touch™ and CFX384 Touch™ Real-Time PCR Detection Systems
The CFX96 Touch and CFX384 Touch systems introduce a new level of user friendliness with the inclusion of an integrated touch screen in the C1000 Touch thermal cycler chassis. The systems feature easy run setup using streamlined menu navigation and, in an industry first, monitoring of real-time amplification traces without a computer attached. |
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2011 — CFX Connect™ Real-Time PCR Detection System
The CFX Connect system delivers excellent thermal and optical performance for all SYBR® Green/EvaGreen and duplex experiments in a 96-well format. Utilizing the powerful, easy-to-use CFX Manager™ software, the CFX Connect system offers a complete package to analyze even the most challenging experiments. |
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2011 — C1000 Touch™ Thermal Cycler
The C1000 Touch thermal cycler builds on the advanced performance and features of the C1000™ thermal cycler by adding a large color touch screen and redesigned interface. This thermal cycler is compatible with six interchangeable reaction modules, including two for real-time PCR. |
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2011 — T100™ Thermal Cycler
The compact 96-well T100 thermal cycler offers a comprehensive package of features, including an easy-to-use touch screen, thermal gradient, and reliable performance. |
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2008 — CFX96™ and CFX384™ Real-Time PCR Instrumentation
The CFX96 and CFX384 real-time PCR detection systems bring flexibility and ease of use to researchers performing high-throughput real-time PCR in a 96- or 384-well format. The solid state components provide sensitive detection for precise quantification and reliable performance. |
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2008 — 1000-Series of PCR Instrumentation
The 1000-series includes the C1000 thermal cycler with innovative features such as the protocol autowriter, the S1000™ thermal cycler, and the high-performance six-channel CFX96 and five-channel CFX384 real-time PCR detection systems. This platform has a patented, reduced-mass sample block for faster time to target temperature and the only gradient-enabled dual block on the market. |
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2005 — iQ™5 Real-Time PCR Detection System
The iQ5 system offers five-target real-time PCR detection, powerful data analysis options, and advanced multiplex performance to researchers seeking a highly flexible system for real-time PCR analysis. |
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2005 — MJ Mini™ Personal Thermal Cycler
The compact yet powerful 48-well MJ Mini cycler boasts features found in larger instruments, including unparalleled thermal performance and thermal gradient technology. |
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2005 — MiniOpticon™ Two-Color Real-Time PCR Detection System
The MiniOpticon two-color real-time PCR detector is the most compact real-time PCR system available. It uses a fixed array of 48 LEDs and photodiodes for sensitive, reliable quantification. |
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2004 — Chromo4™ Real-Time PCR Detection System
The Chromo4 detector offers users innovative technology in a compact design, bringing four-color real-time detection capability and options for increased throughput to the DNA Engine® thermal cycler. |
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2003 — MyiQ™ Real-Time PCR Detection System
The single-color MyiQ real-time PCR detection system is an affordable option for new users of real-time PCR technology as well as those who must handle increasing workload demands involving gene expression. This real-time PCR system is a modular upgrade to the highly flexible iCycler® thermal cycler. |
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2002 — MyCycler™ Personal Thermal Cycler
The MyCycler thermal cycler set a new standard for personal cyclers with a high-resolution graphical display, intuitive graphic-based programming, and exceptional thermal performance. |
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2002 — DNA Engine Opticon® 2 Real-Time PCR Detection System
The DNA Engine Opticon 2 system has the same standard features as the original DNA Engine Opticon system, with the added capability of two-color detection using a fixed array of 96 aqua-colored LEDs and two PMTs for detection. |
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2001 — DNA Engine Opticon® Real-Time PCR Detection System
The novel DNA Engine Opticon detector enables quantitative and melt curve analysis as well as other precision temperature–controlled measurements on the DNA Engine thermal cycler. Its unique rugged design uses LED excitation and PMT detection to deliver high sensitivity with no moving parts. |
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2000 — DNA Engine Dyad® Thermal Cycler
The dual-bay DNA Engine Dyad cycler added ease-of-use features, such as a window-driven interface, point-and-click programming, real-time temperature graphs, and a high-density color display, to the range of compatible options for tens of thousands of DNA Engine owners. |
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1999 — iCycler iQ® Real-Time PCR Detection System
The iCycler iQ system brought the first modular upgrade to the real-time PCR market. It features four-target detection, the use of filtered excitation from a tungsten halogen lamp, and filtered emission detected by a high-pixel-density CCD camera. |
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1999 — iCycler® Thermal Cycler
The iCycler thermal cycler is a state-of-the-art thermal cycler developed to provide the highest performance standards and easiest user interface on the market. Interchangeable reaction blocks, unparalleled ease of use via the large VGA screen, and an upgrade path to real-time PCR make the iCycler instrument the most innovative and flexible thermal cycler available. |
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1999 — Thermal Gradient Feature
To help researchers optimize reactions, we offered a thermal gradient feature to combine unsurpassed accuracy with sophisticated dynamic ramping. Efficient empirical determination of annealing and denaturation temperatures has never been easier or more precise. |
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1997 — Remote Alpha Dock™ System
The Remote Alpha Dock system was the first to address the demand for hands-free unattended amplification by offering automation-friendly options for thermal cycling. The Remote Alpha Dock system and Power Bonnet™ automated lid (first offered in 1996) offer creative solutions to integrating thermal cyclers into robotic systems. |
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1996 — Slide Chambers™ Dual Alpha™ Unit
In 1996, we adapted slide-cycling technology for microscope slides to the DNA Engine line of cyclers by developing the Slide Chambers unit. This Alpha™ unit has the capacity to independently control two 16-chamber slide towers, making it ideal for researchers wishing to add slide cycling or microarray hybridization capability to an existing DNA Engine cycler. |
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1995 — DNA Engine Tetrad® Thermal Cycler
The DNA Engine family grew, adding an instrument that incorporated four DNA Engine cyclers into a single, minimal footprint. We also designed and introduced the configuration for 384-well blocks and vessels, which became the standard in high-throughput DNA sequencing and the thermal cycling backbone of the Human Genome Project. |
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1994 — DNA Engine® Thermal Cycler
Our first user-configurable cycler introduced swappable blocks accommodating a wide variety of vessel formats. Its revolutionary multisensor, multizone, thermal control delivers superior thermal uniformity and unprecedented speed. The DNA Engine architecture allows new block types to be added as research needs evolve. |
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1991 — MiniCycler® Personal Thermal Cycler
The first personal-sized cycler set new standards for speed, convenience, and affordability. It was also the first cycler small enough to be practical for field research. Technologically, it pioneered the use of Joule-assisted Peltier thermal control and precision thermistor sensors with NIST-traceable accuracy. |
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1988 — PTC-100® Thermal Cycler
The premier Peltier-effect thermal cycler — this compact and reliable instrument delivers precision and is easy to use. The novel Peltier heating and cooling technology established a widespread reputation for innovation and versatility. |
