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Product Information
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January 24, 2020
Microinjection is the process of transferring genetic materials into a living cell using glass micropipettes or metal microinjection needles. Glass micropipettes can be of various sizes with tip diameters ranging from 0.1 to 10 µm. DNA or RNA is injected directly into the cell’s nucleus. Microinjection has been successfully used with large frog eggs, mammalian cells, mammalian embryos, plants and tissues. Microinjection has been expensive, can be a slow process and requires skilled personnel, but new technologies are making it even more reliable, repeatable and affordable.
Pronuclear injection, inserting DNA or RNA into the nucleus of a fertilized oocyte to create transgenic organisms, lets researchers study the role of particular genes. This horizontal gene transfer can insert genetic material from the same species or a different one. When using genetic material from different species, a chimera is created. If the genetic material is NOT integrated into the genome of the offspring, it is considered transient transformation and is not passed to subsequent generations. However, if the new genetic material is transferred to future generations, then we have a stable transformation. In this case, the gene inserted by microinjection is called as the transgene, and the organism that develops after a successful gene transfer is called as transgenic.
So, transgenic animals are the results of experimentation that integrates genetic material (DNA) into their germ line. These transgenic animals are invaluable in the quest to identify the functions of specific factors in homeostatic systems through the over-expression or under-expression of a modified gene. In many cases transgenic animals are dependent on the laboratory environment for survival.
Microinjection is a highly reproducible and repeatable method of introducing genetic material into a nucleus. (Qingsong Xu. Micromachines for Biological Micromanipulation. Springer Publication, 2018.) Compared with other methods of genetic manipulation, microinjection optimized the materials used and eliminates a lot of waste. (Chow YT, Chen S, Wang R, et al. Single Cell Transfection through Precise Microinjection with Quantitatively Controlled Injection Volumes. Sci Rep. 2016;6:24127. Published 2016 Apr 12. doi:10.1038/srep24127.) Because the materials used are minimized, there is also a reduction in the cost of the materials needed. With the tight control of the microinjection process, the researcher can obtain the precise integration of the recombinant gene in a limited number of copies.
Products for Efficient Microinjection
WPI offers a broad range of laboratory equipment used for microinjection applications. Our injection systems have been serving scientist for over 30 years. Additionally, WPI offers a variety of accessories for microinjection including pumps, pullers, pipetters, microscopes and more. One of the most popular pumps for zebrafish and adherent cell microinjection is the PV820 Pneumatic PicoPump and its newer cousins the MICRO-ePUMP, the μPUMP and the PV850.
Injection Pumps
Originally, the PV820 and PV830, Pneumatic PicoPumps, were designed to simplify intracellular injection. The microinjection offering was redesigned in 2020 from the ground up to offer ease of use, ensure repeatable operations and cover a broader range of applications. You get touch screen control, footswitch operation and a unit that takes up precious little bench space. Researchers get repeatable microinjections in volumes ranging from picoliters to nanoliters. Our microinjectors offer eject and hold pressure. To guard against injectant dilution, the hold pressure prevents backfilling of the pipette via capillary action, keeping the injectant meniscus at the pipette tip. WPI also has popular pumps for injecting in the picoliter and nanoliter ranges.
Pinpoint Cell Penetrator
The WPI MICRO-ePORE™ pinpoint cell penetrator is a simple and versatile system that can be used for efficient microinjection of a diverse array of compounds and biomolecules into oocytes and pre-implantation stage mammalian embryos. Patent pending Flutter Electrode Technology assists in small, clean, precise membrane penetration without tearing or damaging the membrane when one is working on the microinjection of transgenic animals or cell manipulation. WPI's MICRO-ePORE™ Pinpoint Cell Penetrator offers several advantages over traditional electroporation for the purpose of microinjection.
- The pinpoint cell penetrator uses a much lower voltage to open a port into the cell membrane.
- Electroporation is a shotgun approach that opens many pores in the cell membrane. In contrast, the pinpoint cell penetrator targets a specific area of the cell membrane at the very point of microinjection.
- Survivability of embryos is significantly higher when using pinpoint cell penetration versus electroporation.
Microscope
WPI's PZMIII-MI Microscope with Illuminated Base and Articulating Mirror is perfect for microinjection and transfection. It includes a standard stereo microscope head mounted on a research grade Brightfield/Darkfield pole type stand. It has a large stable work surface and a rotatable lens/mirror system which provides transmitted LED intensity illumination. The sliding mirror is gimbaled, allowing for a full range of movement front to back, as well as rotation. The mirror rotates 360º on one axis and can slide for further lighting effect directionally, front to back. A knob on the right of the base adjusts the mirror and a locking ring holds the desired mirror position. Vary the microscope illumination from Brightfield LED to Darkfield LED at an appropriate angle using the articulating mirror. It is an effective tool for viewing live bacteria. At low magnifications, view tissues, cells or embryo transfer where oblique, transmitted illumination is critical.
Microinjection is a revolutionary tool in the age of modern science. These methods allow any lab to incorporate the technique of microinjection into their experimental repertoire.
Whether DNA, RNA or protein is the molecule of interest, microinjection provides a means of studying function within the context of the living cell. The technology is remarkably accessible and relatively inexpensive, while the possibilities are virtually endless. -
December 20, 2019
The purpose of this article is to describe a new cleaning procedure for thoroughly cleaning WPI flowcells, including Liquid Waveguide Capillary Cells (LWCCs), UltraPath flowcells and optical cuvettes. The image (right) shows a 3000 series LWCC with a MiniStar pump and the LWCC injection system placed on top of it.
Preparation of Chemicals
All chemical reagents should be of at least ACS-Grade, preferably HPLC-Grade. This procedure involves the use of caustic and flammable reagents. Consult the manufacturer’s MSDS for necessary safety precautions.
Cleaning Solution #1:
0.5M Potassium Hydroxide in 100% Ethanol (e.g.: 7 g KOH in 250mL EtOH). After thoroughly mixing, filter the solution through a 20µm pore size filter.
Cleaning Solution #2:
100% Methanol, HPLC grade
Cleaning Solution #3:
Ultrapure water, Type I per ASTM D1193-99 or equivalent...more
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August 21, 2019
Are you looking for a microliter or sub-microliter and high precision syringe that holds needles as small as 36 gauge (G), in addition to having the capability to connect to quartz tubing?
WPI’s NanoFil is the answer. We offer NanoFil syringes with NanoFil needles or the option to connect the NanoFil syringe to quartz tubing to use in research studies, mainly involving sub-microliter volume injections into animal tissues...more
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August 02, 2019
The new WPI MICRO-ePORE™ pinpoint cell penetrator is a simple and versatile system that can be used to facilitate microinjection of a diverse array of compounds and biomolecules into oocytes and pre-implantation stage mammalian embryos. Patent pending Flutter Electrode Technology assists in small, clean, precise membrane penetration without tearing or damaging the membrane. It results in substantially increased viability of embryos. In this quick video, Dr. Pelczar from the Center for Transgenic Models in Switzerland demonstrates the ease of cell penetration using the new MICRO-ePORE™.
Video footage courtesy of Dr. Pawel Pelczar, Head of CTM, University Basel, Switzerland...more
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July 22, 2019
WPI offers custom fiber optic cables and assemblies. This video show how to create a custom ordering code to designate what you need. If you have any questions about ordering Fiber Optic Cables and Assemblies for your laboratory or application, just give us a call (866-606-1974) or email us at [email protected].
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June 19, 2019
The new WPI MICRO-ePORE™ Pinpoint Cell Penetrator is a simple and versatile system that can be used for efficient microinjection of a diverse array of compounds and biomolecules into oocytes and pre-implantation stage mammalian embryos. Patent pending Flutter Electrode Technology assists in small, clean, precise membrane penetration without tearing or damaging the membrane. Here Gabe sets up the system and connects all the components.
Unpacking Your MICRO-ePORE™ System
Connecting Your MICRO-ePORE™ System
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June 19, 2019
For intracellular dual or differential studies, WPI's Duo773 has separate negative capacity controls and built-in active filtering that allows the precise balancing of time constants for artifact-free differential measurement. It comes complete with two probe headstages, 1015Ω and 1011Ω probes to monitor signals from ion-specific micro-electrodes as well as KCl-filled electrodes. Jim shows you how to safely unpack and properly setup your new Duo773.
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May 17, 2019
Optical measurements are important to researchers. Discover today how WPI has contributed with the recent release of Qualified Fiber.
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May 02, 2019
EndOhm Chambers Re-engineered
EndOhm chambers are designed for making accurate TEER measurement of epithelial and endothelial cell cultures. The design keeps the top and bottom electrodes at a fixed gap and maintains the sample (cell culture insert) in a centered position inside. This design minimizes the variability associated with electrode positioning and gap, making EndOhm chambers more accurate and capable of generating reproducible results. WPI made some recent upgrades to the EndOhm chambers. - The NEW EndOhm Chamber is made of GLASS, making it easier to clean and more...more
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March 13, 2019
Prior to sterilizing surgical instruments, it is a good idea to make sure you have cleaned them to remove blood, tissue and all other organic material. If soiled materials dries or is baked onto the instruments, it will interfere with microbial inaction and can compromise the sterilization process.
Cleaning is the removal of foreign material (e.g., soil and organic material) from objects and is normally accomplished using water with detergents or enzymatic products.
The most common type of mechanical automatic cleaner is the ultrasonic cleaner. Ultrasonic cleaners are used in conjunction with detergents and enzymatic cleaners. Ultrasonic cleaning removes particulates by cavitation (bubbles) and implosion. Waves of acoustic energy are transmitted in aqueous solutions and disrupt the bonds that hold particulate matter to surfaces.
When selecting...more
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February 22, 2019
WPI EndOhm chambers are used with WPI's EVOM2 meter for making TEER (transepithelial electrical resistance) measurements. Here Subhra shows the difference between hanging cell culture inserts and standing cell culture inserts.
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February 21, 2019
The WPI EVOM2 meter is used to measure TEER (transepithelial electrical resistance) in cell culture inserts. The STX2 electrodes with a static length may cause damage to Snapwell inserts. Here Subhra demonstrates how to use the adjustable STX3 electrode to prevent damage to your cell culture inserts.
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February 21, 2019
WPI's EndOhm chambers are used with WPI's EVOM2 meter to measure TEER (transepithelial electrical resistance) in cell culture inserts. Three chamber sizes are available for 6-well plates, 12-well plates and 24-well plates. Here Subhra demonstrates how to choose an EndOhm chamber to match the cell culture inserts you are using.
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February 21, 2019
WPI EndOhm chambers are used with WPI's EVOM2 meter for making TEER (transepithelial electrical resistance) measurements. After heavy use your background resistance measurement may start to rise. Your electrodes may need to be resurfaced to remove buildup of proteins, sugars and biological materials. Here Subhra demonstrates how to clean and resurface your EndOhm chambers.
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February 21, 2019
WPI EndOhm chambers are used with WPI's EVOM2 meter for making TEER (transepithelial electrical resistance) measurements. Each EndOhm chamber comes with a "spacer" disk for calibrating the gap between the two chamber electrodes. A consistent gap ensures reliable measurements. Here Subhra shows how to calibrate your chambers.