Physiologic Instruments (http://www.physiologicinstruments.com)designs and manufactures instrumentation, Ussing Chamber Systems and Data Acquisition products for studying transport across epithelial barriers. Transepithelial voltage, short-circuit current and resistance are measured using single and multi-channel voltage/current clamps that may be directly connected to Acquire & Analyze for automating data collection and analysis.

The larger multi-channel clamps include a Master Control section to enable control of all clamp channels from a single set of switches. Tissues and cell cultures are studied using our EasyMount Ussing Chamber Systems consisting of individual Ussing chambers, a heating block for temperature control, needle vales for adjustment of gas flow for oxygenation and stirring, and Ag/AgCI reference electrodes for measuring transepithelial voltage and passing current. These systems have been designed for ease of use, easy cleanup, and flexibility. Cell Cultures and a wide variety of tissue types may be mounted on special inserts that simply slide into position in the chamber. Electrodes insert from the front permitting unrestricted access for fluid sampling. Physiologic Instruments is a leader in equipment for epithelial barrier research.

From Wikipedia, the free encyclopedia

An Ussing chamber is a scientific tool used to measure the short-circuit current as an indicator of net ion transport taking place across an epithelium. Ussing chambers are increasingly being used to measure ion transport in both native tissue, like gut mucosa and monolayer of cells grown on permeable supports.

The chamber is named for the Danish physiologist Hans Ussing (1911-2000), who invented the first one in the 1950s.

An Ussing chamber consists of two halves that are clamped together having the epithelia (sheet of mucosa or monolayer of epithelial cells grown on permeable supports). Note: Epithelia are polar in nature, i.e., they have an apical or mucosal side and a basolateral or serosal side. Thus in an Ussing chamber it is possible to isolate the apical side from the basolateral side. The two half chambers are filled with equal amount of symmetrical Ringer solution in order to remove any chemical, mechanical and electrical driving forces. In any epithelium there is ion transport taking place across it be it from apical side to basolateral side or vice-versa. This ion transport produces a potential difference (voltage difference) across the epithelium. The voltage difference generated is measured using two voltage electrodes that are placed nearer to the tissue/epithelium. And this voltage is cancelled out by injecting the current using another two current electrodes that are placed away from the epithelium. This amount of current injected is called Short-circuit current (Isc) and is the exact measure of net ion transport taking place across the epithlium.

The epithelial ion transport is the factor of greatest interest in research involving Ussing chambers. The voltage that is measured as the voltage difference is a result of this ion transport and the voltage difference is easy to measure accurately. The epithelium pumps ions from one side to the other and the ions leak back through so called tight junctions that are situated between the epithelial cells. In order to measure the ion transport an external current is applied as described above. However by canceling the voltage as described above you get an underestimation of the true ion transport. What you do is to short circuit at the voltage measuring electrodes and not at the epithelium itself. The resistance between the voltage electrodes external to the epithelium has also to be accounted for in some way. The Isc as measured above is always an underestimate of the ion transport and the error can be as much as 10 times. The error is dependent mostly on the chambers. With the type of chambers correctly suggested by Ussing the error is large. This error is often estimated and compensated for by measuring without the tissue present. Such compensations often lead to uncertain values. Many methods exist for better estimation of the ion transport. They involve using alternating current in form of sinus shaped current using several frequencies, square wave pulses, sharp impulses and even random noise. Detailed information and simplified descriptions about these methods can be found on the internet at "The Ussing Pulse project".