Pipette

From Free net encyclopedia

A pipette (also called a pipet) is a laboratory instrument used to transport a measured volume of liquid. Pipettes are commonly used in chemistry and molecular biology research as well as medical tests. Pipettes come in several designs for various purposes with differing levels of accuracy and precision, from single piece flexible plastic transfer pipettes to more complex adjustable pipettes. A pipette works by creating a vacuum above the liquid-holding chamber and selectively releasing this vacuum to draw and dispense liquid.

Pipettes that dispense between 100 and 1000 μl are termed micropipettes, while macropipettes dispense a greater volume of liquid.

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Adjustable pipettes

Image:Single channel rack.jpg Also known as Gilson pipettes after inventor Warren Gilson, these are the most accurate and precise pipette designs. They operate by piston-driven air displacement. The vacuum is generated by the vertical travel of a metal piston within an airtight sleeve. As the piston moves upward, driven by the depression of the plunger, a vacuum is created in the space left vacant by the piston. Air from the tip rises to fill the space left vacant, and the tip air is then replaced by the liquid, which is drawn up into the tip and thus available for transport and dispensing elsewhere.

Sterile technique prohibits any liquid from coming into contact with the pipette. Instead, the liquid is drawn into and dispensed from a disposable pipette tip which is changed between transfers. Depressing the tip ejector button removes the tip, which is then disposed of safely in the appropriate container.

The plunger is depressed to both draw up and dispense the liquid. Normal operation consists of depressing the plunger button to the first stop while the pipette is held in the air. The tip is then submerged in the liquid to be transported and the plunger is released in a slow and even manner. This draws the liquid up into the tip. The instrument is then moved to the desired dispensing location. The plunger is again depressed to the first stop, and then to the second stop, or blowout, position. This action will fully evacuate the tip and dispense the liquid. In an adjustable pipette, the volume of liquid contained in the tip is variable; it can be changed via a dial or other mechanism, depending on the model. Some pipettes include a small window which displays the currently selected volume.

Certain considerations should be observed to ensure maximum accuracy and repeatability:

Operator consistency is paramount to repeatable operation. The necessity of operator practice and development of good pipetting practices and habits is absolute.
When drawing up liquid the tip should be dipped 3 to 5 mm below the surface of the liquid, always at a 90 degree angle.
When dispensing the pipette should be held at a 45 degree angle, and the tip placed against the side of the receiving vessel. Glass vessels are preferred; the surface tension of the glass provides additional torsion that results in complete evacuation of the tip.
The tip must never be wiped off or blotted in any way, even from the exterior, while liquid is in the tip. These actions tend to attract and thus bleed off some of the liquid, resulting in decreased accuracy and repeatability.
A dry tip should always be pre-wetted by drawing up and dispensing the chosen volume a minimum of three times. This action reduces the surface tension on the inside walls of the tip and also provides the proper level of inter-tip humidity, which reduces evaporation of the sample liquid.
For maximum accuracy, and especially necessary when calibrating the pipette, relative humidity in the ambient environment should be maintained between 50% and 75%, and in no case should the humidity be allowed to dip below 50%. This limits the rate of sample evaporation which can cause significant errors, especially at lower volumes.

The importance of operator skill cannot be overstated. A high-quality, well-calibrated pipette in the hand of a disinterested or untrained operator is an unreliable instrument. Additionally, there are four factors that can reduce the accuracy and repeatability of even highly-skilled operators, and these factors must be counteracted if optimal accuracy is to be achieved:

Heat from the operator's hand is absorbed through the handle of the instrument and transferred to the metallic components inside. If the pipette is operated continuously for a prolonged period of time this heat buildup becomes significant, causing the internal components to expand and changing the interplay between components. This reduces the consistency, accuracy, and repeatability of the instrument. The volume dispensed is dependent on the sizes of the piston and the springs that cause its travel. As these change in size the volume dispensed changes also. This effect is more pronounced in low-volume instruments. Additionally, the expansion of a metallic component that interacts with a non-metallic one that does not expand as readily in the presence of heat may cause the instrument to seem to stick, hang up, or react more slowly. Pipettes with thin handles are particularly susceptible to this phenomenon. Plumper handles are both more ergonomic and less likely to suffer from heat transfer problems. The best technique for maximum accuracy is to employ multiple pipettes and rotate them often, storing them between uses in a stand that holds them vertically.

Operator fatigue is an often-overlooked but crucial component when seeking maximal accuracy and repeatability. Human beings are not robots, and repetitive motions cause stress in human joints and muscles. Even a well-trained and experienced operator will see a decrease in accuracy and repeatability as length of time on the job increases. It is for this reason that pipette calibration service providers that are dedicated to excellence limit the number of pipettes that can be calibrated by an individual technician to a maximum daily number. Each pipette, and each customer, deserves a high level of care in the treatment of the instrument. Additionally, some dedicated professionals train themselves to pipette ambidextrously, allowing them to reduce arm and finger strain by alternating hands.

Long-term pipette operation can lead to repetitive strain injuries, such as carpal tunnel syndrome. These disorders may cause significant reductions in accuracy and repeatability by altering the proper pipetting techniques that are crucial to achieving optimal accuracy. Preventive measures include learning to pipette with both hands and alternating their usage, taking frequent breaks while pipetting, and choosing the most ergonomic pipette available. Instruments with plumper handles are generally superior in this regard.

Letting the pipette "rest" for at least one minute after a volume change is made. This does not apply to single-volume instruments, also called set volume or fixed volume pipettes. A change in the dispensed volume of an adjustable pipette involves modifying the internal tensioning of a spring that governs the piston's travel distance. Springs subjected to changing tensioning behave more smoothly and consistently when they are allowed to enjoy an interval of rest to settle into their new configuration. A pipette that is left idle for at least one minute after a volume adjustment will perform more accurately than one that is pressed into service prematurely. This is especially important when calibrating a pipette.

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Calibration

For sustained accuracy and consistent and repeatable operation, pipettes should be calibrated at periodic intervals. These intervals vary depending on several factors:

The skill and training of the operators. Skilled operators tend to operate the instrument more correctly and make fewer accuracy-robbing mistakes.
The liquid dispensed by the pipette. Corrosive and volatile liquids tend to emit vapors which ascend into the pipette shaft even under proper operating conditions and may corrode the metal piston and springs, or the seals and o-rings that provide an air-tight seal between the piston and the surrounding sleeve.
Proper and careful handling. Pipettes that are frequently dropped, are subjected to careless handling or horseplay, or that are not properly stored in a vertical position, will tend to degrade in accuracy over time.
The accuracy required by the instrument. Applications requiring maximum accuracy also demand more frequent calibration. Instruments used for purely research applications or in educational settings generally require less frequent calibration.

Under average conditions, most pipettes can be calibrated semi-annually, or every six months, and provide satisfactory performance. Institutions that are regulated by the Food and Drug Administration's GMP/GLP regulations generally benefit from quarterly calibration, or every three months. Critical applications may require monthly service, while research and educational institutions may need only annual service. These are general guidelines and any decision on the appropriate calibration interval should be made carefully and include considerations of the pipette in question (some are more reliable than others), the conditions under which the pipette is used, and the operators who use it.

Calibration is generally accomplished through means of gravimetric analysis. This entails dispensing samples of distilled water into a receiving vessel perched atop a precision analytical balance. The weight of water is a well-known constant, and thus the weight of the dispensed sample provides an accurate indication of the volume dispensed. Relative humidity, ambient temperature, and barometric pressure are factors in the accuracy of the measurement, and are usually combined in a complex formula and computed as the Z-factor. This Z-factor is then used to modify the raw mass data output of the balance and provide an adjusted and more accurate measurement.

The colormetric method uses precise concentrations of colored water to affect the measurement and determine the volume dispensed. A spectrophotomer is used to measure the color difference before and after aspiration of the sample, providing a very accurate reading. This method is more expensive than the more common gravimetric method, given the cost of the colored reagents, and is recommended when optimal accuracy is required. It is also recommended for extremely low-volume pipette calibration, in the 2 microliter range, because the inherent uncertainties of the gravimetic method, performed with standard laboratory balances, becomes excessive. Properly calibrated microbalances, capable of reading in the range of nanograms (0.000000001 g) can also be used effectively for gravimetric analysis of low-volume micropipettes.

The choice of calibration providers is also a significant factor in the quality of the calibration service provided. The easiest way to choose a competent laboratory is to look for one that is accredited to a national or international standard, such as ISO/IEC 17025. These labs have proven adherence to rigid regulations and protocols and are certified by accredited institutions authorized to perform such accreditation by the body issuing the standard in question. These standards require the laboratory to provide demonstrated adherence to certain practices that tend to establish their competence and impartiality. These practices include implementation of a comprehensive quality system, standardized and published procedures for all laboratory operations, use of only accepted or properly validated test and/or calibration methods, proper personnel training and supervision, provision for handling nonconforming work, transparency of laboratory operations, document and records control, provision for handling complaints, prevention of conflicts of interest, independence of laboratory operations, personal and institutional integrity, rigorous uncertainty analysis, and a commitment to continual improvement of all aspects of laboratory operations and measurements. In short, retaining the services of accredited laboratories relieves the retaining organization of the large and expensive burden of verifying the competence of the provider.

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Other pipette types

Transfer pipettes. In the case of the eyedropper, the rubber bulb creates the vacuum and the tapered glass tube serves as the liquid-holding chamber.
Electric pipettes. Also called a "pipette helper", these pipettes are battery-operated and are designed to be used with disposable pipette tubes.

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