The invention herein pertains to laboratory procedures, particularly procedures involving the transfer of chemical reagents using a single or multichannel manual or electronic pipette.
In recent years costs for laboratory testing and analysis has dramatically risen due in part to the increased salaries of qualified laboratory employees and technicians. In addition, the cost of materials used has also risen including the cost for supplies, such as well plates, chemical reagents and other resources. Manual loading by pipettes of chemical reagents into well plates having either 96 or 384 reservoirs is commonplace. Well plates exhibiting more numerous reservoirs are usually robotically loaded. With few exceptions laboratories commonly utilize manual pipette loading of well plates having 384 or fewer reservoirs. Such well plate loading is often routine and monotonous causing laboratory technicians carrying out such testing and analysis to become inattentive, easily distracted or confused as to the particular reservoir to be loaded next. Sometimes duplication and omissions occur. At other times cross contamination occurs from one reservoir to another due to improper techniques employed in pipette loading.
Once it has been determined that a single reservoir has been improperly loaded or overloaded in a well plate, the error may require the technician to discard the current well plate and start anew. Such errors can be expensive, time consuming and libelous, depending on the particulars of the test or analysis conducted.
Thus with the problems and disadvantages of current well plate loading techniques using manual pipettes, methods and equipment the present invention was conceived and one of its objectives is to ensure faster, more accurate reservoir loading by pipette using manual procedures.
It is another objective of the present invention to provide a pipette guide and method which limits the number of well plate reservoirs exposed at any particular time and helps prevent cross contamination.
It is yet another objective of the present invention to provide a pipette guide which can be locked onto a standard skirted or non-skirted well plate during loading.
It is still another objective of the present invention to provide a pipette guide which includes a movable slotted slide for outlining a single row of reservoirs for pipette loading.
It is yet another objective of the present invention to provide a reservoir isolator which will allow only one specific reservoir in a row to be loaded while shielding immediately adjacent reservoirs from contamination.
It is a further objective of the present invention to provide a method of well plate loading using a manual pipette which will allow greater accuracy and eliminate errors, retesting and analysis.
It is also an objective of the present invention to provide a pipette guide which can be easily locked onto a well plate for loading and readily removed for placement on another well plate as needed.
Various other objectives and advantages of the present invention will become apparent to those skilled in the art as a more detailed description is set forth below.
The aforesaid and other objectives are realized by providing a pipette guide and method, of use which ensure more accurate and efficient reagent delivery to selected well plate reservoirs. The pipette guide includes a cover having a movable slide mounted thereon. The slide is slotted to outline a single row of reservoirs when used with a conventional well plate. A window formed in the cover allows the slide to span the window, outlining selected rows of reservoirs as desired. A slide rod is affixed to the slide from which a single reservoir isolator is suspended. The reservoir isolator is coincidentally aligned with the slide slot whereby a specific reservoir in the row outlined is available for reagent delivery from the pipette.
In use, the pipette guide is secured to the well plate by a manual lock beneath the cover. The lock frictionally engages the side of the well plate to hold it in place during use. Once the well plate has been fully loaded, the lock can be released and the pipette guide placed on another well plate for subsequent loading.
A side rod affixed along one edge of the pipette guide cover includes notches for engagement by a resilient clip. As the slide is movably joined to the side rod, the clip will provide slide indexing along the cover as each successive notch is engaged. If the wrong series of notches is selected for a particular well plate the incorrect movement of the slide will be readily apparent to the user. The rod can be loosened and rotated to reveal a second series of notches. Each set of notches on the side rod corresponds to the number of reservoir rows of the well plate. In addition, a slide rod likewise includes two (2) sets of notches which correspond to the number of reservoirs in a particular row as outlined by the slide slot.
Thus, by using the pipette guide in the reservoir loading process less likelihood of an error exists due to the outlining and isolation of particular selected reservoirs.
For a better understanding of the invention and its operation, turning now to the drawings,
In use well plate 20 is placed on conventional non-slip rubber or polymeric mat 25 supported on a table or laboratory counter 28. While mat 25 is not absolutely necessary, it prevents well plate 20 from any advertent movement as reagent 22 is manually loaded into reservoirs 21 of well plate 20 through standard pipette 24. Reagent 22 can be any number of conventional laboratory chemicals, solutions, solvents and the like as are commonly employed during laboratory testing and analysis.
When loading well plate 20 as in various laboratory procedures, user 12 (as illustrated in fragmented fashion in
In
Pipette guide 10 is releasably attached to well plate 20 as shown in
As earlier explained, pipette guide 10 is employed for more efficient and accurate pipette loading by user 12. As shown in
Well plates are manufactured with consistent center-to-center dimensions but variations in the outer well plate dimensions are usual. Thus, lock nut 31 can be manually rotated for a fine adjustment to exactly center index slide 17 on the initial row of reservoirs.
To precisely index slide 17 as it moves from row to row of reservoirs 21 along well plate 20, flange 19 includes c-shaped metal clip 39 as shown in
When only one specific reservoir 21 is to be loaded by pipette, reservoir isolator 44 as shown in
As further seen in
In the preferred method of use of pipette guide 10, a desired well plate 20 having either 96 or 384 reservoirs 21 is selected. Pipette guide 10 is then placed atop the well plate such as well plate 20 shown in
Once the desired number of selected reservoirs and rows are so loaded, lock 14 is then loosened and pipette guide 10 removed from well plate 20 for further processing of the reservoir contents. Pipette guide 10 can then be placed on another well plate 20 and the process repeated as needed.
The illustrations and examples provided herein are for explanatory purposes and are not intended to limit the scope of the appended claims.
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