WO1991016977A1

WO1991016977A1 - Procedure for handling liquid with the aid of a pipette

Info

Publication number: WO1991016977A1
Application number: PCT/FI1991/000136
Authority: WO
Inventors: Osmo Suovaniemi; Pertti Ekholm
Original assignee: Biohit Oy
Priority date: 1990-05-04
Filing date: 1991-05-03
Publication date: 1991-11-14
Also published as: FI902271A0; FI84790B; FI902271A

Abstract

A procedure for liquid handling with the aid of a pipette wherein liquid is transferred into the liquid volume of the pipette from a certain starting point of this volume, with substantially linearly accelerated speed (A1), until a desired, predetermined constant speed (B1) has been reached; liquid is transferred at constant speed (B1); the transfer of liquid is abruptly stopped (D1) when the liquid quantity to be transferred has been loaded into the liquid volume; and the liquid quantity is dispensed out from the liquid volume in one or several batches according to the respective steps (A, B, D) presented in the foregoing, so that the liquid transfer steps constitute a closed cycle.

Description

PROCEDURE FOR HANDLING LIQUID WITH THE AID OF A PIPETTE

The present invention concerns a procedure, as defined in the preamble to claim 1, for liquid handling with the aid of a pipette.

Liquid handling is in this context understood to mean accurate and reproducible transfer, dilution, dispensing, mixing, titration and other manipulation of a desired quantity of liquid. The pipette may be a device with one passage or with multiple passages. In a_^ multi-passage device is for instance provided a plural¬ ity of side-by-side, identical devices, which most ad¬ vantageously can be made to operate simultaneously. In the art a pipette is known which comprises a plunger, a liquid volume and a plunger operating means for transferring a desired quantity of liquid into, and out from, the liquid volume. The operating means usually includes an electric motor with the aid of which the transfer is implemented.

The problem in liquid handling carried out with a pipette is accuracy, speed and reproducibility and, in particular, fitting these together. The liquid quantity to be handled, e.g. in dispensing, is usually small, but it should be handled with a given accuracy and in reproducible manner. On the other hand, the han¬ dling of the liquid quantity should be fast in order that the means should be able to process a great number e.g. of samples. The object of this invention is to eliminate the drawbacks cited in the foregoing. It is particular¬ ly an object of the invention, to disclose such a novel procedure for handling predetermined liquid quantities with the aid of a pipette in which predetermined liquid quantities can be handled in a simple and reliable man¬ ner, and accurately and offering many possible applica¬ tions. The procedure of the invention is character¬ ized by that which is stated in Claim 1.

The procedure of the invention is character¬ ized in that in a first step liquid is transferred into the liquid volume of the pipette with the aid of a plunger from a given starting point in this volume by moving the plunger with a substantially linearly accel¬ erated velocity, until the desired, predetermined con¬ stant speed of plunger and liquid has been reached; in a second step the plunger and the liquid are moved at constant speed; in a third step the liquid transfer is abruptly stopped when the liquid quantity that is to be transferred has been loaded into the liquid volume; and the liquid quantity is dispensed in one or several batches out from the liquid volume in accordance with the respective steps just described, so that the liquid transfer steps constitute a closed cycle.

In an embodiment of the invention, decelera¬ tion of the plunger movement and of the liquid transfer is commenced with substantially linearly decelerated speed from said constant speed when the liquid quantity already transferred is observed to be close to the ul¬ timate liquid quantity to be transferred.

In an embodiment of the invention, all veloci- ties or speeds, accelerations and decelerations can be set in advance.

In an embodiment of the invention, all veloci¬ ties or speeds, accelerations and decelerations can be selected in advance from a certain, predetermined set of velocity, speed, acceleration and deceleration val¬ ues.

In an embodiment of the invention, at dispens¬ ing the liquid quantity out from the liquid volume in one or several batches, the last step is a secondary phase in which the liquid volume is emptied past the fixed starting point where the plunger was located at the beginning of the first step. In an embodiment of the invention, in the sec¬ ondary phase the liquid volume is emptied by moving the plunger as far as a lower limit, whereafter the liquid volume is returned to the initial state of the first step by moving the plunger to the starting point.

In an embodiment of the invention, at dispens¬ ing the liquid quantity out from the liquid volume one goes from the step of constant-speed plunger and liquid movement to a substantially linear deceleration step, which is replaced at the beginning of the secondary phase with a substantially linear acceleration step, and further with a constant speed step, from which one goes, most advantageously, to a substantially linear deceleration step, until the lower limit of the liquid volume is reached, whereafter the plunger is moved from the lower limit of the liquid volume, most advantage¬ ously through equivalent steps to the starting point, and the liquid volume is returned to the initial state of the first step, where the process is stopped. An advantage of the procedure of the invention is exactitude and accuracy of liquid dispensing.

A further advantage of the procedure of the invention is the ease of its modification and its flex¬ ibility, whereby it is possible to adapt this procedure to different pipettes, and to single passage as well as multiple passage pipettes.

A further advantage of the procedure of the invention is the versatility of its use in conjunction with any suitable single or multiple passage pipette. Any handling of liquid quantities is managed with ease, whatever the application.

A further advantage of the procedure of the invention is that termination both of the intake phase and of the dispensing phase is implemented abruptly, by arresting the plunger movement e.g. with the aid of an efficient brake means, whereby no residual liquid drop¬ lets are incurred on the tip portion of the pipette. Emptying of the liquid volume, in particular, will therefore take place sharply and accurately, and in¬ accuracy due to droplets can thus be avoided.

In the following the invention is described in detail, with reference to the attached drawing, where¬ in:-

Fig. 1 presents, schematically, a pipette; Fig. 2 presents the kinetic diagram of the pipette plunger and of the liquid transfer, in general form; Fig. 3 illustrates the basic operation of the pipette with the aid of a kinetic diagram;

Fig. 4 illustrates a dispensing operation implemented with the aid of a pipette, by the aid of a kinetic dia¬ gram; and Fig. 5 illustrates a diluting operation implemented with the aid of a pipette, by the aid of a kinetic dia¬ gram.

In Fig. 1 is schematically depicted a pipette comprising a cylinder or liquid volume 1; a plunger 2, fitted into the cylinder volume; a tip part 3; a liquid passage 4 to connect the liquid volume 1 with the tip part; an operating means 5 for moving the plunger 2 in the liquid volume; and a control means 6 for control¬ ling the operating means 5 and by its mediation, the movements of the plunger 2.

In Fig. 2 is depicted the kinetic diagram of the plunger and liquid movement, the x axis repre¬ senting the longitudinal direction A-A of the liquid volume, and at the same time of the pipette, and where the length of the liquid volume is 1 . On the y axis of the kinetic diagram is reproduced the velocity with which the plunger is moved, and at the same time the liquid movement speed. It is thus understood that the upper limit and lower limit of the movement of the plunger 2 are separated by the distance 1 . In the following, the procedure of the invention is generally described, referring to this kinetic diagram. Liquid is being transferred into the liquid volume 1 of the pipette.

In the first step, liquid is transferred into the liquid volume 1 of the pipette with the aid of the operating means 5 and plunger ^, under control by the control means 6, from a fixed starting point a in this volume by moving the plunger with substantially linearly accelerated velocity Al, until the desired, predetermined constant speed Bl of plunger and liquid has been reached. In the second step, the plunger 2 and the liquid are moved at constant speed B10,B11. In the third step, the liquid transfer is abruptly stopped when the liquid quantity to be transferred has been loaded into the liquid volume Cl. The liquid quantity is dispensed from the liquid volume in one or several batches by respective steps like those just described, so that the liquid transfer steps constitute a closed cycle. The whole operation is presented step by step in Fig. 2. If the constant speed Bl is higher than the fixed constant speed BIO, deceleration of the movement of plunger 2 and of the liquid transfer, Dl, is com¬ menced with substantially linearly decelerated speed, starting at said constant speed Bl, when the liquid quantity already transferred is found to be close to the ultimate liquid quantity to be transferred.

All velocities, speeds, accelerations and de¬ celerations Al, Bl, BIO, Bll, Dl can be preset. These velocities, speeds, accelerations and decelerations are advantageously selectable in advance from a certain set of velocity, speed, acceleration and deceleration val¬ ues, which can be entered in the memory of the control means.

As Figs 2 and 3 reveal, in the operation of dispensing the liquid quantity from the liquid volume in one (Fig. 2) or several batches (Fig. 3; H, 1-6, W) the last step is a secondary phase T, in which the li- quid volume is emptied past the fixed starting point a of the plunger 2, the location of the plunger at the beginning of the first step.

In an embodiment of the invention, when the liquid quantity is dispensed out from the liquid vol¬ ume, one goes from the step of plunger 2 and liquid movement at constant speed Bl to a substantially linear deceleration step Dl, which is replaced, at the begin¬ ning of the secondary step T, with a substantially lin- ear acceleration step Tl and, further, with a constant speed step T2, from which one goes most advantageously to a substantially linear deceleration step T3, until the lower limit ar of the liquid volume is reached. The plunger 2 is moved from the lower limit ar of the liquid volume 1, through corresponding steps T3,T4, to the starting point a . The liquid volume has been re¬ turned to the initial state of the first step, and the process is stopped there. In this case, too, the move¬ ment of the plunger 2 back to the starting point is arrested abruptly, T5.

Fig. 5 illustrates, with the aid of a kinetic diagram, a diluting operation implemented with the aid of a pipette. In this instance, reagent is transferred into the liquid volume with the aid of the plunger 2 in an inspiration phase Rl, starting at the starting posi¬ tion a , whereafter in a second step I an air bubble is drawn into the liquid volume 1, and thereafter fol¬ lows the sample inspiration R2. Dispensing takes place similarly as shown in Fig. 3. On the dispensing follows a secondary phase T, as has already been described.

By the procedure of the invention all operat¬ ing functions of the pipette can be implemented: dis¬ pensing, secondary, return to starting position, inspi¬ ration and phasing, reagent inspiration air bubble and sample inspiration, hysteresis elimination (see Fig. 4 H) , and waste (= w, see Fig. 4).

The invention is not delimited to concern merely the embodiment example presented in the fore¬ going: numerous modifications are feasible within the scope of the inventive idea defined by the claims.

Claims

1. A procedure for liquid handling particu¬ larly with the aid of a pipette or equivalent device, characterized in that

- liquid is transferred into the liquid volume of the pipette from a certain starting point of this volume, with substantially linearly accelerated speed (Al), until a desired, predetermined constant speed (Bl) has been reached;

- liquid is transferred at constant speed (Bl);

- the transfer of liquid is abruptly stopped (Dl) when the liquid quantity to be transferred has been loaded into the liquid volume; - the liquid quantity is dispensed out from the liquid volume in one or several batches according to the re¬ spective steps (A,B,C) presented in the foregoing, so that the liquid transfer steps constitute a closed cycle.

2. Procedure according to claim 1, character¬ ized in that deceleration of liquid transfer is com¬ menced with substantially linearly decelerated speed (Cl) from said constant speed (Bl) when the liquid quantity already transferred is found to be close to the ultimate liquid quantity to be transferred.

3. Procedure according to claim 1 or 2, char¬ acterized in that all velocities, speeds, accelerations and decelerations can be set in advance.

4. Procedure according to claim 3, character- ized in that all velocities, speeds, accelerations and decelerations are selectable in advance from a certain, predetermined set of velocity, speed, acceleration and deceleration values.

5. Procedure according to any one of the pre- ceding claims, characterized in that when the liquid quantity is being dispensed out from the liquid volume in one or several batches, the last step is a secondary phase in which the liquid volume is emptied past the fixed starting point.

6. Procedure according to claim 5, character¬ ized in that in the secondary phase the liquid volume is emptied to the lower limit, whereafter return to the starting point of the liquid volume is effected.

7. Procedure according to claim 6, character¬ ized in that when the liquid quantity is being dispens¬ ed out from the liquid volume, one goes from the con- stant speed step to a substantially linear deceleration step, which is replaced, at the beginning of the sec¬ ondary phase, with a substantially linear acceleration step, and further with a constant speed step, from which one goes most advantageously to a substantially linear deceleration step, until the lower limit of the liquid volume is reached, whereafter transition is made from the lower limit of the liquid volume, most advan¬ tageously through corresponding steps, to the starting point of the liquid volume, where the process is stopp- ed.