Pipette for use with a pipette tip

Abstract

A pipette (110) includes an ejector member (140) with an ejector end (142) configured to be moved from the retracted position (147a) to the extended position (147b) to eject a gripped pipette tip (120) from an end portion (132) of the body (130) of the pipette (110). The pipette (110) further includes an adjustment device (160) configured to adjust the extended position (147b) of the ejector end (142) with respect to the body (130) and a lock device (200) configured to selectively inhibit operation of the adjustment device (160) to adjust the extended position (147b) of the ejector end (142).

Claims

1. A pipette for use with a pipette tip, the pipette comprising: a body including an end portion; an ejector member including an ejector end configured to reciprocate between a retracted position and an extended position with respect to the body, wherein the end portion of the body is configured to releasably grip the pipette tip when the ejector end is oriented in the retracted position, and wherein a movement of the ejector end from the retracted position to the extended position is configured to eject a gripped pipette tip from the end portion of the body; an adjustment device configured to adjust the extended position of the ejector end with respect to the body; a lock device configured to selectively inhibit operation of the adjustment device to adjust the extended position of the ejector end; and a link member, wherein the adjustment device adjustably couples the ejector member relative to the link member to adjust the extended position of the ejector end, wherein the lock device is configured to substantially prevent operation of the adjustment device from adjusting the extended position by substantially preventing a relative rotation of the link member with respect to the body.

2. The pipette of claim 1, wherein the lock device is configured to be coupled to the link member to substantially prevent operation of the adjustment device from adjusting the extended position by substantially preventing a relative rotation of the link member with respect to the body, and wherein the lock device is configured to be uncoupled from the link member to allow operation of the adjustment device by permitting a relative rotation of the link member with respect to the body.

3. The pipette of claim 1, wherein an interface between the adjustment device and the link member is configured to removably couple the ejector member with respect to the link member.

4. The pipette of claim 3, wherein the interface is configured to inhibit a rotational movement of the adjustment device with respect to the link member.

5. The pipette of claim 1, wherein the lock device comprises an actuator member configured to be pressed to move the ejector end from the retracted position to the extended position to eject the gripped pipette tip from the end portion of the body.

6. The pipette of claim 1, wherein the adjustment device includes a threaded portion configured to engage a threaded portion of the ejector member, wherein an adjustment rotation of the adjustment device relative to the ejector member is configured to adjust the extended position of the ejector end with respect to the body.

7. The pipette of claim 1, wherein the adjustment device includes at least one stop configured to limit an adjustment of the extended position of the ejector end with respect to the body.

8. The pipette of claim 1, wherein the lock device is configured to be coupled with respect to the body to permit a translation of the lock device with respect to the body and/or inhibit a rotation of the lock device with respect to the body.

9. A pipette for use with a pipette tip, the pipette comprising: a body including an end portion; an ejector member including an ejector end configured to reciprocate between a retracted position and an extended position with respect to the body, wherein the end portion of the body is configured to releasably grip the pipette tip when the ejector end is oriented in the retracted position, and wherein a movement of the ejector end from the retracted position to the extended position is configured to eject a gripped pipette tip from the end portion of the body; a link member; an adjustment device attached to the link member, the adjustment device including a threaded portion configured to engage a threaded portion of the ejector member, wherein an adjustment rotation of the adjustment device relative to the ejector member is configured to rotate the link member and adjust the extended position of the ejector end with respect to the body; and a lock device configured to be coupled to the link member to substantially prevent the adjustment rotation of the adjustment device by substantially preventing a relative rotation of the link member with respect to the body, and wherein the lock device is configured to be uncoupled from the link member to allow the adjustment rotation of the adjustment device by permitting a relative rotation of the link member with respect to the body.

10. The pipette of claim 9, wherein an interface between the adjustment device and the link member is configured to removably couple the ejector member with respect to the link member.

11. The pipette of claim 9, wherein the lock device comprises an actuator member configured to be pressed to move the ejector end from the retracted position to the extended position to eject the gripped pipette tip from the end portion of the body.

12. The pipette of claim 9, wherein the adjustment device includes at least one stop configured to limit an adjustment of the extended position of the ejector end with respect to the body.

13. The pipette of claim 9, wherein the lock device is configured to be coupled with respect to the body to permit a translation while inhibiting a rotation of the lock device relative to the body.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) These and other features, aspects and advantages of the present disclosure are better understood when the following detailed description is read with reference to the accompanying drawings, in which:

(2) FIG. 1 illustrates a partial sectional elevation view of a pipette with an ejector member in a retracted position;

(3) FIG. 2 schematically illustrates the pipette of FIG. 1 with the ejector member in an extended position;

(4) FIG. 3 is an enlarged view of portions of the pipette of FIG. 1;

(5) FIG. 4 is a front elevational view of an example adjustment device;

(6) FIG. 5 is a sectional view of the adjustment device along line 5-5 of FIG. 4;

(7) FIG. 6 is a sectional view of the adjustment device along line 6-6 of FIG. 5;

(8) FIG. 7 is an enlarged view of a portion of FIG. 6, illustrating a groove within a protrusion of the adjustment device;

(9) FIG. 8 is a partial sectional perspective view of the adjustment device of FIG. 4;

(10) FIG. 9 is a front elevational view of an example link member;

(11) FIG. 10 is an enlarged view of portions of the link member of FIG. 9;

(12) FIG. 11 is a sectional view of the link member along line 11-11 of FIG. 9;

(13) FIG. 12 is an enlarged perspective view of a portion of the link member of FIG. 9;

(14) FIG. 13 illustrates a method of removing an ejector member;

(15) FIG. 14 illustrates a method of coupling an ejector member;

(16) FIG. 15 illustrates a method of adjusting the extended position of the ejector end of the ejector member with respect to the body of the pipette; and

(17) FIG. 16 is a flowchart illustrating example steps of using a pipette.

DETAILED DESCRIPTION

(18) Methods will now be described more fully hereinafter with reference to the accompanying drawings in which example embodiments of the disclosure are shown. Whenever possible, the same reference numerals are used throughout the drawings to refer to the same or like parts. However, this disclosure may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

(19) FIG. 1 illustrates a partial sectional elevation view of a pipette 110 incorporating aspects of the disclosure. The pipette 110 can include a wide variety of configurations including various designs, sizes, shapes or functional features designed to permit transfer of a quantity of liquid with a pipette tip 120 associated with the pipette 110 in use. In some examples, a plurality of pipette devices may be linked together to independently grip a corresponding pipette tip in use. Alternatively, as shown, a single pipette may be provided that is designed grip a single pipette tip 120. The pipette 110 can comprise an automatic or manual pipette. In some examples, the pipette 110 can be provided or adjusted to provide transfer of a predetermined quantity of liquid.

(20) The pipette 110 can include a body 130 that may provide a holding structure for a user holding the pipette 110 although the housing may alternatively be designed to be grasped by a robot or other support mechanism. The body 130 may comprise a plastic, metal or other material depending on the particular application.

(21) The body 130 can include an end portion 132 configured to grip the pipette tip 120. In one example, end portion 132 may be designed for a friction fit with the pipette tip 120 although a snap fit, expansion device, or other connection method may be employed to allow the end portion 132 to grip the pipette tip 120.

(22) As further shown in FIG. 1, the pipette 110 can further include an ejector member 140 including an ejector end 142 configured to reciprocate between a retracted position, see FIG. 1, and an extended position, see FIG. 2, with respect to the body 130. As shown in FIG. 1, the ejector end 142 can include a sleeve 144 configured to circumscribe the end portion 132. The sleeve 144 can be guided by the end portion 132 of the body 130 between the retracted and extended position and also acts to properly orient the ejector end 142 relative to the body 130 when the ejector member 140 is properly installed with respect to the body 130.

(23) As further illustrated, the ejector end 142 can include an abutment surface 146 configured to engage a portion of the pipette tip 120 to promote ejection of the pipette tip 120 from the end portion 132 of the body 130 when moving the ejector member 140 to the extended position shown in FIG. 2. In some examples, as shown in FIG. 1, the abutment surface 146 can comprise a circumferential edge adapted to engage a circumferential edge 122 of the pipette tip 120.

(24) As such, as shown in FIG. 1, the end portion 132 of the body 130 is configured to releasably grip the pipette tip 120 when the ejector end 142 is oriented in the retracted position. Moreover, as shown in FIG. 2, a movement of the ejector end 142 from the retracted position to the extended position is configured to eject a gripped pipette tip 120 from the end portion 132 of the body 130. Indeed, as shown, the abutment surface 146 of the sleeve 144 may engage and apply an ejection force to a circumferential edge 122 of the pipette tip 120 to eject the gripped pipette tip 120 of FIG. 1 from the end portion 132 of the body 130.

(25) FIG. 3 illustrates an enlarged view of portions of the pipette 110 of FIG. 1. As shown in FIG. 3, the ejector member 140 can also include another end portion 148 that may be crimped or otherwise attached to a coupling device 150. The coupling device 150 can include a mounting sleeve 152 that may be molded with an opposed pair of detents (not shown) configured to receive corresponding inwardly extending protrusions (not shown) of the end portion 148. As such, it is possible to fixedly attach the coupling device 150 to the end portion 148 of the ejector member 140 by crimping the end portion 148 over the mounting sleeve 152. If provided, the detents of the mounting sleeve 152 and the protrusions of the end portion 148 can interact to secure the attachment to resist relative movement between the coupling device 150 and the ejector member 140. In some examples, the end portion 148 of the ejector member 140 may be formed integrally with the features of the coupling device 150. However, providing the ejector member 140 and coupling device 150 different components that are fixedly attached together can allow the components to be fabricated from different materials and/or facilitate fabrication techniques. In one example, the ejector member 140 can comprise stainless steel although plastic or another material type may be used in further examples. In further examples, the coupling device 150 may comprise a plastic material such as polyoxymethylene (POM) although other materials may be used in further examples.

(26) The pipette 110 can further include an adjustment device 160 configured to adjust the extended position of the ejector end 142 with respect to the body 130. For example, as shown in FIG. 1, in the retracted position, the abutment surface 146 achieves the retracted position 147a. As shown in FIG. 2, in the extended position, the abutment surface 146 achieves the extended position 147b wherein a stroke length L is defined between the retracted and extended positions 147a, 147b. The adjustment device 160 is designed to shift the stroke length L in a direction 149a, or a direction 149b. As such, the retracted and extended positions 147a, 147b may be adjusted relative to the body 130 such that the ejector member 140 may be quickly adapted to be used with a wide range of pipette configurations and/or pipette tips.

(27) For example, with reference to FIG. 1, the ejector member 140 may be used with another pipette including a body with a shorter arm 134 extending from a base 136 of the body 130. In such examples, the adjustment device 160 may be used to adjust the extended position of the ejector end 142 in a direction 149a toward the base 136. In such examples, the stroke length L is shifted towards the base 136 to accommodate the shorter arm 134. In further examples, the ejector member 140 may be used with another pipette including a body with a longer arm 134 extending from the base 136 of the body 130. In such examples, the adjustment device 160 may be used to adjust the extended position of the ejector end 142 in a direction 149b away from the base 136. In such examples, the stroke length L is shifted away from the base 136 to accommodate the longer arm 134.

(28) In addition or alternatively, the adjustment device 160 may also be used to adjust the extended position of the ejector end 142 with respect to the body to accommodate alternative pipette tip designs. For example, another gripped pipette tip design may present the circumferential edge 122 closer to the base 136 of the body 130. In such examples, the adjustment device 160 may be used to adjust the extended position of the ejector end 142 in a direction 149a toward the base 136. In such examples, the stroke length L is shifted towards the base 136 to accommodate the shifting of the circumferential edge 122 closer to the base 136. In further examples, yet another gripped pipette tip design may present the circumferential edge 122 farther away from the base 136 of the body 130. In such examples, the adjustment device 160 may be used to adjust the extended position of the ejector end 142 in the direction 149b away from the base 136. In such examples, the stroke length L is shifted away from the base 136 to accommodate the shifting of the circumferential edge 122 fatter away from the base 136.

(29) The adjustment device 160 may include a wide range of structures configured to permit adjustment of the extended position of the ejector end 142 with respect to the body 130. For example, referring to FIG. 5, the adjustment device 160 can comprise a cylindrical sleeve with an inner passage 162. As shown in FIGS. 4, 5, and 8, the cylindrical sleeve may be provided with at least one threaded portion 164a, 164b. Although a single threaded portion may be provided, the illustrated two opposed threaded portions 164a, 164b may be provided to simplify fabrication techniques. For example, during fabrication, a molding device may be inserted through windows 166a, 166b to form the corresponding threaded portions 164a, 164b. Such formation techniques may be particularly beneficial when forming the part from a plastic material, such as polyoxymethylene (POM) although other materials may be used in further examples.

(30) Turning back to FIG. 3, the coupling device 150 may be inserted into the inner passage 162 of the adjustment device 160 such that external threads of a threaded portion 154 are operably engaged with the threaded portions 164a, 164b of the adjustment device 160. As such, the adjustment device 160 can comprise a sleeve with an inner threaded portion configured to engage a threaded portion of the ejector member 140, such as the illustrated coupling device 150, wherein an adjustment rotation of the adjustment device 160 relative to the ejector member 140 is configured to adjust the extended position of the ejector end 142 with respect to the body 130.

(31) The adjustment device 160 can also optionally include at least one stop 168a, 168b configured to limit an adjustment of the extended position of the ejector end 142 with respect to the body 130. For example, the at least one stop can include a first stop 168a and a second stop 168b comprising shoulders defining an expanded area 170. The coupling device 150 can include a circumferential flange 156 designed to travel within the expanded area 170. The adjustment device 160 can be adjusted to one extreme position where further adjustment is prevented by engagement of the circumferential flange 156 with the first stop 168a. The adjustment device 160 can also be adjusted to another extreme position where further adjustment is prevented by engagement of the circumferential flange 156 with the second stop 168b. The distance between the stops 168a, 168b define the extent that the extended position of the ejector end 142 can be adjusted relative to the body 130.

(32) The pipette 110 can optionally include a link member 180. In one example, the adjustment device 160 can adjustably couple the ejector member 140 relative to the link member 180 to adjust the extended position of the ejector end 142. In one example, the ejector member 140 may be removably coupled with respect to the link member 180. For example, an interface between the adjustment device 160 and the link member 180 may be configured to removably couple the ejector member 140 with respect to the link member 180. A wide range of interface configurations may be used in accordance with aspects of the disclosure. For instance, as shown in FIG. 3, the interface 182 may comprise a bayonet joint although other interface configurations may be used in further examples.

(33) As shown in FIGS. 3 and 5-8, a first part of the bayonet joint can include a pair of protrusions 184a, 184b extending within the inner passage 162 of the adjustment device 160. As further illustrated in FIGS. 3, 9, 11 and 12, a second part of the bayonet joint can include a pair of opposed L-shaped slots 186a, 186b. As shown in FIG. 12, each L-shaped slot includes an axial portion 188a and a radial portion 188b in communication with the axial portion 188a. At least one or both of the radial portions 188b can be provided with at least one locking rib 190 or other structure configured to inhibit, such as prevent, a rotational movement of the adjustment device 160 with respect to the link member 180. For example, the locking rib 190 may be configured to engage a corresponding groove 186, see FIGS. 7 and 8, formed on one or both of the protrusions 184a, 184b.

(34) FIGS. 1 and 2 illustrate an example of a lock device 200 configured to selectively inhibit, such as prevent, operation of the adjustment device 160 to adjust the extended position of the ejector end 142. In the illustrated example, the lock device 200 comprises an actuator member configured to be pressed to move the ejector member 140 from the retracted position to the extended position to eject the gripped pipette tip 120 from the end portion 132 of the body 130. In further examples, the lock device 200 may be constructed at a different location to inhibit operation of the adjustment device 160. However, providing the lock device 200 in the form of the illustrated actuator member can simplify the design, operation, potentially reduce modes of failure and reduce manufacturing costs.

(35) The lock device 200 can operate in various different ways to inhibit operation of the adjustment device. For example, as illustrated, the lock device 200 may be configured to substantially prevent operation of the adjustment device 160 by substantially preventing a relative rotation of the link member 180 with respect to the body 130. If formed as the illustrated actuator member, the lock device 200 can be configured to be coupled with respect to the body 130 to permit a translation of the lock device 200 with respect to the body 130. Moreover, the lock device 200 can be configured to be coupled with respect to the body 130 to inhibit a rotation of the lock device 200 with respect to the body 130. For instance, as shown in FIGS. 1 and 2, the lock device 200 can include a tongue 202 slidingly and nonrotatably received within a groove 138 defined in the body 130 of the pipette 110. Once coupled, the lock device 200 may translate along ejection direction 204 from the uncompressed position shown in FIG. 1 to the compressed position shown in FIG. 2.

(36) As mentioned above, the lock device 200 can be nonrotatably coupled to the body 130. As further illustrated, the link member 180 can be nonrotatably attached to the lock device 200 such that the link member 180 is substantially prevented from rotating with respect to the body 130. For example, as shown in FIGS. 1 and 2, an end portion 192 of the link member 180 may be nonrotatably received within a socket 206 of the lock device 200. In one example, the end portion 192 may have a polygonal shape to be received in corresponding polygonal shaped socket. Alternatively, as shown, the end portion 192 may be cylindrical to be received within a cylindrical socket. Providing a cylindrical configuration can allow locking of the adjustment device 160 in an infinite number of positions. As shown in FIG. 10, the end portion 192 may include a frictional rib 194 configured to increase frictional engagement between the end portion 192 and the socket 206 of the lock device 200. As such, the frictional rib 194 can optionally be provided to further inhibit, such as prevent, relative rotation of the link member 180 with respect to the lock device 200. Once the end portion 192 of the link member 180 is nonrotatably coupled with respect to the lock device 200, the link member 180 is consequently prevented from rotating relative to the body 130 of the pipette 110.

(37) It will therefore be appreciated that the lock device 200, such as the illustrated actuator member, can be configured to be coupled to the link member 180 to substantially prevent operation of the adjustment device 160 from adjusting the extended position by substantially preventing a relative rotation of the link member 180 with respect to the body 130. Moreover, the lock device 200 can be uncoupled from the link member from the link member 180 to allow operation of the adjustment device 160 by permitting a relative rotation of the link member 180 with respect to the body 130. As shown in FIG. 15, uncoupling can be achieved by completely removing the lock device 200 from the body 130 of the pipette 110. Although not shown, in further examples, the lock device 200 may be configured to be uncoupled without removing the lock device 200 from the body 130. For example, the lock device 200 may be forced into a different orientation to uncouple the link member while still remaining attached to the body 130. For example, the lock device may be tethered or otherwise connected to the body 130 to help prevent misplacement of the lock device when uncoupled from the link member.

(38) As mentioned above, various aspects of the disclosure may be used with a wide range of configurations. For instance, in just one example, the illustrated pipette 110 can provide the adjustment device 160 that may be attached to the link member 180. As mentioned previously, an interface, e.g. bayonet joint, between the adjustment device 160 and the link member 180 may be configured to removably couple the ejector member 140 with respect to the link member 180.

(39) As discussed, in one example, the adjustment device 160 can include the threaded portion 164a, 164b configured to engage the threaded portion 154 of the ejector member 140. An adjustment rotation of the adjustment device 160 relative to the ejector member 140 is configured to rotate the link member 180 and adjust the extended position of the ejector end 142 with respect to the body 130. In such examples, the lock device 200 can be configured to be coupled to the link member 180 to substantially prevent the adjustment rotation of the adjustment device 160 by substantially preventing a relative rotation of the link member 180 with respect to the body 130. The lock device 200 can alternatively be uncoupled from the link member 180 to allow the adjustment rotation of the adjustment device 160 by permitting a relative rotation of the link member 180 with respect to the body 130. As shown, the lock device 200 can optionally be provided as the illustrated actuator member configured to be pressed to move the ejector member 140 from the retracted position to the extended position to eject the gripped pipette tip 120 from the end portion 132 of the body 130.

(40) Methods of using the pipette 110 will now be discussed with initial reference to the flowchart 300 shown in FIG. 16. As shown, the method can start begin at reference number 310 with a step 320 of providing the pipette 110 with the body 130 including the end portion 132, and the ejector member 140 including the ejector end 142. The pipette 110 can also be provided with the link member 180 adjustably coupled with respect to the ejector member 140, and the actuator member coupled to the link member 180 and substantially nonrotatably coupled with respect to the body 130.

(41) As indicated by arrow 322, the method can then optionally proceed to step 330 of releasably gripping the pipette tip 120 with the end portion 132 of the body 130 when the ejector end 142 is oriented in the retracted position with respect to the body 130 as shown in FIG. 1.

(42) As further indicated by arrow 332, the method can optionally proceed to step 340 of operating the pipette 110 to transfer a quantity of liquid with the pipette tip 120. During this step, a desired volume may be dialed into the pipette 110. The user may then move the pipette tip into fluid communication with the quantity of liquid to be transferred. The user can then trigger the pipette to draw the predetermined volume of liquid into the pipette tip 120. The quantity of liquid can then be moved to a new desired location. Once the pipette tip 120 is appropriately positioned, the user can signal the pipette 110 to dispense the liquid from the pipette tip 120 to complete the transfer of the predetermined volume of liquid.

(43) Once the transfer is complete, the pipette 110 can be moved to a position to discard the used pipette tip. As indicated by arrow 342, and shown in FIG. 2, the method can include the step 350 of pressing the actuator member to translate the actuator member, the link member 180 and the ejector member 140 along the ejection direction 204 relative to the body 130 to move the ejector end 142 from the retracted position, shown in FIG. 1, to an extended position, shown in FIG. 2, with respect to the body 130 to eject the gripped pipette tip 120 from the end portion 132 of the body 130. As shown by arrow 352 the method can then end as indicated at 360. Alternatively, as indicated by arrow 354, the method can loop back to step 330 to proceed with another step 330 of releasably gripping another pipette tip to transfer an additional quantity of liquid.

(44) As indicated by arrows 324, 334 the method can further include the steps 370 for adjusting the ejector member 140 at various times during the method of using the pipette 110. For example, after the step 320 of providing the pipette 110, there may be a desire to adjust the ejector member. For example, the ejector member 140 may appear too short or too long for the arm 134 of the pipette 110. In such a circumstance, the lock device 200, e.g. actuator member, may be uncoupled from the link member 180 during step 372 and as shown in FIG. 15.

(45) As indicated by directional arrows 172a, 172b in FIG. 15 and as represented by step 374 in FIG. 16, the extended position of the ejector end 142 may be adjusted with respect to the body 130 by an adjustment rotation of the adjustment device 160. In one example, the step of adjusting the extended position of the ejector end 142 with respect to the body 130 includes the step of rotating an adjustment device 160 together with the link member 180 relative to the ejector member 140.

(46) As indicated by step 376, the method may further include the step of again coupling the actuator member to the link member 180 to inhibit further adjustment of the extended position of the ejector end 142 with respect to the body 130. For instance, the frictional engagement between the end portion 192 of the link member 180 and the socket 206 of the lock device 200 can substantially prevent rotation of the link member 180 and consequently operation of the adjustment device 160 to adjust the position of the ejector end 142.

(47) As shown in FIGS. 13 and 14, the ejector member 140 can optionally be provided with a construction that allows a quick connect and/or disconnect from the body 130 of the pipette 110. For example, as shown in FIG. 14, to connect the ejector member 140, the lock device 200 may be coupled to the end portion 192 of the link member 180 to prevent an adjustment rotation of the adjustment device 160. Next, the sleeve 144 of the ejector member 140 may be aligned with the end portion 132. Then, the ejector member 140 may be moved upward in direction 145 until the protrusions 184a, 184b enter the respective axial portions 188a of the L-shaped slots 186a, 186b. Once fully received, the adjustment device 160 can be rotated in direction 141 relative to the link member 180 such that the protrusions 184a, 184b are seated within the respective radial portions 188b of the L-shaped slots 186a, 186b. Once fully seated, the locking ribs 190 can be snappingly received in the grooves 186 of the protrusions 184a, 184b to couple the adjustment device 160 to the link member 180 such that an adjustment rotation of the adjustment device 160 results in a corresponding rotation of the link member 180. Such coupling of the coupling the adjustment device 160 to the link member 180 allows locking of the adjustment device 160 from an adjusting rotation. Thus, the snapping connection between the locking rib 190 and the groove 186 can provide sufficient resistance to prevent an adjusting rotation when the link member is locked. The snapping connection also permits an audible sound and/or sensory vibration that allows the user to confirm positive locking of the ejector member 140 to the link member 180.

(48) At the same time, upon application of sufficient torque, the locking ribs 190 may be snapped out of the grooves 186 by rotating in the opposite direction 143 shown in FIG. 13. Upon sufficient rotation in the opposite direction 143, the protrusions 184a, 184b can be backed out of the L-shaped slots 186a, 186b to quickly disconnect the ejector member 140 from the body.

(49) Features of the disclosure provide an ejector member 140 with a quick connect and/or disconnect coupling with respect to the body 130 of the pipette. As such, a wide range of ejector members 140 may be used with various pipette devices. In some examples, an ejector member 140 may be designed to be used with various pipette models. As such, a smaller inventory of ejector members 140 may be provided to service a wide range of pipette models. Moreover, the quick connect and/or disconnect feature, e.g. provided by the bayonet joint, allows quick replacement of a damaged ejector member or switching between different sized ejector members if desired.

(50) Still further, the pipette may be provided with an adjustment device that can optionally provide a dual function of allowing adjustment of the ejector end 142 relative to the body 130 and/or allow disconnecting of the ejector member 140 from the body 130.

(51) Still further, aspects of the disclosure allows for adjustment of the ejector end 142 and then locking the customized adjustment in place. Once locked, inadvertent adjustment of the ejector end 142 can be avoided. Still further, aspects of the disclosure can provide the locking device as the actuator member configured to be pressed to move the ejector member 140 from the retracted position to the extended position to eject the gripped pipette tip 120 from the end portion 132 of the body 130. As such, the actuator member can provide a selective locking function as well as an ejection function.

(52) In another example aspect, a method of using a pipette tip includes the step of (I) providing the pipette with a body including an end portion. The step further includes providing the pipette with an ejector member including an ejector end, a link member adjustably coupled with respect to the ejector member, and an actuator member coupled to the link member and substantially nonrotatably coupled with respect to the body. The method further includes the steps of: (II) releasably gripping a pipette tip with the end portion of the body when the ejector end is oriented in a retracted position with respect to the body; and (III) operating the pipette to transfer a quantity of liquid with the pipette tip. The method further includes the step of: (IV) pressing the actuator member to translate the actuator member, the link member and the ejector member along an ejection direction relative to the body to move the ejector end from the retracted position to an extended position with respect to the body to eject the gripped pipette tip from the end portion of the body. After step (I) and before step (III), the method further includes the step of: (V) uncoupling the actuator member from the link member, and then adjusting the extended position of the ejector end with respect to the body, and then again coupling the actuator member to the link member to inhibit further adjustment of the extended position of the ejector end with respect to the body.

(53) In one example, the step of adjusting the extended position of the ejector end with respect to the body includes the step of rotating an adjustment device together with the link member relative to the ejector member.

(54) It will be apparent to those skilled in the art that various modifications and variations can be made to the present disclosure without departing from the spirit and scope of the invention. Thus, it is intended that the present invention cover the modifications and variations of this disclosure provided they come within the scope of the appended claims and their equivalents.