The present invention is related generally to a pipette for aspirating and for dispensing adjustable volumes of liquid. More specifically, the present invention relates to a programmable electronic pipette providing multiple modes of operation.
In pharmaceutical, genomic, and proteomic research, biology research, drug development laboratories, and other biotechnology applications, a liquid pipette is used to handle laboratory samples in a variety of laboratory procedures. Using a pipette, a volume of liquid is aspirated into the pipette. The volume of liquid may then be dispensed in one or more dispensation volume. A piston drive mechanism controls the aspiration and the dispensation of the liquid in specified volumes by imparting motion to a piston assembly. Pipettes in which the piston assembly within the body of the pipette includes a piston rod controlled by either a motor or directly by the user are known to those skilled in the art. Motion of the piston rod is controlled by a thrust exerted by the piston drive mechanism. However, angular displacement of components within the piston drive mechanism may occur relative to the piston assembly. The displacement often causes a small, but measurable longitudinal shift of the piston drive mechanism that in turn causes an inaccurate aspiration or dispensation of the volume of liquid. Thus, what is needed, is a pipette that eliminates the unwanted longitudinal displacement of the piston drive mechanism components.
A pipette may operate in a manual mode wherein the user manually controls the speed and the volume of aspiration or of dispensation of the liquid using a pressure sensitive knob. Alternatively, a pipette may operate in an electronic mode wherein a motor controls the aspiration and/or dispensation of the liquid. The user may select various parameters including a speed, a volume, a number of aspirations, a number of dispensations, etc. using a user interface. The user interface may include a numeric keypad that allows the user to enter, for example, the volume. A pipette generally is small and lightweight because the desire is for an easily portable device that fits comfortably into a hand of the user and that can be used repetitively with a single hand. As a result, the display and the operational controls must be small making them generally tedious to use. For example, some pipettes may have the small numeric keypad, while the input to other pipettes may be through a set of buttons such as up and down arrow buttons to increase or to decrease a parameter. However, the numeric keypad is difficult to use because each numerical button is small and difficult to select particularly when a user is wearing gloves. Also, use of the keypad buttons generally requires the use of both hands. One hand to support the device and the other hand to precisely select the appropriate numerical button. Additionally, the user may need to successively dispense widely-differing volumes. The up and down arrow buttons require a large number of depressions to reach, for example, the widely-differing volume amount. Thus, what is needed is a pipette having an input interface that simplifies the selection of operational parameters for the device and that reduces the time required to change settings within the device. What is further needed is an input interface that can be operated using a single hand.
Electronic pipettes typically are controlled by small microprocessors placed within the housing of the pipette. As electronic pipettes have become more sophisticated, additional and more complex operational modes may be provided. For example, an electronic pipette may be configured to aspirate a volume of liquid and dispense the volume in successive dispensation cycles. Additionally, an electronic pipette may be configured to repeatedly aspirate and dispense a volume of liquid thereby mixing the liquid before the final dispensation of the liquid. To add additional complexity, a sequence of modes may be provided to execute in succession. Again, however, the display and the operational controls are small and tedious to use making it more difficult to “program” the electronic pipette to perform a complex sequence of operations. Thus, what is needed is a pipette that can interface with an external computing device. What is further needed is an application that can be executed on the external computing device to provide an easy to use interface to the user and to provide instructions to the pipette for operation in a “programmed” mode.
An exemplary embodiment of the invention relates to a method of using a user interface presented in a display of a device. The method includes, but is not limited to, moving between a plurality of items by imparting rotational motion to a disc mounted in a first plane of a device, the plurality of items presented in a display of the device, and selecting an item from the plurality of items by imparting translational motion to the disc in the first plane. The method may further include modifying the item by imparting rotational motion to the disc in the first plane and setting the modified item by imparting translational motion to the disc in the first plane.
Another exemplary embodiment of the invention relates to a method of responding to user inputs to a user interface presented in a display of a device. The method includes, but is not limited to, receiving a first signal indicating movement between a plurality of items wherein the first signal is generated by imparting rotational motion to a disc mounted in a first plane of a device, the plurality of items presented in a display of the device, and receiving a second signal indicating selection of an item from the plurality of items wherein the second signal is generated by imparting translational motion to the disc in the first plane. The method may further include receiving a third signal indicating modification of the item wherein the third signal is generated by imparting rotational motion to the disc in the first plane and receiving a fourth signal indicating that the modified item should be set in the device wherein the fourth signal is generated by imparting translational motion to the disc in the first plane.
Still another exemplary embodiment of the invention relates to a device for using a user interface presented in a display of the device. The device includes, but is not limited to, an axle, a disc, an encoder, a motion detector, a display, and a microprocessor. The disc mounts to the axle in a manner allowing rotation of the disc about the axle in a plane of the device, the disc translatable in the plane of the device. The encoder is configured to generate a first electrical signal indicating a first rotation of the disc about the axle, the first rotation in the plane of the device. The motion detector is configured to generate a second electrical signal indicating a first translation of the disc in the plane of the device. The microprocessor couples to the display and is configured to receive the first electrical signal, wherein the first rotation of the disc indicates movement between a plurality of items presented in the display, and to receive the second electrical signal, wherein the first translation of the disc indicates selection of an item from the plurality of items presented in the display.
Still another exemplary embodiment of the invention relates to a device for aspirating and for dispensing liquid. The device includes, but is not limited to, a thumb wheel, a display, a sampling tube, and a microprocessor. The thumb wheel includes, but is not limited to, an axle, a disc, an encoder, and a motion detector. The disc mounts to the axle in a manner allowing rotation of the disc about the axle in a plane of the device, the disc translatable in the plane of the device. The encoder is configured to generate a first electrical signal indicating rotation of the disc about the axle, the rotation in the plane of the device. The motion detector is configured to generate a second electrical signal indicating translation of the disc in the plane of the device. The sampling tube has an assembly for holding a liquid. The microprocessor couples to the display and is configured to regulate the liquid in the sampling tube, to receive the first electrical signal, wherein the rotation of the disc indicates movement between a plurality of items presented in the display, and to receive the second electrical signal, wherein the translation of the disc indicates selection of an item from the plurality of items presented in the display.
Still another exemplary embodiment of the invention relates to a device for aspirating and for dispensing liquid. The device includes, but is not limited to, a sampling tube, a piston assembly, and a piston drive mechanism. The piston assembly mounts to the sampling tube and includes, but is not limited to, a piston rod that fits within the sampling tube. The piston drive mechanism includes, but is not limited to, a control rod having a surface that contacts the piston assembly. The piston drive mechanism is configured to move the piston rod of the piston assembly within the sampling tube thereby causing regulation of a liquid in the sampling tube. The surface of the control rod is a non-flat surface.
Still another exemplary embodiment of the invention relates to a method of controlling a pipette. The method includes, but is not limited to, receiving at a communication interface of a pipette electronic signals from a computing device, wherein the computing device is not integral with the pipette and performing an operation at the pipette in response to the received electronic signals.
Still another exemplary embodiment of the invention relates to a device for aspirating and for dispensing liquid. The device includes, but is not limited to, a sampling tube, a piston assembly, a piston drive mechanism, a communication interface, and a microprocessor. The piston assembly mounts to the sampling tube and includes, but is not limited to, a piston rod that fits within the sampling tube. The piston drive mechanism includes, but is not limited to, a control rod having a surface that contacts the piston assembly. The piston drive mechanism is configured to move the piston rod of the piston assembly within the sampling tube thereby causing regulation of a liquid in the sampling tube. The communication interface is configured to receive electronic signals from a computing device, wherein the computing device is not integral with the device. The microprocessor is configured to control the piston drive mechanism and to perform an operation in response to the received electronic signals.
Still another exemplary embodiment of the invention relates to a system for controlling aspiration and dispensation of a liquid in a pipette. The system includes, but is not limited to, a computing device and a pipette. The computing device includes, but is not limited to, a pipetting module and a first communication interface. The pipetting module includes, but is not limited to, computer code configured to define an operation to perform at a pipette. The first communication interface is configured to send electronic signals to the pipette, the electronic signals defining the operation to perform at the pipette. The pipette includes, but is not limited to, a sampling tube, a piston assembly, a piston drive mechanism, a second communication interface, and a microprocessor. The piston assembly mounts to the sampling tube and includes, but is not limited to, a piston rod that fits within the sampling tube. The piston drive mechanism includes, but is not limited to, a control rod having a surface that contacts the piston assembly. The piston drive mechanism is configured to move the piston rod of the piston assembly within the sampling tube thereby causing regulation of a liquid in the sampling tube. The second communication interface is configured to receive the electronic signals from the computing device. The microprocessor couples to the second communication interface and is configured to control the piston drive mechanism and to perform the operation defined by the electronic signals.
Other principal features and advantages of the invention will become apparent to those skilled in the art upon review of the following drawings, the detailed description, and the appended claims.
The preferred embodiments will hereafter be described with reference to the accompanying drawings, wherein like numerals will denote like elements.
With reference to the exemplary embodiment of
The body case 32 provides a comfortable external cover for a user holding the pipette 30 and protects the components of the pipette 30. The body case 32 includes, but is not limited to, a front case 50, a rear case 52, a finger rest 54, a case connection guide 56, a display cover 58, and a customization cover 60. The front case 50 fits with the rear case 52 to enclose the piston drive mechanism 34, the piston assembly 35, the internal tip ejection mechanism 42, and the control electronics card 44. The finger rest 54 provides a bracing point, for example, for the pipette user's index finger to rest against while holding the body of the pipette 30 in the palm of the hand and while using the pipette 30 user controls with the thumb of the same hand. The pipette 30 provides operation with either a left or a right hand of the user. One or more screw 55 or other attachment device may mount the finger rest 54 to an upper portion 62 of the rear case 52. As used in this disclosure, the term “mount” includes join, unite, connect, associate, insert, hang, hold, affix, attach, fasten, bind, paste, secure, bolt, screw, rivet, solder, weld, and other like terms. The upper portion 62 of the rear case 52 may tilt away from a user looking at the display cover 58 and holding the pipette 30 upright along a longitudinal axis A-A depicted in
The finger rest 54 may slidably mount to the rear case 52 allowing the user to comfortably position the finger rest 54 based on the size of the user's hand. The case connection guide 56 slides over an end 51 of the front case 50 and an end 53 of the rear case 52 to mount the front case 50 to the rear case 52. One or more screw 57 may removably mount the case connection guide 56 to the front case 50 and/or the rear case 52 to allow disassembly and reassembly of the pipette 30. The display cover 58 may be formed of plastic, glass, or other suitably transparent material that protects a display 170 of the control electronics card 44. The customization cover 60 may be formed of plastic, glass, or other suitably transparent material that protects a customization sheet 64 used to allow quick identification of the pipette 30.
The piston drive mechanism 34 causes the aspiration and dispensation of a specified volume of liquid through the sampling tube 36 by moving a piston rod 94 within the piston assembly 35 along the longitudinal axis A-A within the sampling tube 36. Motion of the piston produces an air displacement that aspirates or dispense the liquid into or out of the sampling tube 36. The piston drive mechanism may be manually controlled by a user, for example, through depression of a knob or may be controlled using a motor. With reference to the exemplary embodiment of
The actuator 70 may be a power controlled motor for moving the control rod 72 under the control of a microprocessor (not shown) mounted to the control electronics card 44. The actuator 70 may be implemented using a variety of electromechanical devices as known to those skilled in the art. The actuator 70 precisely moves the control rod 72 up and down the longitudinal axis A-A to aspirate or to dispense liquid into or out of the sampling tube 36. The actuator 70 interfaces with the microprocessor of the control electronics card 44 from which the actuator 70 receives electrical signals for controlling the control rod 72 displacement. The control electronics card 44 may include one or more connector or interface for communicating with the actuator 70. The control rod tip 74 mounts to an end of the control rod 72 opposite the actuator 70. For example, the control rod tip 74 may screw onto or into the control rod 72. The control rod support 76 maintains the control rod 72 displacement along the longitudinal axis A-A. The housing 78 mounts to the control rod support 76 and encloses the portion of the control rod 72 and the control rod tip 74 that extend beyond the control rod support 76. Thus, for example, the housing 78 may form a socket.
The tube attachment knob 80 extends from an end of the housing 78 opposite the control rod support 76. The tube attachment knob 80 includes an exterior surface 82 that may be threaded. A tube attachment nut 84 may include an interior surface that fits over the tube attachment knob 80 thereby removably connecting the sampling tube 36 to the body case 32 of the pipette 30 as shown with reference to
With reference to the exemplary embodiment of
The piston housing 96 mounts to the second face 93 of the piston head 92 and extends in a generally perpendicular direction from the second face 93 of the piston head 92 and encloses the piston rod 94. The piston housing 96 may be formed of metallic or plastic material. In an exemplary embodiment, the piston housing 96 is formed of plastic material. The piston housing 96 has a generally cylindrical shape and may include one or more tapered section as shown with reference to
The spring guide 100 may include a hollow cylindrical body 102, a rim 104, and a guide ring 106. The rim 104 mounts to one end of the hollow cylindrical body 102 and extends from the hollow cylindrical body 102 in a generally perpendicular direction away from a center of the hollow cylindrical body 102. The guide ring 106 mounts to the rim 104 opposite the hollow cylindrical body 102. The guide ring 106 has a smaller inner circumference than the hollow cylindrical body 102. The piston housing 96 and the piston return spring 98 fit within the hollow cylindrical body 102 as shown with reference to the exemplary embodiment of
As shown with reference to the exemplary embodiment of
With reference to the exemplary embodiment of
With reference to the exemplary embodiment of
The external tip ejection mechanism 40 and the internal tip ejection mechanism 42 eject the tip 130 from the aspirating and dispensing end of the pipette 30 avoiding possible contamination of samples. The internal tip ejection mechanism 42 includes, but is not limited to, an ejection knob 140, a stationary cylinder 142, a knob cylinder 144, a body cylinder 146, a rod 148, an ejection spring 150, and a mounting brace 152. The stationary cylinder 142 mounts to the body case 32. The mounting brace 152 mounts to the body case 32 and/or the stationary cylinder 142. The stationary cylinder 142 and the mounting brace 152 remain fixed to the body case 32. The ejection knob 140 mounts to the knob cylinder 144. The ejection knob 140 may be rotatable about the longitudinal axis A-A thereby accommodating comfortable operation using either a left or a right hand of a user. The knob cylinder 144 slidably mounts to the stationary cylinder 142 to allow motion of the knob cylinder 144 in combination with depression of the ejection knob 140 to eject the tip 130. The body cylinder 146 mounts to the knob cylinder 144. The rod 148 mounts to an end of the body cylinder 146 opposite the knob cylinder 144. The ejection spring 150 mounts to the body cylinder 146 at a first end 156 and to the mounting brace 152 at a second end 158. Depression of the ejection knob 140 drives the rod 148 toward the tip 130. The ejection spring 150 causes the rod 148 to return in the opposite direction when the ejection knob 140 is released thereby moving the ejection knob 140 back into the original position. The rod 148 includes a notch 154 at a first end of the rod 148 opposite the body cylinder 146.
With reference to
With reference to the exemplary embodiment of
The display 170 presents information in a user interface to the user and allows the user to define the operational characteristics of the pipette. The display 170 may be, but is not limited to, a thin film transistor (TFT) display, a light emitting diode (LED) display, a Liquid Crystal Display (LCD), a Cathode Ray Tube (CRT) display, etc. With reference to
The speed decrease button 174 decreases the speed of the aspiration and/or dispensation of liquid into or out of the sampling tube 36. In an exemplary embodiment, the speed decrease button 174 decreases a pre-set speed setting in a range from one to five. In an alternative embodiment, the speed decrease button 174 directly decreases a speed value. The speed increase button 176 increases the speed of the aspiration and/or dispensation of liquid into or out of the sampling tube 36. In an exemplary embodiment, the speed increase button 176 increases a pre-set speed setting in a range from one to five. In an alternative embodiment, the speed increase button 176 directly increases the speed value.
Depressing the inversion button 178 causes the operation of the aspirate/dispense button 180 to invert from aspirate to dispense or from dispense to aspirate. In an exemplary embodiment, the inversion button 178 is enabled in only certain operational modes supported by the pipette 30 or during specific programs as defined by the user. Depressing the aspirate/dispense button 180 causes the aspiration, dispensation, and/or purge of liquid in the sampling tube 36. In an exemplary embodiment, successive depressions of the aspirate/dispense button 180 causes different results depending on the operational mode of the pipette 30.
The left operational mode button 182 and the right operational mode button 184 may be located on either side of the pipette 30 to provide comfortable access by the user using either a left or a right hand. The left operational mode button 182 and the right operational mode button 184 provide the user with one or more operational mode of using the pipette 30. The user selects the desired operational mode through successive depression of either the left operational mode button 182 or the right operational mode button 184 or both. Example operational modes may include, but are not limited to “auto”, “auto+mix”, “manual”, “repetitive”, and “program”. In the “auto” operational mode, for example, the user may define the volume to pipette without a limit to the number aspirations and/or dispensations of liquid. In an exemplary embodiment, simultaneous depression of both the left operational mode button 182 and the right operational mode button 184 may cause the display 170 to present a menu of selectable items. Example menu items and a sequence of display are shown in
In the “auto+mix” operational mode, for example, the user may define the volume to pipette and the volume of mixing. In the “manual” operational mode, for example, the user may use the pipette 30 like a manual pipette without use of the actuator 70 to control the volume of aspiration/dispensation. The user may aspirate or dispense only a part of a defined volume of liquid allowing aspiration or dispensation in one or more step. In the “repetitive” operational mode, for example, the user may define a volume to dispense. In a next step, the user may define the number of dispensation volumes. For example, using a 100 μL pipette, selecting a dispensation volume of 10 μL may allow up to 10 successive dispensations. The entire specified volume is aspirated after a first depression of the aspirate/dispense button 180 and successive depressions of the aspirate/dispense button 180 cause dispensation of the selected dispensation volume divided by the number of selected dispensation volumes. A subsequent depression of the aspirate/dispense button 180 causes a purge. A new cycle may be entered after a subsequent depression of the aspirate/dispense button 180. In the “program” operational mode, for example, the user may define a “program” for execution by the microprocessor. The program may be defined using an external computing device and received at the pipette 30 using a communication interface 190 discussed with reference to
The thumb wheel 172 enables menu navigation and parameter setting by providing three functions: parameter selection, a parameter increase, and a parameter decrease. Use of the thumb wheel 172 minimizes the number of buttons on the control electronics card 44 of the pipette 30 by replacing a validation button, an incrementing button, and a decrementing button. With reference to
Both translational motion 210 and rotational motion 212 of the thumb wheel 172 are detected and relayed to the microprocessor of the control electronics card 44 through the electronic circuit board 204. In translational motion, all of the points of the moving body have at any instant the same velocity and direction of motion as opposed to rotational motion. In rotational motion, the body turns about an axis. Rotation in a plane involves rotation about an axis perpendicular to the plane of rotation. An optical motion encoder detects and converts motion information into a digital output. A quadrature encoder generally may be composed of a light source, an encoded disc, and a light detector. The encoder modulates a beam of light, whose intensity is sensed by the light detector, producing two signals, A and B as shown with reference to
The photodetector may be mounted to the electronics board 204, detect motion of the rotating disc 202 and transmit the rotational motion information to the electronic circuit board 204. In an exemplary embodiment, the photodetector is an infrared photodetector. As known to those skilled in the art, other detection means may be integrated with the thumb wheel 172 to detect rotational motion of the disc 202. The disc 202 and the electronic circuit board 204 may be arranged so that the rotation 212 of the disc 202 simultaneously generates the signal A and the signal B, for example as illustrated in
A motion detector may be mounted to the electronic circuit board 204 to detect a translational motion 210 of the disc 202 produced when the user depresses the thumb wheel 172. For example, in an exemplary embodiment, the motion detector may include a spring 208 that mounts to the axle 206 and causes the disc 202 to return to its original position after the user releases the thumb wheel 172. Movement of the spring 208 may create an “impulse” that is detected at the electronic circuit board 204. As known to those skilled in the art, other detection means may be integrated with the thumb wheel 172 to detect translational motion of the disc 202.
The pipette 30 may measure the rotational speed of the rotating disc 202 when it is moved by the user. The rotating disc 202 may be divided into a predetermined number of sections that correspond to an angular measure of the wheel. For example, four sections correspond to an angular measure of 90 degrees. Six sections correspond to an angular measure of 60 degrees. The number of section crossings by the rotating disc 202 while it is rotated by the user are counted. While rotating the rotating disc 202, the user may “feel” each section crossing. The microprocessor measures the period of time for the rotating disc 202 to complete some rotation distance thereby calculating a speed of rotation. For example, the time to complete two successive rotations may be used to calculate the speed of rotation. Based on the period of time measured, the microprocessor may change an increment size for a parameter currently being modified by the user. For example, if the period is less than fifteen milliseconds, the microprocessor may increment the parameter by 100. If the period is greater than fifteen milliseconds but less than twenty-five milliseconds, the microprocessor may increment the parameter by 10. If the period is greater than twenty-five milliseconds, the microprocessor may increment the parameter by 10. Thus, the faster the user rotates the thumb wheel 172, the faster the parameter being set by the user increases or decreases. Conversely, if the rotation of the thumb wheel 172 is slow, the microprocessor commands a slower variation of the parameter. The increment values and thresholds for changing the increment values may be modified.
Example functions performable using the thumb wheel 172 through information displayed to the user in the display 170 include, but are not limited to the following.
As shown with reference to
The wired connection 192 may include a first end that connects with the communication interface 190 of the pipette 30 and a second end that connects with a communication interface 234 of the computing device 230. In an exemplary embodiment, the communication interface 190 of the pipette 30 meets the Institute of Electrical and Electronics Engineers (IEEE) 1394 mini standards. In an exemplary embodiment, the communication interface 234 of the computing device 230 may be of type RS 232 that is designed to accept a Universal Serial Bus connector. In an alternative embodiment, the communication interface 190 of the pipette 30 and/or the communication interface 234 of the computing device 230 may be an Ethernet interface.
Wireless communication interfaces may connect devices over various distances from short to long. The pipette 30 and the computing device 230 may support processing for broadcasting and receiving a wireless signal. The wireless signals may, for example, use the IEEE 802.11 ™ standard, using either version 802.11a, 802.11b, 802.11 f or 802.11 g. Additionally, the wireless signals may, for example, use the BLUETOOTH standard of which IEEE 802.15.1 is the most recent version. The IEEE 802.11 ™ specifications define wireless standards for Wireless Local Area Networks (WLANs) that provide an “over-the-air” interface between a wireless client and a base station or access point, as well as among other wireless clients. The IEEE 802.15 Working Group provides standards for low-complexity and low-power consumption Wireless Personal Area Networks (PANs) such as those supported by the Bluetooth specification.
With reference to the exemplary embodiment of
The memory 238 may be the electronic holding place for an operating system of the computing device 230 and/or the pipetting module 242 so that the information can be reached quickly by the processor 240. The computing device 230 may have a plurality of memories 238 using different memory technologies including, but not limited to, Random Access Memory (RAM), Read Only Memory (ROM), flash memory, etc.
The processor 240 executes instructions that cause the computing device 230 to perform various functions. The instructions may be written using one or more programming language, scripting language, assembly language, etc. Additionally, the instructions may be carried out by a special purpose computer, logic circuits, or hardware circuits. Thus, the processor 240 may be implemented in hardware, firmware, software, or any combination of these methods. The term “execution” refers to the process of running an application, program, or module or the carrying out of the operation called for by an instruction. The processor 240 executes a module meaning that it performs the operations called for by that module in the form of a series of instructions. The processor 240 may retrieve an application from a non-volatile memory that is generally some form of ROM or flash memory and may copy the instructions in an executable form to a temporary memory that is generally some form of RAM. The processor 240 may execute instructions embodied, for example, in the pipetting module 242. The computing device 200 may include one or more processor 240.
The pipetting module 242 is an organized set of instructions that, when executed, allow the user to create a program for execution by the pipette 30. The program defines operations for the pipette 30 to perform. The pipetting module 242 may be written using one or more programming language, assembly language, scripting language, etc. The term “execution” is the process of carrying out the instructions called for by the pipetting module 242. For the pipetting module 242 to execute, the application may be translated into a machine language that the computing device 230 understands. Launching the pipetting module 242 generally entails retrieving the pipetting module 242 in an executable form from a permanent memory device and copying the executable to a temporary memory device, generally some form of RAM. The permanent memory device may be, but is not limited to, a hard disk, a floppy disk, a CD-ROM, etc.
The pipette 30 may transmit and receive information from the computing device 230. Selection of the operational mode “program” causes the pipette 30 to execute a program module defined by the user on the computing device 230 using the pipetting module 242 and transmitted to the pipette 30 through the communication interface 234. The pipetting module 242 transmits the program module to the pipette 30 using the communication interface 234. The pipette 30 receives the program module using the communication interface 190. The program module includes the operations to be executed by the microprocessor of the pipette 30 after the user places the pipette 30 in the “program” operational mode. For example, the program module may be a table of instructions to the pipette 30. As another alternative, the program module may include a word or letter followed by a parameter value. A communication language may be developed for defining the operations to be executed by the pipette 30. The communication language may be similar to those that employ tags such as the hypertext markup language or the extensible markup language. To execute the program module that comprises the operational instructions to the pipette, the pipette 30 is placed into the program mode using the left operational mode button 182 or the right operational mode button 184.
The pipetting module 242 of the computing device 230 allows the user to easily create complex pipetting operations using the display 232 and the input interface 236 of the computing device 230 instead of the interface components of the pipette 30 described with reference to
In alternative embodiments, additional, fewer, or different operations may be definable using the pipetting module 242. For example, when specifying the “auto” operational mode in the program module, the user may additionally select among various aspirate/dispense/purge options. For example, in an exemplary embodiment, the user may select from three aspirate/dispense/purge options. In a first option, the pipette stops after dispensing the liquid and before purging. In a second option, the pipette dispenses the liquid and purges without stopping. In a third option, the pipette is operated in a classic manner wherein liquid is aspirated after a first depression of the aspirate/dispense button 180, liquid is dispensed after a second depression of the aspirate/dispense button 180 without releasing the aspirate/dispense button 180, and liquid is purged after a release of the aspirate/dispense button 180 and a third depression of the aspirate/dispense button 180.
It is understood that the invention is not confined to the particular embodiments set forth herein as illustrative, but embraces all such modifications, combinations, and permutations as come within the scope of the following claims. Those skilled in the art will recognize that the system and methods of the present invention may be advantageously operated on different platforms using different operating systems including but not limited to, a Microsoft® Windows based operating system, a Macintosh® operating system, LINUX based operating system, a UNIX® based operating system, etc. Additionally, the functionality described may be distributed among modules that differ in number and distribution of functionality from those described herein without deviating from the spirit of the invention. Additionally, the order of execution of the modules may be changed without deviating from the spirit of the invention. Thus, the description of the preferred embodiments is for purposes of illustration and not limitation.
Number | Date | Country | Kind |
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0313921 | Nov 2003 | FR | national |
0313920 | Nov 2003 | FR | national |
0402433 | Mar 2004 | FR | national |
0409442 | Sep 2004 | FR | national |
0409438 | Sep 2004 | FR | national |
0409443 | Sep 2004 | FR | national |