System and method for following and conducting laboratory procedures

Abstract

There is provided a system and method for following and conducting laboratory procedures for preventing errors and fatigue of the user. The system involves input means, such as a microscope, and a camera connected to the input means, while the camera creates images of the input means. A computer is connected to the camera, and it processes the images so that augmented reality glasses which are also connected to the computer, are capable of having those images projected thereon. The computer also has laboratory protocol files installed thereon, and it projects images of the protocols onto the glasses. The projected images do not interfere with a user's natural vision.

Claims

1. A system for following and conducting laboratory procedures simultaneously, said system comprising: input means; a camera connected to said input means, wherein said camera is configured to accept images captured by said input means; a computer connected to said camera, wherein said computer is configured for processing said images; and at least one pair of augmented reality glasses connected to said computer for projecting said images thereon; laboratory protocol files installed on said computer for being projected as images by said computer onto said glasses, and wherein said laboratory procedures are for In Vitro Fertilization (IVF) procedures including any of ovum pickup, oocyte screening, and in vitro maturation, wherein said augmented reality glasses have both said images of said protocols and said input means captured images projected thereon simultaneously while concurrently visually allowing a user to view through the glasses using the user's natural vision; and wherein said projected images prevent errors and fatigue of the user.

2. The system of claim 1, wherein said input means is selected from a group consisting of: a microscope, a stereomicroscope, an ultrasound transducer, an inverted microscope, and a device which is connected to said camera.

3. The system of claim 1, wherein said input means connection to said camera is selected from a group consisting of: a wireless, wired connection.

4. The system of claim 3, wherein said connection is wireless and a person situated away from a laboratory location wears said glasses and by so doing, supervises a lab worker's steps.

5. The system of claim 1, wherein said computer connection to said at least one augmented reality glasses is selected from a group consisting of: wireless, wired connection.

6. The system of claim 1, further comprising a Smartphone device including an application which transmits a protocol of at least one procedure selected from a group consisting of: a photo, a video and audio files, to said glasses via a cable or radio frequency transition.

7. The system of claim 1, wherein said input means is a stereomicroscope having a plurality of objectives, wherein each of the objectives thereof is displayed on a different screen of said augmented reality glasses, thereby providing a three dimensional image.

8. A method for following and conducting laboratory procedures simultaneously, said method comprising: wearing augmented reality glasses and connecting them to a computer; projecting a written laboratory protocol onto said augmented reality glasses for a user to read, enabling the user to follow steps of said protocol while conducting a laboratory procedure; connecting input means to a camera, wherein said input means examines a specimen and wherein said camera produces images of the specimen captured by said input means; connecting said camera to said computer, wherein said computer analyzes said images produced by said camera; and projecting said images of the specimen onto said augmented reality glasses, wherein said laboratory procedures are for In Vitro Fertilization (IVF) procedures including any of ovum pickup, oocyte screening, and in vitro maturation; wherein said augmented reality glasses have both said images of said protocol and said input means captured images projected thereon simultaneously while concurrently visually allowing the user to view through the glasses using the user's natural vision; and wherein said produced images are a video sequence and the specimen is being micromanipulated while viewing the specimen through said augmented reality glasses.

9. The method of claim 8, wherein said input means is an electrical device configured to be connected to a camera.

10. The method of claim 8, wherein said method further comprises a step of identifying the specimen situated in a petri dish by screening a barcode attached thereon with said augmented reality glasses.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Preferred embodiments, features, aspects and advantages of the present invention are described herein in conjunction with the following drawings:

(2) FIG. 1 shows a prior art example of a user viewing a specimen through a microscope eyepiece, also having a digital screen connected to the microscope;

(3) FIG. 2 shows a system for following and conducting laboratory procedures;

(4) FIG. 3 shows a petri dish with a barcode;

(5) FIG. 4 shows a specimen under a microscope under the treatment of a micromanipulator;

(6) FIG. 5 shows augmented reality glasses of the present invention showing an image of a specimen being micro manipulated;

(7) FIG. 6 shows the augmented reality glasses, showing a specimen image and a protocol image projected onto the glasses; and

(8) FIG. 7 shows a schematic block diagram of the system and method of the present invention.

(9) It should be understood that the drawings are not necessarily drawn to scale.

DETAILED DESCRIPTION OF THE EMBODIMENTS

(10) The present invention will be understood from the following detailed description of preferred embodiments (“best mode”), which are meant to be descriptive and not limiting. For the sake of brevity, some well-known features, methods, systems, procedures, components, circuits, and so on, are not described in detail.

(11) In FIG. 1 there is shown a prior art example of a user viewing a specimen through a microscope eyepiece. The microscope is connected to a digital screen which shows an image of the specimen.

(12) In FIG. 2 there is shown a system for following and conducting laboratory procedures 30. System 30 includes augmented reality glasses 32 which are connected to computer 34 via a wireless or wired connection and a microscope 36, connected to computer 34. A screen 35 may also be connected to computer 34. A video and stills camera (not shown) is connected to microscope 36. A specimen 38 is placed under microscope 36 for viewing, manipulating or treating specimen 38. The camera can photograph images, or shoot videos, of specimen 38 and project those images and movies onto glasses 32. The videos and photographed images may be saved for backup or evidence. A user (typically a lab worker or scientist) wearing glasses 32 can view specimen 38 without using an eyepiece of microscope 36, which can be very tiring after using the eyepiece for a long period of time. The glasses 32 have clear lenses so that the user has a regular view of his surroundings in addition to a view of the projected images.

(13) In addition to having images from specimen 38 projected onto glasses 32, images of lab protocols can be projected. images of computer documents of various types, such as .pdf, .gif, .jpg etc., may be projected. The advantage of having protocols projected onto a user's glasses 32, is that the user can carefully follow the steps of the laboratory protocol while conducting the protocol, and therefore will not forget any step, and errors will be prevented.

(14) In addition glasses 32 may be adapted to reflect the visual characteristics of a user, such that if the user is near sighted or far sighted, the image presented on glasses 32 is adapted accordingly.

(15) Glasses 32 may have a camera installed thereon for taking photos and videos.

(16) In another embodiment of the system 30, a Smartphone features applications which transmit protocols of various procedures including photos, video and audio files, to the glasses via a cable or RF transmission.

(17) In FIG. 3 there is shown a petri dish having a barcode 42 attached to its side, for scanning to a matching system. Barcode 42 holds information regarding the identity of the individual to whom specimen 38 (not shown here) belongs. Glasses 32 have the ability to scan a barcode 42 and read it so that the information regarding the individual will appear on glasses 32 for the user to view, and the information will be compared to a database. The matching system alerts the user if there is a mismatch by projecting a warning onto glasses 32. This feature is very important for any lab, but particularly for an IVF lab which handles both sperm specimens and egg specimens and needs to “mix” them in order for fertilization to take place. It is obviously crucial for a sperm specimen of a man to fertilize the egg specimen of his female spouse. The results of a mistake in this stage are devastating. Therefore, many precautions are to be taken to prevent such a mistake. Before working with a certain specimen, the user must scan the barcode 42, with glasses 32, on petri dish 40 so that the matching system of glasses 32 can make sure the correct specimen is being handled.

(18) In FIG. 4 there is shown microscope 36 having petri dish 40 placed under microscope's 36 objective 44, and a micromanipulator 46 is shown treating a specimen in petri dish 40. A camera (not shown) is connected to microscope 36 and glasses 32 (not shown here) are connected to the camera so that images taken by the camera are projected onto glasses 32, still and videos alike. The embryologist micromanipulating the specimen does not need to see it via the eyepiece of microscope 36, he can see everything on glasses 32, in real time. Using this method, IMSI (sperm morphology) can be done, as well as Intra Cytoplasmatic Sperm Injection (ICSI), laser assisted hatching or any other specific micromanipulation. For example, oocyte vitrification can be performed by projecting the oocyte vitrification protocols of different companies (such as Origio, Kitazato or Vitrolife, inclusive of preparation of the various solutions and devices). Imaging of the various stages of equilibration and vitrification can be seen. Because each step is time dependent, glasses 32 are able to notify the embryologist of the time to perform the next procedure.

(19) In vitro culture (IVC) and embryo monitoring by time-lapse systems such as Embryoscope, Primovision, Eeva, Gavi, etc., can be connected to glasses 32, and embryo images are projected thereon.

(20) Using glasses 32 is a very convenient method for training new employees. A simulation of the procedures can be displayed on the glasses as well.

(21) FIG. 5 shows augmented reality glasses 32 showing an image of a specimen (38) being micromanipulated. Any common IVF procedure may benefit from using glasses 32, also a procedure known as Ovum Pick Up (OPU) which is a procedure for extracting eggs from a woman's ovaries. An OPU procedure is executed by inserting a needle through the vaginal wall and into an ovarian follicle. This procedure is done under the guidance of an Ultrasound (U.S) device, and the physician needs to keep his eye on a screen showing the U.S images, during the entire procedure. By using glasses 32, there is no need to look at the screen, the U.S images are projected to glasses 32, so that the physician need not glance away from the patient to the screen. Using this method, the entire procedure is smoother, quicker and safer.

(22) Embryo transfer (ET) into a patient's uterus can also be done using glasses 32. Ultrasound images of the endometrium will be projected onto glasses 32. Additionally, the physician performing the transfer can evaluate the embryos as seen in the stereomicroscope and will be read the details of the couple.

(23) An additional example of a procedure that can be done using glasses 32 is sperm collection and evaluation; images of the analyzed sperm can appear on the glasses, as well as images of the sperm parameters from the microscope. Digital magnification and morphology evaluation additionally can be seen.

(24) In FIG. 6 there is shown augmented reality glasses 32 showing a specimen image and a protocol image projected onto glasses 32. The wearer of glasses 32 can see both the image of the specimen and the written protocol of the procedure he is conducting.

(25) In FIG. 7 there is shown a schematic block diagram of the architecture of the system and method of the invention. Block 50 represents the various input means that may be used for system 30, such as microscope, stereomicroscope, an inverted microscope, barcode scanner, U.S transducer, etc. Arrow 52 represents the processing of the input information of block 50, and block 54 represents the various processing operations done with the input of block 50. Arrow 56 represents the output resulting from processing operation 54, which is projected onto either/both screen 35 and augmented reality glasses 32.

(26) In the figures and/or description herein, the following reference numerals (Reference Signs List) have been mentioned: The system for following and conducting laboratory procedures 30 Augmented reality glasses 32 Input means 33 Computer 34 Computer screen 35 Microscope 36 Specimen 38 petri dish 40 barcode 42 Microscope objective 44 Micromanipulator 46

(27) The foregoing description and illustrations of the embodiments of the invention has been presented for the purposes of illustration. It is not intended to be exhaustive or to limit the invention to the above description in any form.

(28) Any term that has been defined above and used in the claims, should be interpreted according to this definition.

(29) The reference numbers in the claims are not a part of the claims, but rather used for facilitating the reading thereof. These reference numbers should not be interpreted as limiting the claims in any form.