Provided herein are collection devices for semen. The collection device may be a collection cup with an open top and a closed bottom with a collection cavity therewithin. The open top and closed bottom are oriented such that an angle greater than 0 degrees is formed by an intersection of a plane across the open top with a plane across the closed bottom. Alternatively, the collection cup is removably attached to a flow-through receptacle which is in fluid communication therewith.

Provided herein are devices and methods for analysis of male fertility. The invention provides self-contained, hand-held receptacles and systems for collection and analysis of semen samples and methods of using such devices to analyze semen samples. Also provided are processor-implemented and machine learning methods of analyzing semen sample data obtained using devices of the invention.

A method for preparing an agonist for improving boar sperm motility includes: (1) collecting and infiltrating a testicular tissue of a young boar 3-5 days after born; (2) washing the tissue with PBS; (3) incubating the tissue in a cell culture medium, and centrifuging the cell suspension to remove a supernatant; (4) adding hyaluronidase and collagenase IV followed by shaking, and adding the cell culture medium and centrifuging to remove a supernatant; (5) adding trypsin and deoxyribonuclease followed by shaking, and adding the cell culture medium; (6) filtering the cell suspension by a cell sieve; (7) centrifuging to remove a supernatant, and adding the cell culture medium; (8) culturing and passaging the cells; (9) culturing and storing the cell suspension. The invention has the advantages of good application effect, low cost and simple production process.

Disclosed herein is method and system for determining quality of semen sample. Trajectories of objects, identified in each of plurality of image frames of semen sample, are generated by tracking movement of the objects across image frames, and compensating a drift velocity of the semen sample. Further, generated trajectories are classified into sperm and non-sperm trajectories. Finally, total concentration estimate and total motility estimate of the semen sample are computed to generate a semen quality index, which indicates quality of the semen sample. In an embodiment, the method of present disclosure uses a multi-level Convolutional Neural Network (CNN) analysis technique for effectively classifying the object trajectories into sperm and non-sperm objects. Also, since the present method includes estimating and compensating drift velocity in the semen sample, it enhances overall accuracy of motility estimation and semen quality analysis.

Disclosed herein is method and system for evaluating semen quality. Plurality of images of stained semen sample are captured and analyzed for eliminating unusable images. Further, visible objects in the images are extracted and classified into sperm objects and non-sperm objects. The sperm objects are further classified into normal/abnormal sperm objects based on morphological characteristics of sperm objects, and a differential count of normal/abnormal sperm objects is determined. Subsequently, an aggregate count of the non-sperm objects is determined. Finally, a sperm quality index, indicative of quality of the semen sample, is computed based on morphological characteristics of sperm objects, differential count of normal/abnormal sperm objects, aggregate count of non-sperm objects and total motility estimate of semen sample. The method of present disclosure helps in accurate estimation of the semen quality, since the aggregate count of the non-sperm objects is considered as a crucial parameter for computing the semen quality index.

To include a rotating holder 30 that is rotatably arranged in an opening of a casing 10 and detachably holds a part of a sperm sampler, a motor 50 that rotates and drives the rotating holder, a control unit 60, a battery 70, a single switch 20, 67, and an angular speed sensor 61 that detects an angular speed of the casing 10, where the control unit changes a rotation direction and a rotation speed of the motor according to a change in a turning angle of the casing 10.

The present disclosure provides a sperm collection device, including at least one driving unit, and a soft main body wrapping the at least one driving unit. The soft main body includes a penis passage. The at least one driving unit is configured to vibrate an inner wall of the penis passage and provide a squeezing force to the penis passage.

A sampling device for collecting and dispensing a sample is disclosed, the sampling device including a sample collector having an absorbent portion configured to collect a sample and a receiving section configured to receive the sample collector after the collection of the sample. In one embodiment, the receiving section includes a dropper, the sample collector configured to be secured to the dropper, the dropper defining an internal chamber in which the absorbent portion of the sample collector is received when the sample collector is secured to the dropper; and a base releasably engaged with the dropper and at least partially housing the dropper, wherein the dropper is configured to be released from the base to allow dispensing of the sample from the dropper. In one embodiment, the absorbent portion interferes with a surface of an internal chamber of the receiving section. In one embodiment, a length adapter for the sample collector is employed and, in another embodiment, a desiccant housing is employed.

System and associated method for capturing, preserving, and transporting a bodily fluid, including a collection jar having a base body, a lid body, and a plunger, the plunger housing a preservative when in a first plunger position and permitting a release of the preservative into an internal cavity of the collection jar when in a second plunger position, where the plunger moves from the first plunger position to the second plunger position by pushing the plunger into the internal cavity, and a transportation packaging having an outer container, at least one vacuum insulated panel, at least one phase change material bottle, and at least one collection jar holding tray, where the phase change material bottle has an indented portion corresponding to an indented portion of the collection jar holding tray, where the collection jar is configured for placement in the at least one collection jar holding tray during transportation.

The present invention provides a microfluidic device with a confined geometry for isolating a slither-capable subpopulation of sperm which is of higher quality than the raw sperm population. The proposed device isolates slither-capable sperm based on their ability to enter and traverse a confined region where 3D locomotion is restricted. The DNA integrity of the selected sperm was higher than that of the corresponding raw samples by 55% and 122% for donors and patients, respectively. In side-by-side testing this method outperforms current clinical selection methods, density gradient centrifugation and swim-up, as well as sperm selected via general motility. Slithering represents a viable selection mechanism, readily applicable to clinical workflows with the potential to improve outcomes for couples and offspring.