SU1673595A1 - Device for microinjections of a liquid into a live cell - Google Patents

Abstract

The invention relates to biology. The purpose of the invention is to improve the accuracy of the beam in the object. The device contains a mirror 1, an amplifier of brightness 2, a deflecting mirror 3, a microscope 4, a screen 6. A device for microinjection of a fluid inside a living non-fixed cell is carried out using a laser puncture of its membrane in a laser microscope circuit. 2 Il.

Description

The invention relates to medicine and can be used in biology, cytology, neurohistology, biophysics, as well as in other aspects related to studies of living non-fixed and biological objects.

The purpose of the invention is to improve the accuracy of falling into the object.

FIG. 1 shows a device for microinjection of a liquid; in fig. 2 is a diagram explaining his work.

The device contains a mirror 1. having the ability to rotate around the axis. The mirror can occupy a position both perpendicular to the optical axis of the laser amplifier of 2 brightness and parallel to it. The laser amplifier 2 brightness is a laser tube ILGI-10G or QUANT on copper vapor, generating monochromatic light with a wavelength of 510 nm. The device also contains a deflecting mirror 3, a biological microscope 4 with a set of short-focus and long-focus lenses of different resolutions, an object table of this microscope, on which a mirror is mounted that carries a bath with chemicals and the object under study 5, screen 6 (any screen can be used as a screen industrial screen or just a sheet of white paper, lens 7, deflecting mirror 8, deflecting image obtained from the end of the tube 2. expanded to the desired size with collimator lens 7 to screen 6

The device works as follows.

The laser amplifier 2 brightness emits, at a frequency of 10 kHz, pulses of light with a wavelength of 510 nm, which are captured by a mirror 3 through a microscope objective 4 on an object 5, which lies on the mirror of a microscope 4 (on its object table). Reflecting from this mirror, the light beam carrying the image of the object 5. Re-enters the laser amplifier 2 brightness, where it is amplified in brightness. The image enhanced by the brightness, expanded by the collimator lens 7 and deflected in the desired direction by the mirror 8, creates an image on the screen 6

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About VJ ate

the object under study (living cell). At the moment when a microinjection is required, the mirror 1 is rotated around an axis so that it becomes perpendicular to the axis of the laser amplifier 2, the mirror 1 and the mirror of the microscope 4 form an optical resonator, inside which the laser amplifier 21 appears, resulting in a laser beam focused by a microscope objective 4 at a specific point of object 5. This beam creates an orifice of a certain size in the membrane of object 5, through which the substance washing it enters object 5. When mirror 1 returns to its initial position (parallel to the beam), the laser effect disappears and the hole in the membrane of object 5 is drawn in, which leads to the cessation of microinjection. Moreover, the entire process of microinjection visually is observed on the screen b.

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Claims (2)

1. A device for microinjection of fluid inside a living cell, characterized in that, in order to increase accuracy the beam hits the object, it is performed in form located on the same optical axes of a biological microscope with a mirror placed on its table that serves support for cell floating in solution for injection, and a laser amplifier, as well as a mirror located on the site of its output end, which, together with the mirror of a biological microscope, makes up an optical resonator. 2. Device pop. 1, characterized in that, in order to provide visual monitoring of the injection process, it is provided with a screen mounted at the output of the laser amplifier of luminance behind the mirror.