CN206512221U - A kind of cell vesicle Fast Labeling device - Google Patents
A kind of cell vesicle Fast Labeling device Download PDFInfo
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- CN206512221U CN206512221U CN201621400850.1U CN201621400850U CN206512221U CN 206512221 U CN206512221 U CN 206512221U CN 201621400850 U CN201621400850 U CN 201621400850U CN 206512221 U CN206512221 U CN 206512221U
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- vesica
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Abstract
The utility model discloses a kind of cell vesicle Fast Labeling device, the device includes fluorescence microscope, the special living cells culture systems of microscope, glass microelectrode, pressure controller, egersimeter and gas cylinder, this method is to use a kind of glass microelectrode for patch clamp experiments, pass through certain frequency and the gas of pressure, vesica labeling dye in microelectrode is equably discharged into cell peripheral, stable dye strength is formed, specific vesica is marked so as to realize.Complete after mark, stop to gas, dye strength can rapidly be reduced because of diffusion, without elution process, can directly carry out the later observation of vesica dynamic change.This method, which can be realized fast and effeciently, to be marked and records in real time, so as to be greatly enhanced conventional efficient.
Description
Technical field
The utility model is related to a kind of use for laboratory device, specifically, be a kind of cell vesicle Fast Labeling device and
Method, the device is simple, and method efficiently, can carry out Real Time Observation record and experiment.
Background technology
The research of cell vesicle form and dynamic change carries out fluorescence labeling firstly the need of to vesica.At present, conventional mark
Note method be carried out with certain density fluorescent dye it is extracellular be incubated, it is to be marked it is upper after extracellular dyestuff is eluted, so
Observe and record to entering Mobile state under microscope afterwards, from mark, to elution, again to being transferred to observed and recorded under microscope, this
Process usually requires the time of 10-30 minutes.However, the vesica dynamic changing process of many types is very of short duration, in elution and
Huge change is just had occurred that during transfer, and the change procedure of this time can not be observed and record.
Therefore, the utility model is transformed on the basis of existing labeling method, is released using a kind of gas pressure in microelectrode
The device of micro labeling dye, and the phenomenon quickly spread in a liquid using dyestuff are put, the time of elution and transfer is saved,
Obtain the vesica labeling method of a kind of quick significant notation of energy and energy Real Time Observation record.
Utility model content
The purpose of this utility model is the cell for providing a kind of new quick significant notation and energy Real Time Observation record
Vesica labelling apparatus and method.
Cell vesicle Fast Labeling device of the present utility model, including the special living cells culture of fluorescence microscope, microscope
System, glass microelectrode, pressure controller, egersimeter and gas cylinder, gas cylinder (compressed air or nitrogen) connect with pressure controller
Connect, pressure controller output end connects glass microelectrode tail end by tracheae, egersimeter is connected with pressure controller for controlling
Vesica labeling dye is inoculated with the air pressure output frequency and duration of pressing pressure controller, glass microelectrode, it is micro- for being opposite to
Cell vesicle in the special living cells culture systems of mirror is marked, and fluorescence microscope carries out real-time monitored.
Preferably, described glass microelectrode tip can be 2 μm, external diameter 1mm, internal diameter 0.5mm.
The method that cell vesicle Fast Labeling is carried out using the utility model device, is comprised the following steps:
The corresponding vesica labeling dye of cell vesicle is poured into glass microelectrode, bubble is eliminated, the dyestuff amount of pouring into is glass
The length of glass microelectrode 2/3;
Gas cylinder (compressed air or nitrogen) is connected on pressure controller, regulation output pressure (being generally adjusted to 3psi),
Glass microelectrode tail end is connected by tracheae with pressure controller output end;
Egersimeter and pressure controller are connected, by setting the parameter of egersimeter come the air pressure of control pressure controller
Output frequency and duration;
Cell vesicle is marked in the special living cells culture systems of microscope, fluorescence microscope carries out real-time mark
Observation.
Completed after mark, stopped to gas, dye strength can rapidly be reduced because of diffusion using method of the present utility model,
The later observation of vesica dynamic change can be directly carried out without elution.
The utility model has following features:1) mark precision is high, can be marked for the cell specified;2) labeling process
Can accurately it control;3) it can be observed and be recorded without elution after marking;4) whole process is implemented under the microscope, mark
Process can be recorded in real time;5) synchronous medicine irritation can be realized.Therefore, device and method of the present utility model can quickly have criterion
Remember and energy Real Time Observation record.
Brief description of the drawings
Fig. 1 vesica labelling apparatus schematic diagrames.
Fig. 2 glass microelectrode micrographs, tip diameter is about 2 μm, graphic scale:5μm.
Dyestuff Sulforhodamine 101 (SR 101) diffusion property that Fig. 3 is discharged by microelectrode.Fig. 3 (a) fluorescence
Intensity detection schematic diagram, the concentric circles of different colours represents position (the concentric radius of circle apart from eletrode tip different distance respectively
Respectively 15 μm, 50 μm, 100 μm, 150 μm, 200 μm, 250 μm), graphic scale, 50 μm.The fluorescence intensities of Fig. 3 (b) SR 101
Quantitative analysis, all data do normalized on the basis of the fluorescence intensity level at 15 μm.300 μm of models of Fig. 3 (c) eletrode tips
Diffusion profiles of the interior fluorescent dye SR 101 in different time is enclosed, X and Y coordinates axle illustrates the position using eletrode tip as origin
Put.SR 101 reaches Stable distritation state in 5min or so, and keeps in 30min the stable state.
Vesica in Fig. 4 microglia transition processes can be dyed with the label Dextran of pinocytotic vacuole, in figure respectively
With Alexa Fluor 488dextran (3000MW, 1 μ g/ μ l;Green, AF3K) and Texas Red dextran (70,
000MW, 1 μ g/ μ l;Red, TR70K) pinocytotic vacuole is marked, graphic scale:10μm.
Dynamic change of Fig. 5 pinocytotic vacuoles in microglia transition process.Fig. 5 (a)-(c) pinocytotic vacuoles are different types of
Dynamic change.Fig. 5 (a) arrows indicate red and green in the vesicles split off from pinocytotic vacuole, Fig. 5 (b) and Fig. 5 (c)
Color arrow indicates that white and yellow arrows in the interaction between successively two pinocytotic vacuoles of formation, Fig. 5 (c) indicate vesica
Form the process that after ripening diminishes, graphic scale:10μm.The area that Fig. 5 (d) pinocytotic vacuoles enter after microglia dynamically becomes
Change statistical result.
Embodiment
The method involved by the utility model is described further with reference to embodiments.
The utility model proposes a kind of new vesica labeling method and device, this method is to be used for diaphragm using a kind of
The glass microelectrode of experiment is clamped, by certain frequency and the gas of pressure, the dyestuff in microelectrode is equably discharged into cell
Around, stable dye strength is formed, specific vesica is marked so as to realize.
As shown in Figure 1, realize the device of this method by laser confocal microscope (model:FV1000, Japan
Olympus companies), the special living cells culture systems (model of microscope:INU-ZILCS-F1, Japanese Tokai Hit companies), glass
Glass microelectrode (external diameter 1mm, internal diameter 0.5mm, article No. BF100-50-15, Sutter Instrument companies of the U.S.), pressure control
Device (model processed:PicospritzerIII, Parker companies of the U.S.), egersimeter (model:SEN-7103, Japanese Nihon
Kohden companies) and gas cylinder composition.Glass microelectrode draws instrument (model by microelectrode:P-97, U.S. Sutter
Instrument companies) prepare, tip diameter is about 2 μm, as shown in Figure 2.Corresponding vesica mark is poured into glass microelectrode
Dyestuff, about 2/3 length notes eliminating bubble.First, gas cylinder (compressed air or nitrogen) is connected to pressure controller
On, glass microelectrode is connected by regulation output pressure (generally 3psi) by tracheae with pressure controller;Secondly, connection electricity
Stimulator and pressure controller, by set the parameter of egersimeter come the air pressure output frequency of control pressure controller and when
It is long, to control the rate of release of vesica labeling dye in glass microelectrode.Complete after mark, stop to gas, dye strength can be because
Diffusion is reduced rapidly, and the later observation of vesica dynamic change can be directly carried out without elution.
Labeling process is implemented in the special living cells culture systems of microscope, it is ensured that CO in culture systems2Concentration be 5%,
Temperature control is at 37 DEG C or so, after instrument stabilizer, sets laser confocal microscope acquisition parameters, one is shot at regular intervals
Pictures, whole process can realize real-time live cell fluorescent observation and record.
Another glass microelectrode can be additionally utilized, the stimulation of certain drug is carried out to cell.
Device of the present utility model can be used for the cell that the adherent cell on slide is transferred to living cells culture systems
It is interior, L15 nutrient solutions or ECS are included, one layer of methyl-silicone oil of upper cover passes through the micro- electricity of glass to maintain the temperature and osmotic pressure of stabilization
Pole released dye and stimulation molecule, the steady concentration gradient of formation, the formation vesica of inducing cell are simultaneously labeled.Without elution,
The mark to cell vesicle can be fast and effeciently realized, conventional efficient can be greatly enhanced, there is great meaning to Bioexperiment
Justice.
Illustrated below using the Fast Labeling of microglia pinocytotic vacuole and recording method as instantiation:
Primary microglia culture and purifying
1) preparation:Get out overlay PDL 75-cm2Flask, and cleaned with aseptic double-distilled water;Wiped with cotton ball soaked in alcohol
Wipe operating theater instruments;Preparation ice chest, HBSS (4 DEG C of precoolings), (37 DEG C are pre- for MEM (containing 10% (vol/vol) FBS) nutrient solution and pancreatin
Heat).
2) newborn SD rat (P0-2) is taken, whole body spray disinfectant alcohol obtains rat head with head-breaking.
3) in super-clean bench, scalp and skull are cut off respectively along skull center line with eye scissors, and skull is peeled off with ophthalmic tweezers, it is small
The heart takes out brain, is quickly transferred in the 35-mm culture dishes (being placed on ice chest) of the HBSS containing precooling.
4) under anatomical lens, left and right brain hemisphere is separated with tying tweezer, meninx is removed, remaining blood sinus and blood vessel group is removed
Knit, remove core group and hippocampus, only stay cortex.
5) cortex is cut into 2-mm with tweezers3Fritter, cortex fragment is transferred to the 1.5-ml containing 0.25% pancreatin
In EP pipes (each two cortex 0.6ml pancreatin), 37 DEG C of digestion 12min.
6) digestion reaction is terminated with MEM (containing 10%FBS), piping and druming about 25 times of being exerted oneself in glass tube with 5-ml pipettors
Afterwards, 5min is stood, tissue block precipitation is waited, 500g centrifugations 5min at supernatant, 4 DEG C is collected.
7) supernatant is abandoned, cell precipitation is resuspended with MEM (containing 10%FBS), is inoculated in above ready flask (every
Individual flask kinds plant the cell concentration of about 2 cortexes), the nutrient solution in each flask is 10-15ml.
8) cell is placed on (95% air/5%CO in 37 DEG C of incubators2) culture, liquid is changed entirely within second day, afterwards every three
It partly changes liquid.
9) microglia is ripe after cultivating 6-8 days, now, is observed under phase contrast microscope, and astroglia is paved with
Bottom of bottle, in smooth silk shape, the visible cell that circle is full, bright, adherence quality is weak in upper strata, part has been suspended in nutrient solution
In, these cells are largely accredited as microglia;Shake flask gently makes cell detachment, collects at supernatant, 4 DEG C
500g centrifuges 5min.
10) supernatant is abandoned, is resuspended with 3-4ml MEM (containing 10%FBS), is planted on 8 × 8mm cover plates, hanged per the μ l of slide about 50
Liquid, cell density is about 4 × 104cells/cm2。
11) slide is placed on (95% air/5%CO in 37 DEG C of incubators2) 15min is stood, make cell attachment, Ran Houyong
MEM (containing 10%FBS) washes away not adherent cell, and adds fresh MEM (containing 10%FBS), is placed in 37 DEG C of incubators and treats
With standing time is no more than 2 days.
The method that microglia cultural method herein with reference to Nakajima, and slightly modified.Early-stage preparations and
Incubation probably needs the time of one week, and the microglia of high-purity can be obtained by this method, passes through immune dye
The method validation of color, its purity can be higher than 95%.
Vesica is marked and dynamic analysis
1) the special CO of microscope is utilized2Living cells culture systems, maintain stable cell state, and about 30min can make
System temperature reaches stable state.
2) pressure dosing system is connected, pressure output parameter (see Fig. 1) is set.
3) the ATP γ S (1mM) for inducing pinocytotic vacuole are poured into microelectrode and the dyestuff Dextran of pinocytotic vacuole is marked
(1 μ g/ μ l), about 2/3 length notes eliminating bubble.
4) obtained microglia will be purified in step 1 to be transferred on the chamber containing 1.5ml nutrient solutions, above
One layer of methyl-silicone oil of lid, to maintain temperature and the stabilization of osmotic pressure in experimentation.
5) microelectrode is moved on to above cellular layer with micro-manipulator, eletrode tip is located at the centre in the visual field.
6) DIC and the imaging of fluorescence channel time series, image chi are carried out with laser confocal microscope under 60 times of hydroscopes
Very little 1024 × 1024pixels, time interval 20sec, open thin after pressure dosing system, effect 10min simultaneously when imaging starts
Dextran on born of the same parents' basic token, stops pressure dosing system, and dyestuff dilutes rapidly because of diffusion, and without elution, this process connects
Continuous imaging terminates until experiment, total time 30-50min (such as Fig. 4 and Fig. 5).
7) obtain after image, the dynamic changing process of microglia pinocytotic vacuole is entered with softwares such as ImageJ and Imaris
Row is followed the trail of and analysis (such as Fig. 5).
Claims (2)
1. a kind of cell vesicle Fast Labeling device, it is characterised in that including fluorescence microscope, the special living cells culture of microscope
System, glass microelectrode, pressure controller, egersimeter and gas cylinder, gas cylinder (compressed air or nitrogen) connect with pressure controller
Connect, pressure controller output end connects glass microelectrode tail end by tracheae, egersimeter is connected with pressure controller for controlling
Vesica labeling dye is inoculated with the air pressure output frequency and duration of pressing pressure controller, glass microelectrode, it is micro- for being opposite to
Cell vesicle in the special living cells culture systems of mirror is marked, and laser confocal microscope carries out real to whole dynamic process
When observe and record.
2. cell vesicle Fast Labeling device according to claim 1, it is characterised in that described glass microelectrode tip
For 2 μm, external diameter 1mm, internal diameter 0.5mm.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107043698A (en) * | 2016-12-20 | 2017-08-15 | 浙江大学 | A kind of cell vesicle Fast Labeling device and method |
CN111122525A (en) * | 2019-12-11 | 2020-05-08 | 浙江大学 | Fluorescence-patch clamp-micro suction tube detection device |
-
2016
- 2016-12-20 CN CN201621400850.1U patent/CN206512221U/en not_active Withdrawn - After Issue
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107043698A (en) * | 2016-12-20 | 2017-08-15 | 浙江大学 | A kind of cell vesicle Fast Labeling device and method |
CN107043698B (en) * | 2016-12-20 | 2023-08-11 | 浙江大学 | Quick labeling device and method for cell vesicles |
CN111122525A (en) * | 2019-12-11 | 2020-05-08 | 浙江大学 | Fluorescence-patch clamp-micro suction tube detection device |
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