MENÚ
AR | ARS
-
-
-
-
- Advanced Therapies Week (ATW) 2025
- Forum Labo 2025
- SLAS Europe 2025
- Bioprocessing Summit Europe 2025
- Medlab Middle East 2025
- SLAS International 2025
- Biologics World Nordics 2025
- ASIA LABEX: The Lab Show 2025
- BioProcess International Europe 2025
- ISEV 2025
- Future Labs Live 2025
- Cell 2025
- ASIA LABEX: The Lab Show 2025
- Stem Cell Community Day 2025
-
-
-
-
- Advanced Therapies Week (ATW) 2025
- Forum Labo 2025
- SLAS Europe 2025
- Bioprocessing Summit Europe 2025
- Medlab Middle East 2025
- SLAS International 2025
- Biologics World Nordics 2025
- ASIA LABEX: The Lab Show 2025
- BioProcess International Europe 2025
- ISEV 2025
- Future Labs Live 2025
- Cell 2025
- ASIA LABEX: The Lab Show 2025
- Stem Cell Community Day 2025
AR | ARS
-
- Pipeteo manual & dispensación
- Pipetas mecánicas
- Pipetas electrónicas
- Pipetas multicanal
- Pipetas de desplazamiento positivo y dispensadores
- Pipeteo automatizado
- Dispensadores de botella
- Controladores de pipeta
- Puntas de pipeta
- Consumibles de automatización
- Accesorios para dispensadores y pipetas
- Accesorios de automatización
- Servicios para dispensadores y pipetas
Está a punto de abandonar este sitio.
Por favor, tenga en cuenta que su carro de la compra actual no ha sido guardado todavía y no podrá ser restablecido en el nuevo sitio ni cuando regrese. Si desea guardar su carro de la compra, inicie sesión en su cuenta.
Sorry, we couldn't find anything on our website containing your search term.
Cell Culture FAQ: How to minimize the risk of a clogged microcapillary in cell injections?
Academia de laboratorio
- Biología celular
- Cultivo celular
- Consumibles para cultivo celular
- Preguntas más frecuentes
Answer by Dr. Sandra Stobrawa, Application Specialist Cell Handling at Eppendorf
This article appeared first in “Inside Cell Culture”, the monthly newsletter for cell culture professionals
Particles in the microinjection solution can quickly clog the fine opening (around 0.5 µm) of an injection capillary and prevents further microinjections with this capillary. Capillary exchange in general means slowing down of the injection experiment and increased time outside the incubator. However, the frequency of capillary exchange depends not only on the type and concentration of the microinjection sample, but also on the quality of the sample preparation.
For proper preparation of microinjections, all buffer solutions should be filtered through 0.2 µm pore size filters before adding the injection sample. And most importantly, the injection sample should be centrifuged for 15 - 20 min at 4 °C (approx. 16,000 x g) just before loading the supernatant into the microinjection capillary. This significantly reduces any precipitation in the sample and effectively prevents a clogged microcapillary.
Furthermore, your sample-loaded microcapillary should enter the medium of your injection dish with a continuous flow at low pressure generated by the microinjector (compensation pressure). This keeps the solution moving with the molecules, reducing the risk of clogging by debris from the medium surface. It also prevents the medium from entering the microcapillary by capillary forces, which would dilute the injection solution and impact your microinjection experiment.
Particles in the microinjection solution can quickly clog the fine opening (around 0.5 µm) of an injection capillary and prevents further microinjections with this capillary. Capillary exchange in general means slowing down of the injection experiment and increased time outside the incubator. However, the frequency of capillary exchange depends not only on the type and concentration of the microinjection sample, but also on the quality of the sample preparation.
For proper preparation of microinjections, all buffer solutions should be filtered through 0.2 µm pore size filters before adding the injection sample. And most importantly, the injection sample should be centrifuged for 15 - 20 min at 4 °C (approx. 16,000 x g) just before loading the supernatant into the microinjection capillary. This significantly reduces any precipitation in the sample and effectively prevents a clogged microcapillary.
Furthermore, your sample-loaded microcapillary should enter the medium of your injection dish with a continuous flow at low pressure generated by the microinjector (compensation pressure). This keeps the solution moving with the molecules, reducing the risk of clogging by debris from the medium surface. It also prevents the medium from entering the microcapillary by capillary forces, which would dilute the injection solution and impact your microinjection experiment.
Leer más
Leer menos
