CRISPR Controls | Thermo Fisher Scientific

Validated positive and negative CRISPR controls

High-quality controls play an integral role in the successful development of CRISPR-Cas9 experiments, as well as the performance of high throughput CRISPR-Cas9 screens. Thermo Fisher Scientific provides a complete collection of validated positive and negative controls to help optimize delivery conditions, maximize editing efficiency, and establish hit selection criteria. These controls will help build robust assays with a better signal to noise ratio.

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About CRISPR controls

Type of control	Description	Recommended use
CRISPR positive controls	A CRISPR positive control is necessary to monitor the gene editing efficiency of the CRISPR reagents being used in the experimental design. Positive controls are validated gRNA sequences that have demonstrated high editing efficiency across different cell types. Some positive controls offered By Thermo Fisher Scientific offer up to 90% editing efficiency or greater in several cell types. Individual LentiArray and TrueGuide gRNAs are available.	Positive controls are intended to be used during assay development to determine the conditions that provide maximum editing efficiency in your cell models. Individual gRNAs against specific genes are available to serve as biological controls for both assay development and as on-plate positive controls when performing your screen.	Order
CRISPR negative controls	A CRISPR negative control is necessary to show that the observed phenotype is the result of the intended genetic modification and is not a result of other non-specific events. Negative controls are non-targeting control gRNA sequences that do not recognize any sequence in the human genome.	Thermo Fisher Scientific non targeting control gRNA negative controls are available in multiple package sizes for use in both assay development and as on-plate controls when performing screening assays.	Order
CRISPR delivery optimization controls	CRISPR delivery optimization controls are necessary to be sure that transfection was successful. Specific to the LentiArray CRISPR libraries, Thermo Fisher Scientific offers a set of control lentiviruses that are available as either negative or positive controls that express GFP.	The GFP marker provides a visual readout to aid in the rapid optimization of viral delivery conditions.	Order

Type of control

Description

Recommended use

CRISPR positive controls

A CRISPR positive control is necessary to monitor the gene editing efficiency of the CRISPR reagents being used in the experimental design. Positive controls are validated gRNA sequences that have demonstrated high editing efficiency across different cell types. Some positive controls offered By Thermo Fisher Scientific offer up to 90% editing efficiency or greater in several cell types.

Individual LentiArray and TrueGuide gRNAs are available.

Positive controls are intended to be used during assay development to determine the conditions that provide maximum editing efficiency in your cell models.

Individual gRNAs against specific genes are available to serve as biological controls for both assay development and as on-plate positive controls when performing your screen.

Order

CRISPR negative controls

A CRISPR negative control is necessary to show that the observed phenotype is the result of the intended genetic modification and is not a result of other non-specific events. Negative controls are non-targeting control gRNA sequences that do not recognize any sequence in the human genome.

Thermo Fisher Scientific non targeting control gRNA negative controls are available in multiple package sizes for use in both assay development and as on-plate controls when performing screening assays.

Order

CRISPR delivery optimization controls

CRISPR delivery optimization controls are necessary to be sure that transfection was successful. Specific to the LentiArray CRISPR libraries, Thermo Fisher Scientific offers a set of control lentiviruses that are available as either negative or positive controls that express GFP.

The GFP marker provides a visual readout to aid in the rapid optimization of viral delivery conditions.

Order

Data: Optimize assay design with GFP controls

In the following experiment, HT1080 cells were infected with LentiArray CRISPR Control Lentivirus, human HPRT, with GFP. This technique provides a visual readout of transduction efficiency and helps determine the multiplicity of infection (MOI) for the cell line being used. This example illustrates how green fluorescent protein (GFP) enabled controls can be used to optimize transduction and assay design.

Two microscopic images of cells glowing with green fluorescent protein, one CRISPR positive control and one CRISPR negative control

Figure 1. HT1080 cells infected with LentiArray CRISPR Positive Control Lentivirus, human HPRT, and GFP.

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Resources and user guides for CRISPR controls

Gene editing resources and support

Resources

Support

For Research Use Only. Not for use in diagnostic procedures.