Embedding-driven clusters
Unbiased similarities and differences in your data
Model even the most subtle biology with unbiased phenotypic clustering
Unbiased similarities and differences in your data
Model even the most subtle biology with unbiased phenotypic clustering
Unbiased similarities and differences in your data
Model even the most subtle biology with unbiased phenotypic clustering
Unbiased similarities and differences in your data
Model even the most subtle biology with unbiased phenotypic clustering
Find similarities and differences in conditions
Unbiased phenotypic clustering brings AI's superhuman ability to detect similarities and differences in experimental conditions to your scientists' fingertips
Take advantage of all the data in your images
Spring's embedding-driven technology makes use of all of the data in your images, as opposed to just one marker or readout or even set of traditional features
Cluster your most difficult, subtle phenotypes
All combined, this unbiased phenotypic technology excels at clustering even the most difficult, subtle cellular phenotypes
Your images have data you may not be using (yet)
The data size and complexity created by high-content imaging and microscopy in general is exploding, yet scientists' are often equipped with yesterday's software for taking advantage of this data. These images are ridiculously powerful, full of rich features and biological signal that can only be unlocked with cutting edge, unbiased AI-driven analytical approaches. Unlock this data for your team today with Spring's unbiased clustering technology.
Your images have data you may not be using (yet)
The data size and complexity created by high-content imaging and microscopy in general is exploding, yet scientists' are often equipped with yesterday's software for taking advantage of this data. These images are ridiculously powerful, full of rich features and biological signal that can only be unlocked with cutting edge, unbiased AI-driven analytical approaches. Unlock this data for your team today with Spring's unbiased clustering technology.
Your images have data you may not be using (yet)
The data size and complexity created by high-content imaging and microscopy in general is exploding, yet scientists' are often equipped with yesterday's software for taking advantage of this data. These images are ridiculously powerful, full of rich features and biological signal that can only be unlocked with cutting edge, unbiased AI-driven analytical approaches. Unlock this data for your team today with Spring's unbiased clustering technology.
Your images have data you may not be using (yet)
The data size and complexity created by high-content imaging and microscopy in general is exploding, yet scientists' are often equipped with yesterday's software for taking advantage of this data. These images are ridiculously powerful, full of rich features and biological signal that can only be unlocked with cutting edge, unbiased AI-driven analytical approaches. Unlock this data for your team today with Spring's unbiased clustering technology.
From unbiased clusters to mechanism of action
Cluster your well- and single-cell phenotypes in an unbiased manner to uncover all sorts of biological mechanisms. These clusters can be colored or filtered by metadata — explore and narrow down which experimental conditions are driving each phenotypic cluster, and what phenotypes are in each cluster, to gain unprecedented insight into mechanism of action.
From unbiased clusters to mechanism of action
Cluster your well- and single-cell phenotypes in an unbiased manner to uncover all sorts of biological mechanisms. These clusters can be colored or filtered by metadata — explore and narrow down which experimental conditions are driving each phenotypic cluster, and what phenotypes are in each cluster, to gain unprecedented insight into mechanism of action.
From unbiased clusters to mechanism of action
Cluster your well- and single-cell phenotypes in an unbiased manner to uncover all sorts of biological mechanisms. These clusters can be colored or filtered by metadata — explore and narrow down which experimental conditions are driving each phenotypic cluster, and what phenotypes are in each cluster, to gain unprecedented insight into mechanism of action.
From unbiased clusters to mechanism of action
Cluster your well- and single-cell phenotypes in an unbiased manner to uncover all sorts of biological mechanisms. These clusters can be colored or filtered by metadata — explore and narrow down which experimental conditions are driving each phenotypic cluster, and what phenotypes are in each cluster, to gain unprecedented insight into mechanism of action.
Find similarities and differences between many conditions
Experiments with multiple controls, conditions, and compounds can be analyzed in many different ways. With our phenotypic clustering technology, scientists can quickly discover the conditions or drugs that are most similar to each other, those most dissimilar, and what's driving these similarities or differences — all with an unbiased computational approach.
Find similarities and differences between many conditions
Experiments with multiple controls, conditions, and compounds can be analyzed in many different ways. With our phenotypic clustering technology, scientists can quickly discover the conditions or drugs that are most similar to each other, those most dissimilar, and what's driving these similarities or differences — all with an unbiased computational approach.
Find similarities and differences between many conditions
Experiments with multiple controls, conditions, and compounds can be analyzed in many different ways. With our phenotypic clustering technology, scientists can quickly discover the conditions or drugs that are most similar to each other, those most dissimilar, and what's driving these similarities or differences — all with an unbiased computational approach.
Find similarities and differences between many conditions
Experiments with multiple controls, conditions, and compounds can be analyzed in many different ways. With our phenotypic clustering technology, scientists can quickly discover the conditions or drugs that are most similar to each other, those most dissimilar, and what's driving these similarities or differences — all with an unbiased computational approach.
See it in action
“This is an amazing software platform to handle single-cell phenotypes. I haven’t seen anything else on the market like it.”
— Head of Imaging, Big Pharma
“This is an amazing software platform to handle single-cell phenotypes. I haven’t seen anything else on the market like it.”
— Head of Imaging, Big Pharma
“This is an amazing software platform to handle single-cell phenotypes. I haven’t seen anything else on the market like it.”
— Head of Imaging, Big Pharma
See what happens when scientists use Spring
Ready to get started?
Try out our tools with your existing workflow, or we can create a custom experience for you.
For industry
Spring tools are licensed by pharma, biotechs, startups, and research groups of all kinds.
For academics
We make it easy for academic research groups and non-profits to try Spring's tools.
For educators
Educators are invited to use Spring in the classroom and with their research students.
Ready to get started?
Try out our tools with your existing workflow, or we can create a custom experience for you.
Ready to get started?
Try out our tools with your existing workflow, or we can create a custom experience for you.
Ready to get started?
Try out our tools with your existing workflow, or we can create a custom experience for you.
Ready to get started?
Try out our tools with your existing workflow, or we can create a custom experience for you.
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