Innovative Methodology for Biotech

Our three-phase methodology integrates biological digitization, hybrid architecture, and validation for advanced micro-robotic applications in drug delivery and biochemistry.

A detailed view of a robotic device featuring a bright orange casing with multiple cameras or sensors. The design includes perforated sections for ventilation and exposed mechanical parts, indicating advanced technology and engineering.
A detailed view of a robotic device featuring a bright orange casing with multiple cameras or sensors. The design includes perforated sections for ventilation and exposed mechanical parts, indicating advanced technology and engineering.
A close-up view of a precision laboratory instrument with a metal component and a blue holder labeled 'DIATOME'. A gloved hand is using tweezers to manipulate a small object, indicating a meticulous scientific or technical procedure.
A close-up view of a precision laboratory instrument with a metal component and a blue holder labeled 'DIATOME'. A gloved hand is using tweezers to manipulate a small object, indicating a meticulous scientific or technical procedure.
A laboratory machine with a protective transparent cover is positioned on a counter. Next to it, a monitor is attached, and various cables are connected. The setting appears to be sterile, with a focus on technology and instrumentation.
A laboratory machine with a protective transparent cover is positioned on a counter. Next to it, a monitor is attached, and various cables are connected. The setting appears to be sterile, with a focus on technology and instrumentation.

Our Unique Approach

We utilize cutting-edge techniques like dual-pathway networks and swarm communication to enhance microfluidic navigation and drug delivery systems.

Innovative Methodology

Our three-phase methodology integrates biological digitization, hybrid architecture, and validation for advanced solutions.

Biological Digitization

We build chemotaxis databases and implement differentiable Berg-Purcell theory as physics constraints.

A small, toy-like yellow robot with large binocular-style eyes and track-like wheels is positioned on a smooth white surface. Its mechanical arm is slightly raised, and the design appears both endearing and functional.
A small, toy-like yellow robot with large binocular-style eyes and track-like wheels is positioned on a smooth white surface. Its mechanical arm is slightly raised, and the design appears both endearing and functional.
Hybrid Architecture

Our dual-pathway network combines CNN for spatial gradients and LSTM for temporal dynamics effectively.

We validate through microfluidic maze navigation tests and deploy micro-robot swarms for targeted drug delivery.

Validation Process
Hands are manipulating a small mechanical assembly, which includes metal and plastic components. The setup seems to involve green gears and metallic rods, indicative of a robotics or engineering-related activity.
Hands are manipulating a small mechanical assembly, which includes metal and plastic components. The setup seems to involve green gears and metallic rods, indicative of a robotics or engineering-related activity.
A person wearing green gloves is working in a laboratory setting, using a pipette to transfer liquid into small tubes placed in a pink rack. A red biohazard container is visible on the right side, and various lab equipment and documents are scattered around the workspace.
A person wearing green gloves is working in a laboratory setting, using a pipette to transfer liquid into small tubes placed in a pink rack. A red biohazard container is visible on the right side, and various lab equipment and documents are scattered around the workspace.
Innovation

Advancing drug delivery through microfluidic technology.

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