SENSORA

Molecular-Level Precision

Wearable Health Technology

Sensora Molecular-Level Wearable Sensor

The world's first flexible biosensor combining Molecular Imprinting (MIP) and Laser-Induced Graphene (LIG) — delivering lab-grade biomarker analysis from your sweat, continuously and non-invasively.

Patents Filed

Nature-Level Papers

Citations

0 cycles

Repeatability Verified

See It in Action

Watch how the Sensora patch seamlessly integrates into daily life — from application to real-time biomarker data on your phone.

How It Works

Wear

Apply the ultra-thin, flexible patch to your skin — designed for comfort during any activity.

Sense

MIP cavities selectively capture target biomarkers from sweat. LIG electrodes detect electrochemical signals.

Transmit

NFC wireless technology sends real-time data to your smartphone — no battery required in the patch.

Analyze

The Sensora app displays biomarker trends, health insights, and personalized recommendations.

Core Technology

Molecular Imprinting (MIP)

MIP creates synthetic antibody-like cavities that selectively bind specific molecules (e.g., uric acid, glucose, cortisol) with exceptional specificity. Unlike traditional biosensors that use biological antibodies, MIP is stable, reusable, and manufacturable at scale — enabling affordable precision diagnostics.

Template Molecule

Polymerization

Template Removal

Selective Binding

Template Molecule

Polymerization

Template Removal

Selective Binding

96% selectivity against interferents — comparable to biological antibodies

Laser-Induced Graphene (LIG)

A CO₂ laser directly converts polyimide film into porous, conductive graphene electrodes. This single-step process creates flexible, biocompatible electrodes ideal for skin contact. LIG electrodes have high surface area for sensitive electrochemical detection and can be manufactured at low cost.

Polyimide Film

CO₂ Laser Scan

Graphene Formation

Flexible Electrode

Polyimide Film

CO₂ Laser Scan

Graphene Formation

Flexible Electrode

Single-step manufacturing — 10× lower cost than traditional electrode fabrication

Lab Validated

Performance Data

Validated through rigorous laboratory testing and peer-reviewed publications in Nature-level journals.

Achieved Detection Limit

1.17 nM

Arginine detection — lab-grade precision from sweat

Sensing Principle

Electrochemical Impedance Spectroscopy (EIS)

Nyquist plots from 3 MIP compositions validated. Sensitivity increases with crosslinker concentration.

Sensor Performance Metrics

Selectivity vs. Interferents96%

Repeatability (30 cycles)98%

Signal Stability94%

LOD vs. Blood Test99% match

Skin Comfort Score97%

Data from peer-reviewed publications in Nature Catalysis, ACS Sustainable Chemistry & Engineering, JACS, and Reaction Chemistry & Engineering. 2,000+ citations.

Technical Specifications

Sensor Type

Electrochemical biosensor (amperometric/potentiometric)

Detection Method

Molecular Imprinting + Laser-Induced Graphene

Target Biomarkers

Uric acid, glucose, cortisol, lactate, arginine, and more

Achieved LOD

1.17 nM (Arginine) — lab-grade precision

Sensing Principle

Electrochemical Impedance Spectroscopy (EIS)

Sample Matrix

Sweat (non-invasive)

Communication

NFC (ISO 15693) — passive, no battery in patch

Form Factor

Ultra-thin flexible patch (~0.3mm)

Electrode Material

PtIr + PEDOT:PSS microelectrodes

Repeatability

Verified over 30 cycles at 10kHz

Biocompatibility

Skin-safe materials, hypoallergenic

Data Platform

iOS / Android app with cloud sync

Use Cases

🏃

Sports Performance

Monitor lactate, electrolytes, and hydration in real time during training and competition.

Lactate · Electrolytes · Hydration

💊

Chronic Disease Management

Track glucose, uric acid, and cortisol for diabetes, gout, and stress management.

Glucose · Uric Acid · Cortisol

🏭

Occupational Health

Monitor workers in high-stress environments for fatigue biomarkers and health alerts.

Fatigue Biomarkers · Alerts

🔬

Clinical Research

Continuous, non-invasive biomarker collection for clinical trials and population studies.

Continuous · Non-invasive

Market Opportunity

Sensora targets the intersection of high-value, low-competition segments in the global wearable biosensor market.

Sports Tech32%

Chronic Care28%

Wellness24%

Research Tools16%

12%+ CAGR · $7.8B+ in 2024

Development Roadmap

Phase 1: R&D

Prototyping, lab testing, academic collaborations (0–12 months)

Phase 2: Vertical

Sports wearables, health management go-to-market

Phase 3: Platform

Multi-molecule targets, SaaS layer, licensing

Angel / Pre-Seed Round

$300K target · 60% prototyping & testing · 20% validation · 20% team & IP

Backed by the Community

Sensora launched on Indiegogo to bring this breakthrough technology directly to early adopters worldwide. Join the movement toward truly personalized, non-invasive health monitoring.

QUESTIONS

Sensor FAQ

Currently, the sensor is designed to detect cortisol, glucose, lactate, uric acid, and electrolytes from sweat. Our MIP technology can be customized to target additional biomarkers based on research or enterprise needs.

Yes. The sensor uses a thin, flexible substrate that conforms to your skin. It is lightweight (under 5g), breathable, and designed for extended wear during exercise, sleep, or daily activities.

Each disposable sensor patch is designed for 7-14 days of continuous use. The reusable electronics module has a battery life of approximately 72 hours per charge.

Our peer-reviewed research demonstrates detection limits in the nanomolar range with over 30 cycles of repeatability verified. The MIP+LIG combination achieves lab-grade sensitivity in a wearable form factor.

Yes. The sensor transmits data via Bluetooth Low Energy (BLE) to the Sensora companion app on iOS and Android. The app provides real-time biomarker dashboards, trend analysis, and personalized health insights.