People used O-Mira.
Early users reported a different relationship with the phone they keep close every day.
M.I.D.™ Technology
Why we believe in M.I.D.™
O-Mira did not start from fear of technology. It started from a simple question: if the phone is now one of the objects we keep closest to the body every day, can that relationship be designed more responsibly?
Early users shared their experiences. We decided the responsible next step was not to exaggerate, but to measure.
Experience to measurement
Independent lab analysis
Passive material platform
Non-blocking by design
The starting point
First, people felt a difference.
O-Mira was built for real daily phone life: the hand, the pocket, the desk, the car, the bedroom, and the moments when the phone stays close for hours.
As early users began describing a lighter, calmer relationship with their phone, we wanted to understand what could be happening at a deeper level.
That changed the question from “Do people feel something?” to “Can we observe a measurable biological signal when the M.I.D.™ material is introduced under laboratory conditions?”
Confidence should not come from a promise. It should come from a process: listen, question, measure, verify, and keep improving.
The pathway
How we moved from experience to evidence.
The story is simple. We listened to users, then looked for measurable signals that could help explain why O-Mira exists.
O-Mira asked a better question.
Instead of turning experience into exaggerated claims, we looked for signals that could be measured.
ENERLAB analyzed it.
Independent laboratory work observed measurable changes in human blood and plasma samples exposed to the M.I.D.™ material.
CEA Nice confirmed a change.
Blood-sample tests performed at CEA Nice showed measurable changes consistent with ENERLAB’s observations.
Independent analysis
Measured by ENERLAB. Confirmed through CEA Nice testing.
For O-Mira, the role of laboratory work is not to create medical promises. It is to understand whether the M.I.D.™ material is associated with measurable biological signal changes under controlled conditions, and whether those changes can be observed again through a separate confirmation pathway.
Initial independent analysis.
Initial analyses were conducted by ENERLAB, an independent laboratory in France, using human blood and plasma samples.
The observations focused on ultra-weak biological light emission, also known as ultra-weak photon emission, a faint signal studied in biological systems.
O-Mira presents this as a measurement and confirmation pathway, not as a medical claim or institutional endorsement.
Step 1
Customer experience raised the question.
People described a more balanced relationship with their phone, so O-Mira looked for a measurable way to investigate.
Step 2
ENERLAB performed the initial analysis.
Human blood and plasma samples were studied before and after exposure to O-Mira’s M.I.D.™ material.
Step 3
CEA Nice testing confirmed a measurable change in blood samples.
Tests performed at CEA Nice showed changes consistent with ENERLAB’s observations. This confirms the presence of a biological signal change, without presenting CEA as endorsing the product or making a medical claim.
What was observed
When M.I.D.™ was introduced, measurable signals changed.
In the initial ex vivo analysis, the M.I.D.™ material used in O-Mira was associated with measurable changes in human blood and plasma samples. These are laboratory observations, not clinical outcomes.
+129%
Blood light signal
Observed ultra-weak biological light emission shift in whole blood samples after exposure to O-Mira’s M.I.D.™ material.
+145%
Plasma light signal
Observed ultra-weak biological light emission shift in plasma samples within the same research direction.
300–400 → 400–500
Spectral profile
The observed wavelength distribution shifted. In plain language: not only more signal, a different signal profile.
These observations help explain why O-Mira speaks about modulation. They do not diagnose, treat, cure, prevent disease, or guarantee an individual outcome.
ENERLAB research archive
Selected ENERLAB research reports.
Explore the first ENERLAB documents currently shared in the O-Mira research archive. These reports are presented for research context and transparency, not as medical claims.
Blood and plasma biophotonic study
Ultra-weak photon emission analysis in human blood and plasma under the O-Mira research protocol.
This report presents the core human-sample measurements behind the archive, including signal intensity changes, spectral redistribution, and time-course observations.
Open PDF
Research PDF
Phone-related signal and water analysis
Biophotonic signal measurements in a water-based phone exposure model with O-Mira present.
This supporting report examines how the measured photon signal changed in a controlled water-model setup linked to phone-related electromagnetic exposure.
Open PDF
Research PDF
Alfalfa germination biophotonic study
Comparative photon-emission tracking during alfalfa germination under the O-Mira research protocol.
This report follows germination-related photon activity over time and compares the O-Mira condition with a matched control group.
Open PDF
Research PDF
Simple definition
What M.I.D.™ means.
M.I.D.™ stands for Mode d’Information Dynamisant.
In O-Mira One, it refers to a passive material platform designed to sit between the smartphone and the body, without battery, app, Bluetooth, charging, or signal-blocking mechanism.
O-Mira does not ask you to disconnect. It is designed to change the relationship.
✓
Material, not electronics.
No battery, software, firmware, pairing, or charging cycle.
✓
Interface, not interruption.
The product adds a passive material layer to the phone you already use.
✓
Modulation, not blocking.
Calls, Wi‑Fi, Bluetooth, 5G, and mobile data are intended to continue normally.
✓
Measured, not mystical.
The O-Mira story is built around laboratory observation and ongoing validation.
Responsible language
Careful science makes the story stronger.
What we can say
- O-Mira One uses a passive M.I.D.™ material platform.
- ENERLAB performed independent laboratory analysis on human blood and plasma samples.
- Blood-sample tests performed at CEA Nice showed measurable changes consistent with ENERLAB’s observations.
- Initial observations showed measurable changes in biological light signal behavior.
What we do not claim
- Not a medical device, diagnosis, treatment, cure, or prevention product.
- Not clinical proof or a guaranteed personal outcome.
- Not a Faraday shield, EMF blocker, or phone-signal reducer.
- Not a product endorsement, medical endorsement, or certification by ENERLAB, CEA, or any third party unless separately stated in authorized documentation.
Keep the connection. Change the relationship.
O-Mira One brings M.I.D.™ technology into a discreet, French-made smartphone format: passive, non-blocking, and developed from experience toward measurable biological observation.
O-Mira Science
Measured results. Clear human meaning.
O-Mira Science connects three things: what our analyses measured, what external research says these signals can represent, and why that supports the benefit story behind O-Mira One.
+128.8% blood light signal
+145.5% plasma light signal
~63% charge shift
Spectrum + persistence changed
Light changed. Charge changed.
That is the scientific foundation behind less digital stress, more vitality, and a better mood around your phone.
The page logic
Every claim needs a bridge.
We do not throw numbers at the visitor. We explain why each number matters.
O-Mira measured it.
Initial lab analyses measured light and charge response in human blood and plasma samples.
Science gives context.
External studies help explain why biological light and electrokinetic charge are meaningful signals.
The benefit becomes clear.
The product story becomes human: calmer, lighter, less draining phone life.
Lab-observed results
Measured biophysical modulation, translated into human meaning.
Initial laboratory observations, translated into a clear proof path: what changed, why it matters scientifically, and how it supports O-Mira’s passive M.I.D.™ material platform.
01
Blood biophoton signal
+128.8%
What it means
This supports the story of more vitality and a body that feels less drained around daily phone use.
O-Mira analysis
Whole blood showed a stronger ultra-weak light signal after exposure to O-Mira’s M.I.D.™ material.
Research context
Human ultra-weak photon emission is measurable and studied as a window into biological activity.
02
Plasma biophoton signal
+145.5%
What it means
This supports a broader balance story: clearer energy, calmer interaction, better mood around your phone.
O-Mira analysis
Plasma also showed a stronger ultra-weak light signal, not only the cellular blood fraction.
Research context
Biophotonic research studies light emission as part of the body’s broader biological response.
03
Zeta-potential charge shift
~63%
What it means
This adds a second proof axis behind biological balance and less digital stress.
O-Mira analysis
Blood and plasma samples shifted toward a more negative zeta-potential profile in the lab protocol.
Research context
Zeta potential is used to describe surface charge, dispersion behavior, and colloidal stability.
04
Spectrum shift + persistence
300–400 → 400–500
What it means
This supports the idea of a more coherent response, not just a random spike.
O-Mira analysis
The light response changed in profile, not only intensity, with a shifted wavelength window and persistence.
Research context
Signal quality, organization, and duration can matter as much as signal strength.
The product bridge
Measured modulation, made usable for connected life.
These observations position O-Mira as a passive material platform with lab-observed biophysical modulation — designed to support everyday phone use without an app, battery, Bluetooth, or signal blocking.
Passive by design
No app, charging, Bluetooth, or active electronic emission.
Measured response
Initial lab observations across light and electrokinetic readouts.
Clear benefit path
Scientific signals translated into calmer, less draining phone life.
Preliminary laboratory observations. O-Mira is not a medical device and is not intended to diagnose, treat, cure, or prevent disease. Further validation is planned.
So what does the customer get?
✓
Less digital stress.
The phone keeps working, but the daily interaction is designed to feel less heavy.
✓
More vitality.
The light-response data gives a measurable foundation to the “less drained” benefit.
✓
Better mood around your phone.
The product promise becomes emotional, but it is built from measured light + charge response.
External science context
The O-Mira claim is supported through context, not empty hype.
These references explain why the measured signals can matter. They do not turn O-Mira into a medical device or medical promise.
Kobayashi et al., PLOS ONE 2009
Showed that the human body emits ultra-weak spontaneous photon emission, far below naked-eye sensitivity, with daily rhythmic variation.
Ultra-weak photon emission research
Biological light emission is studied in relation to oxidative, metabolic, and physiological activity in living systems.
Zeta-potential science
Zeta potential is a standard electrokinetic measure used to understand surface charge and dispersion behavior in fluids.
Clear boundaries
Strong claim, clean frame.
What we can say
O-Mira analyses measured changes in biological light and charge signals. Those changes support the product story: less digital stress, more vitality, and a better mood around your phone.
- Measured blood/plasma light response
- Measured zeta-potential charge response
- Passive, non-blocking M.I.D.™ material
What we do not say
This page does not claim medical proof, medical outcomes, biological correction, or signal blocking.
- Not a medical device
- Not a medical outcome promise
- Not a phone-signal blocker
References to O-Mira analyses relate to initial ex vivo laboratory observations on biological samples. Individual experiences may vary.
From science to product
Measured in the lab. Designed for daily phone life.
O-Mira One turns measured light + charge response into a passive, non-blocking product designed to help you feel better around your phone.
Biophoton Research Library
A curated scientific reading room on the light emitted by living systems.
Biophotons, also called ultra-weak photon emission or UPE, are faint light emissions studied in relation to oxidative metabolism, biological rhythms, spectral analysis, and non-invasive measurement.
Human body light
Oxidative metabolism
Spectral analysis
Cell communication
Non-invasive measurement
Ultra-weak signal, serious measurement context.
Researchers use sensitive instruments to study very faint biological light that the eye cannot see.
Start here
What are biophotons? In plain English, they are tiny light emissions from living systems. They are far below normal visibility, so they require sensitive imaging or photon-counting equipment.
Researchers study UPE because it is associated with reactive oxygen species, oxidative metabolic processes, human body rhythms, human skin oxidative stress, and spectral patterns. This library gives scientific context for O-Mira's interest in biological light signals; it does not prove O-Mira health outcomes.
Featured Evidence Themes
Four ideas that make the field worth reading.
The literature is broad, but these themes help visitors understand why ultra-weak biological light is treated as a serious research signal.
Human body light can be rhythmic.
Researchers have imaged ultra-weak light from the human body and observed daily variation in the signal.
UPE reflects oxidative processes.
Reviews describe UPE as connected to oxidative metabolic reactions and reactive oxygen species.
Spectral analysis adds meaning.
Studies do not only measure intensity; they also analyze wavelength patterns that help interpret the signal.
Communication remains a careful hypothesis.
Researchers have explored potential roles for ultra-weak emissions in cell-to-cell communication, presented as an active research question.
Curated Library
Twelve research references for the biophoton context.
Each card links to PubMed and summarizes why the paper matters in plain English. These references are educational context, not direct proof of O-Mira outcomes.
2009
Human rhythm
Imaging of ultraweak spontaneous photon emission from human body displaying diurnal rhythm.
Kobayashi M.; Kikuchi D.; Okamura H. PLoS ONE.
Why it matters: A landmark human-body study showing that the body emits ultra-weak light below naked-eye sensitivity, with rhythmic daily variation.
View PubMed
2005
Human overview
An introduction to human biophoton emission.
Van Wijk R.; Van Wijk E.P. Forsch Komplementarmed Klass Naturheilkd.
Why it matters: A useful entry point for understanding biophoton emission as ultra-weak light from living systems, including humans.
View PubMed
2021
Non-invasive tool
Human ultra-weak photon emission as non-invasive spectroscopic tool for diagnosis of internal states - A review.
Zapata F.; Pastor-Ruiz V.; Ortega-Ojeda F.; Montalvo G.; Ruiz-Zolle A.V. J Photochem Photobiol B.
Why it matters: Reviews human UPE as a developing non-invasive research field influenced by oxidative metabolic processes and internal or external factors.
View PubMed
2014
Whole-body imaging
Towards whole-body ultra-weak photon counting and imaging with a focus on human beings: a review.
Van Wijk R.; Van Wijk E.P.; van Wietmarschen H.A.; van der Greef J. J Photochem Photobiol B.
Why it matters: Frames human UPE research within systems biology and the body as a complex, dynamic biological system.
View PubMed
2016
Spectral analysis
Polychromatic spectral pattern analysis of ultra-weak photon emissions from a human body.
Kobayashi M.; Iwasa T.; Tada M. J Photochem Photobiol B.
Why it matters: Shows why wavelength patterns matter when interpreting UPE, not just the total amount of light detected.
View PubMed
2014
Mechanisms
Ultra-weak photon emission from biological samples: definition, mechanisms, properties, detection and applications.
Cifra M.; Pospisil P. J Photochem Photobiol B.
Why it matters: A broad field map covering how UPE is defined, detected, and interpreted across biological samples.
View PubMed
2014
Cell communication
New perspective in cell communication: potential role of ultra-weak photon emission.
Prasad A.; Rossi C.; Lamponi S.; Pospisil P.; Foletti A. J Photochem Photobiol B.
Why it matters: Reviews experimental results and hypotheses about whether ultra-weak emissions may contribute to cell-to-cell communication.
View PubMed
2020
Human skin
Oxidative stress in human facial skin observed by ultraweak photon emission imaging and its correlation with biophysical properties of skin.
Tsuchida K.; Kobayashi M. Scientific Reports.
Why it matters: Demonstrates that UPE imaging can reveal regional variation in human facial skin oxidative stress under controlled observation.
View PubMed
2023
Label-free imaging
Biological Auto(chemi)luminescence Imaging of Oxidative Processes in Human Skin.
Poplova M.; Prasad A.; Van Wijk E.; Pospisil P.; Cifra M. Analytical Chemistry.
Why it matters: Shows how very faint luminescence can spatially resolve oxidative processes in human skin without labels.
View PubMed
2019
Skin evaluation
Imaging of ultraweak photon emission for evaluating the oxidative stress of human skin.
Tsuchida K.; Iwasa T.; Kobayashi M. J Photochem Photobiol B.
Why it matters: Supports UPE imaging and spectroscopy as research methods for evaluating oxidation-related skin responses.
View PubMed
2010
Epidermal cells
Ultra-weak photon emission as a non-invasive tool for monitoring of oxidative processes in the epidermal cells of human skin.
Rastogi A.; Pospisil P. Skin Research and Technology.
Why it matters: Describes spontaneous UPE as a result of cellular metabolic processes and a monitoring signal for oxidative processes in skin research.
View PubMed
2010
Monitoring method
Using ultra-weak photon emission to determine the effect of oligomeric proanthocyanidins on oxidative stress of human skin.
Van Wijk E.P.; Van Wijk R.; Bosman S. J Photochem Photobiol B.
Why it matters: Presents UPE measurement as a non-invasive method for continuously monitoring oxidative stress responses in human skin research.
View PubMedCategory Map
A topic map for deeper reading.
How This Connects To O-Mira
Scientific context for a measured biophotonic response.
O-Mira's M.I.D.™ research is built around measured biophotonic response in laboratory samples. The wider literature explains why biological light is a serious research context: researchers have observed UPE in humans, studied oxidative metabolic links, analyzed spectral patterns, and reviewed potential biological roles.
This library does not prove O-Mira health outcomes. It supports a narrower, responsible bridge: O-Mira belongs in a research conversation about biological light signals, passive material interfaces, and careful measurement.
Continue from the research archive to the O-Mira experiences story.
Explore how O-Mira explains M.I.D.™ material research, everyday use, and the O-Mira One device while keeping the science boundaries clear.
