MESCOPE

SAV- Super Auto Vaccine
SAT- Super Auto Test
SAS- Super Auto Supplement

BIOBOT

MeScope-HAI
Individual-Microfluids
Human-Artificial-Intelligence
Microfluid-Analysis-Microscopy
Microfluid-Analysis-Spectroscopy
Cell-Phone-Video-Camera-Attachment
Skin-Extract-Blood-Sweat-Saliva-Urine
Micro-Fluids-Reacting-Analyzing-Strips
Micro-Nano-Testing-Individual-Laboratory
Human-Artificial-Intelligence-Image-Analysis
Image-Enhancement-Computerized-Analysis
Medical-Micro-Nano-Spectro-Scope-Analysis
Smart-Phone-Micro-Nano-Scope-Lens-Sensors

CBM
Cell Bank Medculture

MeScope-HAI
Testing-Information
Natural-Individual-Service
Micro-Intra-Venal-SLR-ALR
Systemic-Life-Regenetration
Nano-Intra-Skin-SAV-SAS-SAT
Accelerated-Local-Regeneration
Antigen-Antibody-Patch-Pill-Spray
Human-mRNA-Exosome-Supplement
Super-Auto-Test-Vaccine-Supplement
Anti-Virus-Bacteria-Cancer-Aging-Toxin
Disease-Immunity-Substance-Abuse-Test
Adverse-Drug-Reaction-Placebo-Drug-Reaction

MeScope is an individual Human Artificial Intelligence Microfluid Analysis Microscopy and Spectroscopy system. Smart cellphone accessories micro-nano-spectro-scope lens-sensors that turn it into a micro-nano testing individual home-office laboratory. Smart cell phone video camera attachment for skin extract, blood, sweat, saliva, urine, micro-fluids reacting analyzing strips. A medical micro-nano-spectro-scope analyzer with Human Artificial Intelligence image enhancement computerized analysis.

Smart-phone micro/spectroscopy detection feasibility depends of molecule/cell type/size, AI Microscopy for red/white blood cells, AI Spectroscopy to detect/quantify molecules, protein aggregates, antibodies, aminoacids, glucose, cholesterol, vitamins and hormones. Miniaturized advanced optics portable Surface-Enhanced Raman Spectroscopy Sensors needed for analyzing molecular composition via Raman (RM), Infra-Red (IR), Ultra-Violet (UV) or Visible (VIS) light/photons.

AI models, like transformer neural networks, can interpret spectral fingerprints to identify protein compositions and hormonal profiles as for aging reversal age-profile dosages. Spectroscopy probes molecular vibrations by different mechanisms: Raman by scattering, IR by absorption, UV-Vis by electronic transitions, providing information about the electronic structure of molecules.
Each technique utilizes different regions of the electromagnetic spectrum to probe different aspects of molecular structure and behavior.

Raman Spectroscopy measures inelastic scattering of light when interacting with molecule. Most photons are scattered elastically at same wavelength, but small fraction of photons are scattered at different wavelength: longer wavelength/lower frequency or shorter wavelength/higher frequency. Raman spectrum shows molecule vibrational modes by intensity of scattered light at different frequencies.

Infrared Spectroscopy measures absorption of infrared light by molecules. Molecules absorb IR light at specific frequencies that correspond to vibrational modes of molecules. IR Spectrum analyses absorption to identify the types of bonds and functional groups present in molecules.

Ultraviolet-Visible Spectroscopy measures absorption of ultraviolet and visible light by molecules to study electronic transitions. It identifies/quantifies compounds based on their unique absorption patterns in UV-Vis region, useful for studying conjugated systems and aromatic compounds.

HAI Laser Spectroscopy

Human Artificial Intelligence Hybrid concept combining Laser Capture Microdissection (LCM) with miniaturized spectroscopy for isolating and analyzing molecules.

Laser Microdissection Unit isolates target cells or tissue regions.

Microfluidic Transfer System moves dissected samples to analysis chamber.

Miniaturized Spectroscopy Sensor analyzes molecular composition (Raman, IR and/or UV-Vis).

Fluorescence Tagging optionally enhances visibility of specific macromolecules.

AI-Driven Imaging Software guides laser targeting and interprets spectral data.

Optical Tweezers with Spectroscopy integrates optical tweezers, laser beams that trap and manipulate individual molecules, with single-molecule spectroscopy. That opens doors to studying protein folding, enzyme activity, or DNA interactions in real time.

HAI Vein Sense Non-Invase Spectroscopy

Human Artificial Intelligence Non-Invasive Blood Analysis Spectroscopy with technology that work through skin and veins.

Near-Infrared (NIR) Spectroscopy penetrates skin and tissue to reach blood vessels. Used to measure hemoglobin, oxygen saturation and glucose. Combined with Photoplethysmography (PPG) for pulse and flow data. Already used in devices like pulse oximeters and some smartwatches.

Raman Spectroscopy detects molecular vibrations to identify proteins, lipids and blood cells. Can characterize whole blood and its components like hemoglobin, albumin and glucose. Works best with enhanced signal technology as surface-enhanced Raman.

Photoacoustic Spectroscopy uses pulsed laser light to generate sound waves from blood molecules. Can detect biochemical parameters like uric acid, albumin and creatinine and deep-tissue analysis without ionizing radiation.

Skin tone, hydration and tissue thickness limitation affect signal quality. Cortisol and hormones are harder to detect optically requiring biochemical tagging or saliva/urine samples. Smartphone system must have enhanced optics or external modules.

Wearable spectrometers with NIR and Raman capabilities can have AI-enhanced signal processing to improve accuracy through skin and
hybrid devices combining spectroscopy with microfluidic sampling for real-time blood analysis.

Flexible wristband or adhesive skin patch placed over the radial vein of wrist or median cubital vein or inner elbow. Biocompatible silicone material with embedded optical sensors, minimal LED strip or bluetooth sync display for smartphone app.

NIR Spectroscopy penetrates skin to detect hemoglobin, oxygen and glucose. Raman Spectroscopy identifies molecular vibrations of proteins and lipids. Photoacoustic Sensors
converts light pulses into sound waves for deep-tissue analysis. AI signal processor filters noise, interprets spectra and predicts trends. Wireless sync sends data to smartphone or cloud dashboard.

Monitor Hemoglobin/Oxygen to track anemia, oxygenation and fitness. Glucose for non-invasive
diabetic monitoring. Lactate for exercise recovery and metabolic stress. Uric Acid for gout risk and kidney function. Albumin for liver health and hydration status.

Real-Time Alerts for glucose rising recommending exercizing. Trend Analysis with weekly health graphs and predictions. Skin-Adaptive Calibration adjusts for tone, hydration and thickness. Sleep and Stress Integration combines biochemical data with heart rate and movement.

Wearable device band or patch placed over vein-rich area. Passive monitoring of light pulses scanning blood molecules every few minutes.
Data sync app displays trends, alerts and health insights. Cloud backup optional encrypted storage for medical sharing.