BrushO, the pioneering Solana-based oral health DePIN project and creator of the world’s first Web3 AI-Powered Mining Toothbrush, is launching a global recruitment for 100 ambassadors!

Whether you’re passionate about oral health, eager to experience the revolutionary AI and blockchain-powered oral care, or looking to earn tokens simply by brushing and sharing, we welcome you to join us! Fill out the application form for a chance to receive a free AI-Powered Mining Toothbrush valued at $199 and earn over 1000 USDT in token rewards!
Event Period: March 27th — June 26th, 10 PM (UTC)
Apply Now! Limited Slots, Don’t Miss Out!
Outstanding ambassadors will be promoted to BRUSHO PIONEERS, with doubled rewards!
Submit your application now for faster review! Early applicants enjoy quicker processing and immediate access to ambassador benefits!
Option 1: Social Media Influencers
Option 2: Video Content Creators
To be considered for a BRUSHO PIONEER role after successfully becoming an ambassador(and receiving the toothbrush), you will need to create a video showcasing your experience. Please follow these guidelines:
Video Length: 1–2 minutes
Clearly introduce yourself: “Hello, my name/social media handle is [Your Name or Handle], and I’m based in [Your Region or Country]. As a BrushO Ambassador, I’m excited to share my experience with the BrushO AI-Powered Toothbrush.”
2. Product Showcase (Design & Features)
· Present the BrushO AI-Powered Toothbrush clearly, highlighting its sleek design.
· Demonstrate the main functionalities, including turning it on, switching modes, brushing demonstration, intelligent LED indicators at the handle’s base, and brushing scores.
· Showcase interaction with the smartphone app: illustrate oral hygiene zone tracking, brushing performance scores, daily brushing reports, and token rewards in the personal dashboard.
3. Personal Experience & Feedback
· Share your authentic experience regarding the toothbrush’s cleaning effectiveness and how it has impacted your oral hygiene routine.
· Describe your impressions of the FSB features, such as idle detection and overpressure speed reduction.
· Discuss your experience with the “Brush and Earn” feature, emphasizing the motivational aspect of earning token rewards.
4. Conclusion
· Briefly summarize the key benefits and advantages of using the BrushO AI-Powered Toothbrush.
· Invite viewers to join the BrushO Ambassador Program or to try the BrushO AI-Powered Toothbrush themselves.
2. Review Phase:
3. Ambassador Phase:
4. Reward Distribution Phase:
5. Important information.
Limited to 100 slots! Apply now (BrushO AI-Powered Toothbrush Ambassador Application Form) and join the BrushO Ambassador Program! Help BrushO build a global oral health data network and improve oral health worldwide!
BrushO(https://brusho.io/) is a decentralized global oral health data platform, consisting of the BrushO AI-Powered Mining Toothbrush and the BrushO Network. BrushO empowers users to significantly improve their oral care routine while simultaneously establishing their own Web3 oral health identity. Users accumulate personal oral health data assets, contributing to a global oral health data network. This network provides a valuable data gateway for the entire oral health industry, benefiting both individuals and businesses across the sector.Through user authorization, BrushO transforms the oral health industry by restructuring production relationships while safeguarding user privacy, driving industry upgrades, and raising global oral health standards.
BrushO Website:https://brusho.io/
BrushO Telegram:https://t.me/BrushOcommunity
Apr 2
Mar 25

An in-depth exploration of the three principal hardness testing methodologies used in dental enamel research—Vickers, Knoop, and nanoindentation—and what they reveal about remineralization, erosion, and the anisotropic mechanical properties of the body's hardest tissue.

A deep dive into silver diamine fluoride—its mechanism of action combining silver's antimicrobial properties with fluoride's remineralization, FDA approval history, clinical efficacy data for arresting cavitated lesions, and practical considerations including the characteristic dark staining.

Reviews the emerging field of oral probiotics—examining specific strains (S. salivarius K12/M18, L. reuteri) and their mechanisms including competitive exclusion, bacteriocin production, and immune modulation. Evaluates clinical evidence for halitosis reduction, caries prevention, and periodontal health.

Explores oral lichen planus—a T-cell mediated chronic inflammatory condition affecting 1-2% of the population. Covers subtypes, diagnostic hallmarks, malignant transformation risk, and management from topical corticosteroids to systemic immunosuppressants.

Explores the dental implications of intermittent fasting—how prolonged fasting windows alter salivary flow, pH buffering capacity, and the oral microbiome, potentially increasing or decreasing cavity risk depending on hydration and meal composition.

A technical deep dive into the hardware powering AI toothbrushes—how 6-axis inertial measurement units achieve real-time orientation tracking, zone classification, and brushing motion analysis through sensor fusion algorithms with sub-second latency.

Examines Hunter-Schreger bands—alternating zones of decussating enamel prisms visible under polarized light. Explains how this crack-deflection architecture dramatically increases enamel fracture toughness, and its clinical relevance for understanding enamel's remarkable durability.

Explains the biological mechanisms behind age-related tooth darkening—how progressive deposition of peritubular dentin within dentinal tubules creates sclerotic dentin, altering light transmission. Covers differentiation from pathological sclerosis and implications for whitening treatment expectations.

Investigates dental pulp stones—their prevalence (up to 50% in some populations), classification, hypothesized etiologies, and clinical significance for endodontic access and treatment planning.

Modern AI toothbrushes perform complex computations — zone classification, pressure detection, stroke recognition — entirely on-device using edge computing architectures, eliminating the latency, privacy, and connectivity constraints of cloud-dependent processing. This article dissects the hardware, neural network architectures, and real-time inference pipeline that enable a toothbrush to understand brushing behavior.