What is the Arbitrum Bridge and How to Use it?

Crypto Basics

What is the Arbitrum Bridge and How to Use it?

Learn everything about Arbitrum Bridge, its benefits, top features and discover how to use it for efficient Ethereum transactions.

Sumit Meghani

7 Minutes

MIN

Index

Overview of Solana Blockchain

In the vast realm of cryptocurrencies, new developments and innovations emerge every day. One of the most recent and noteworthy advancements in the world of decentralized applications (dApps) and Ethereum scaling solutions is Arbitrum.

A central aspect of this is the Arbitrum Bridge. Let's dive deep into understanding this technological marvel.

What is Arbitrum?

Arbitrum is a Layer-2 scaling solution designed to bring scalability and reduced fees to the Ethereum network.

By offloading much of the transaction processing from Ethereum's primary chain (Layer-1), Arbitrum provides a faster and more efficient environment for dApps and smart contracts.

Why the Need for a Bridge?

Imagine a busy highway with just one lane. That's Ethereum's Layer-1, where congestion can lead to high fees and slower transactions.

Now, envision an express lane created alongside it - that's your Layer-2, where Arbitrum operates. To move from the main highway to this express lane (or vice-versa), you need a ramp. In the crypto world, that ramp is called a 'bridge'.

Understanding the Arbitrum Bridge

The Arbitrum Bridge acts as a secure channel connecting Ethereum's mainnet (Layer-1) with the Arbitrum Rollup (Layer-2). This bridge allows users to transfer assets, like ETH or ERC-20 tokens, between these layers.

Key Features of the Arbitrum Bridge

The Arbitrum Bridge is not just a bridge; it's an epitome of innovation tailored to enhance the Ethereum ecosystem. Here are its distinct features:

Scalability: One of the core objectives of Arbitrum Bridge is to handle a higher transaction volume than Ethereum's mainnet. By shifting much of the computational load off the main chain, Arbitrum facilitates quicker transaction processing, alleviating the congestion commonly found on Ethereum.

Cost Efficiency: The bridge's design focuses on minimizing gas fees. Transactions that are executed on Arbitrum are consolidated and batch-processed, drastically reducing the cumulative cost when they're finally posted to Ethereum.

Security: Backed by Ethereum's robust security model, the Arbitrum Bridge ensures that assets being transferred are always safeguarded.

Even in situations where validators might act maliciously, the bridge has mechanisms to detect and correct any irregularities, preventing asset loss.

Interoperability: The bridge is not limited to just ETH. It supports the transfer of a wide range of assets, including various ERC-20 tokens, thereby providing users with versatility in their transactions.

Decentralization: Arbitrum operates in a permissionless environment. This means that anyone can become a validator, contributing to the security and robustness of the system.

User Experience: Designed with the end-user in mind, the bridge provides a seamless and intuitive interface. This makes transferring assets between layers straightforward, even for those new to the cryptocurrency space.

How to Use the Arbitrum Bridge?

Using the Arbitrum Bridge is a straightforward process:

Step 1: Visit the official Arbitrum Bridge portal.

Step 2: Connect your Ethereum wallet. Most users opt for MetaMask, but several Ethereum-compatible wallets work.

Step 3: Select the asset you wish to transfer from the drop-down menu.

Step 4: Enter the amount you wish to move to Arbitrum.

Step 5: Confirm the transaction details and the gas fees.

Step 6: Approve and initiate the transaction. Once completed, your assets will appear in your Layer-2 Arbitrum wallet.

Step 7: When you're ready to move assets back to Ethereum's mainnet, follow the process in reverse.

Remember, while transferring from Ethereum to Arbitrum is relatively fast, moving assets from Arbitrum back to Ethereum may require a waiting period due to the underlying security mechanisms.

Why Use Arbitrum Bridge?

Cost Savings: The primary allure is the significant reduction in transaction fees, making activities like trading, yield farming, or simple transfers more economical.

Speed: Transactions on Arbitrum's Rollup are processed faster than on the congested Ethereum mainnet.

Access to New dApps: Some decentralized applications and protocols might operate exclusively on Arbitrum, requiring users to bridge assets.

Points to Remember

Gas Fees: While Arbitrum significantly reduces fees, remember there's still a cost associated with bridging assets.
Waiting Period: The potential waiting period when moving from Layer-2 to Layer-1 is a crucial aspect to consider, especially if you need your assets quickly.
Asset Safety: While the Arbitrum Bridge is designed to be secure, always ensure you're using official platforms and not falling for scams or unofficial bridges.

Best Bridges to Arbitrum

The Ethereum ecosystem's expansion to Layer-2 solutions, particularly with the introduction of Arbitrum, has led to the creation of several bridges.

These bridges facilitate the seamless movement of assets between Ethereum and Arbitrum. Here are the few best bridges that have been widely recognized for their functionality, security, and user experience:

Official Arbitrum Bridge: Developed and maintained by Offchain Labs, the team behind Arbitrum, this bridge is often the first choice for many. Its direct integration with Arbitrum ensures optimal security, a user-friendly interface, and comprehensive support for a range of Ethereum-based tokens. Continuous updates and development support make it a reliable choice.

Hop Protocol: Hop stands out for its focus on interoperability. It doesn’t just bridge assets to Arbitrum but also other Layer-2 solutions like zkSync and Optimism. Its unique feature is the automatic swapping of tokens across rollups, making transfers efficient and ensuring liquidity.

zBridge: Powered by zkSync, zBridge is another contender in the Arbitrum bridging landscape. It specializes in low-cost, swift transfers between Ethereum and Arbitrum. The bridge’s emphasis on user privacy, coupled with its cost-effectiveness, is drawing a growing user base.

cBridge: Designed and pioneered by the renowned Celer Network, cBridge stands as an advanced gateway for the efficient transfer of assets, encompassing both ETH and a vast array of ERC-20 tokens, between Ethereum and Arbitrum.

Harnessing the cutting-edge technology of the Celer Network, cBridge prioritizes not just rapidity but also uncompromised security in its transfers, all the while upholding a staunch commitment to decentralization.

When selecting a bridge to Arbitrum, it's essential to weigh the pros and cons of each option. While all the bridges listed above offer unique features and benefits, users should consider factors like security, fees, ease of use, and compatibility with their specific needs to make an informed decision.

Frequently Asked Questions

Q1. What differentiates Arbitrum from other Ethereum Layer-2 solutions?

Arbitrum stands out due to its unique combination of optimistic rollups, scalability, and close integration with Ethereum's security model. It offers improved transaction speeds and reduced fees, all while preserving the robustness associated with Ethereum.

Q2. Why is bridging necessary between Ethereum and Arbitrum?

Bridging acts as a connector to transfer assets between Ethereum's mainnet (Layer-1) and Arbitrum (Layer-2). Given that they operate on different layers, a bridge provides a secure and efficient pathway for this movement.

Q3. Are there fees associated with using bridges to Arbitrum?

Yes, there are fees involved, primarily to compensate for the computational and transactional efforts. However, these fees are generally lower than standard Ethereum gas fees, especially during network congestion.

Q4. Can assets be moved back from Arbitrum to Ethereum?

Absolutely! Though it's worth noting that due to the security mechanisms in place, moving assets from Arbitrum back to Ethereum may come with a waiting period.

Q5. How does Arbitrum ensure the security of assets during transfers?

Arbitrum operates closely with Ethereum's primary security framework. Even in scenarios where potential malicious activities occur, Arbitrum has built-in measures to detect and rectify any discrepancies, ensuring assets remain safeguarded.

Q6. What's the role of validators in the Arbitrum network?

Validators help in processing transactions, submitting proofs to Ethereum, and maintaining the overall security and authenticity of the network. Given its decentralized nature, anyone can become a validator in the Arbitrum ecosystem.

Q7. Is the Official Arbitrum Bridge the only way to transfer assets to Arbitrum?

While the Official Arbitrum Bridge is a popular and trusted choice, several other bridges, like cBridge, Connect, and Hop Protocol, have emerged, offering different features and benefits for users.

Q8. What happens if there's a dispute in a transaction on Arbitrum?

Arbitrum's design includes a challenge period where disputes can be raised. If an invalid or malicious transaction is detected, it can be challenged, and if proven false, it will be rolled back, ensuring the integrity of the system.

Conclusion

The Arbitrum Bridge stands as a testament to the ongoing innovation in the cryptocurrency space. As Ethereum continues to face scalability challenges, solutions like Arbitrum offer a promising avenue for users seeking speed, cost-effectiveness, and a seamless experience.

For those eager to maximize the potential of their Ethereum-based activities, understanding and utilizing the Arbitrum Bridge is invaluable. As always, stay informed, stay safe, and let technology pave the way for smarter crypto choices.

Disclaimer

The information provided on this website does not constitute investment advice, financial advice, trading advice, or any other sort of advice and you should not treat any of the website's content as such.

Token Metrics does not recommend that any cryptocurrency should be bought, sold, or held by you. Do conduct your own due diligence and consult your financial advisor before making any investment decisions.

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Practical Guide to Fabric API and Integrations

Token Metrics Team

MIN

Fabric API is a cornerstone for developers building permissioned blockchain solutions with Hyperledger Fabric. This article explains what Fabric APIs are, how they fit into Fabric's architecture, practical integration patterns, and how to evaluate tooling when you need reliable programmatic access to Fabric networks.

What is the Fabric API and why it matters

The term "Fabric API" broadly refers to the programmatic interfaces and SDKs that allow applications to interact with a Hyperledger Fabric network. These interfaces expose capabilities such as submitting transactions, querying ledger state, managing identities via Fabric CA, and deploying or invoking chaincode (smart contracts). For enterprise use cases—supply chain auditing, tokenized assets, or confidential data flows—the Fabric API is the gateway between business logic and the distributed ledger.

Key characteristics of Fabric APIs include:

Permissioned access: operations are gated by identity and certificate-based authentication.
Support for multiple languages: SDKs and chaincode runtimes enable JavaScript/TypeScript, Go, Java, and more.
Gateway patterns: modern Fabric versions favor the Gateway API for simplified connection management and transaction lifecycle handling.

Core components and SDKs to know

Interacting with Fabric typically involves several layers. Understanding these helps you choose the right API surface for your application:

Fabric Gateway API: A high-level client API that simplifies endorsement, submission, and event handling. It abstracts peers, orderers, and channel configuration so developers can focus on transactions.
Fabric SDKs: Language-specific SDKs (Node.js, Java, Go) provide programmatic access where fine-grained control is required—example: advanced endorsement policies, custom discovery, or private data collection management.
Chaincode APIs: Chaincode runtimes expose an API surface for smart contract logic to access ledger state, emit events, and perform composite key queries.
Fabric CA API: Certificate Authority endpoints for identity lifecycle operations—enrollment, revocation, and affiliation management—accessible via REST or SDK wrappers.
REST/Proxy layers: Many deployments add a REST façade or API gateway in front of Fabric to translate HTTP requests to SDK calls, add RBAC, rate limiting, and telemetry.

Design patterns and integration best practices

Choosing how to surface Fabric functionality depends on risk, latency, and operational model. Common patterns include:

Direct SDK clients: Suitable for backend services with secure key management that need direct ledger access and deterministic transaction flows.
Gateway + Microservice: Use the Fabric Gateway for transaction orchestration behind microservices that encapsulate business logic and validation.
REST API gateway: A REST façade simplifies integration with web and mobile apps. Add authorization checks, input validation, and transformation layers to prevent malformed transactions reaching the ledger.
Event-driven integrations: Subscribe to Fabric events (block/chaincode events) to trigger downstream processes or ML pipelines for analytics and monitoring.

Cross-cutting concerns to design for:

Identity management: Use Fabric CA and hardware-backed keys where possible; separate admin and application identities.
Determinism and validation: Ensure chaincode logic is deterministic and validated across peers to avoid endorsement failures.
Observability: Instrument SDK calls, latency, retry behavior, and endorsement responses to troubleshoot production issues.

Practical steps for building, testing, and securing Fabric API integrations

Follow a structured approach when integrating with Fabric networks:

Prototype locally: Use test networks (Fabric samples or Docker-based local networks) to validate transaction flows and endorsement policies before deploying to staging.
Choose the right API layer: For rapid development, the Gateway API with the Node SDK reduces boilerplate. For advanced control, use language-specific SDKs and custom connection profiles.
Implement a façade for public clients: Never expose Fabric SDK credentials to browsers or untrusted environments—place a server-side API between clients and Fabric.
Automate CI/CD: Include unit tests for chaincode logic, integration tests against ephemeral networks, and deployment pipelines for chaincode packaging and approvals.
Security posture: Enforce TLS, rotate certificates, isolate admin operations, and employ least-privilege identities for applications.

Testing tips: use channel-level mock data, replay recorded endorsement responses for deterministic unit tests, and simulate peer failures to validate client retry logic.

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FAQ: What is the Fabric API?

The Fabric API comprises SDKs, the Gateway API, chaincode interfaces, and CA endpoints that let applications manage identities, submit transactions, and query ledger state on Hyperledger Fabric networks.

FAQ: How do I choose between Gateway and direct SDKs?

Use the Gateway API for simpler, high-level transaction workflows and reduced configuration. Choose direct SDKs when you need low-level control over discovery, endorsement policies, or custom peer selection logic.

FAQ: Can I expose Fabric functionality via REST?

Yes. Implement a secure REST proxy or API gateway to translate HTTP calls to Fabric SDK operations. This adds flexibility for web/mobile clients but requires careful identity and input validation.

FAQ: What are best practices for identity and key management?

Use Fabric CA for certificate issuance, adopt hardware-backed key stores where possible, separate admin and app roles, and rotate/revoke certificates according to policy. Avoid embedding private keys in client-side code.

FAQ: How should I monitor Fabric API usage and performance?

Instrument SDK calls, capture latency and endorsement statistics, log chaincode events, and integrate with observability stacks (Prometheus/Grafana). Monitor peer health and orderer topology to correlate API issues with network state.

FAQ: What common pitfalls should I watch for?

Common issues include endorsement mismatches due to non-deterministic chaincode, exposing credentials to clients, insufficient testing of policy changes, and lacking observability for transaction failures.

Disclaimer: This article is educational and technical in nature. It does not provide financial, legal, or regulatory advice. Implementations should be validated against your organization's compliance and security requirements.

Research

REST API Explained: Design, Security & Best Practices

Token Metrics Team

MIN

REST APIs are the connective tissue of modern web and mobile applications. Whether you're integrating services, building microservices, or exposing data for AI agents, a clear grasp of REST API principles helps you design interfaces that are maintainable, performant, and secure. This guide walks through the core concepts, practical design patterns, authentication and security considerations, and tooling that make REST APIs reliable in production.

What is a REST API and core principles

REST (Representational State Transfer) is an architectural style that uses standard HTTP verbs and status codes to manipulate resources. Key tenets include:

Statelessness: Each request contains all information needed to process it; servers don’t maintain client session state.
Resources and representations: Resources are identified by URIs; responses return representations (JSON, XML) describing resource state.
Uniform interface: Use predictable HTTP methods (GET, POST, PUT, DELETE, PATCH) and status codes for consistent client-server interaction.
Layered system: Clients need not be aware of whether they communicate with the origin server or an intermediary.

Understanding these principles helps when choosing between REST, GraphQL, or RPC for a given use case. REST is well-suited for CRUD-style operations, caching, and wide compatibility with HTTP tooling.

Design patterns: resources, versioning, and idempotency

Good API design starts with modeling resources and their relationships. Practical patterns include:

Resource naming: Use plural nouns and hierarchical paths (e.g., /users/{userId}/orders).
Versioning: Use URL or header-based versioning (e.g., /v1/ or Accept header) to avoid breaking clients.
Idempotency: Ensure methods like PUT and DELETE can be retried safely; supply idempotency keys for POST when necessary.
Pagination and filtering: Provide cursor-based or offset-based pagination, with clear metadata for total counts and next cursors.

Design with backward compatibility in mind: deprecate endpoints with clear timelines, and prefer additive changes over breaking ones.

Authentication, authorization, and security considerations

Security is non-negotiable. Common, interoperable mechanisms include:

API keys: Simple and useful for identifying applications, but pair with TLS and usage restrictions.
OAuth 2.0: Industry-standard for delegated authorization in user-centric flows; combine with short-lived tokens and refresh tokens.
JWTs: JSON Web Tokens are compact bearer tokens useful for stateless auth; validate signatures and expiration, and avoid storing sensitive data in payloads.
Transport security: Enforce TLS (HTTPS) everywhere and use HSTS policies; mitigate mixed-content risks.
Rate limiting & throttling: Protect backends from abuse and accidental spikes; return clear headers that expose remaining quota and reset times.

Also consider CORS policies, input validation, and strict output encoding to reduce injection risks. Implement principle of least privilege for every endpoint and role.

Performance, observability, and tooling

Operational maturity requires monitoring and testing across the lifecycle. Focus on these areas:

Caching: Use HTTP cache headers (Cache-Control, ETag) and CDN fronting for public resources to reduce latency and load.
Instrumentation: Emit structured logs, request traces (OpenTelemetry), and metrics (latency, error rate, throughput) to diagnose issues quickly.
API specifications: Define schemas with OpenAPI/Swagger to enable client generation, validation, and interactive docs.
Testing: Automate contract tests, integration tests, and fuzzing for edge cases; run load tests to establish scaling limits.
Developer experience: Provide SDKs, clear examples, and consistent error messages to accelerate integration and reduce support overhead.

Tooling choices—Postman, Insomnia, Swagger UI, or automated CI checks—help maintain quality as the API evolves. For AI-driven integrations, exposing well-documented JSON schemas and stable endpoints is critical.

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What is REST and when should I choose it?

REST is ideal for resource-oriented services where standard HTTP semantics are beneficial. Choose REST when caching, simplicity, wide client compatibility, and predictable CRUD semantics are priorities. For highly dynamic queries, consider GraphQL as a complement rather than a replacement.

How do I manage breaking changes?

Version endpoints, use feature flags, and publish changelogs with migration guides. Prefer additive changes (new fields, new endpoints) and give clients time to migrate before removing legacy behavior.

What authentication method should I implement?

Match the method to the use case: API keys for server-to-server integrations, OAuth 2.0 for delegated user access, and JWTs for stateless session claims. Always layer these with TLS and short token lifetimes.

How should I handle rate limits and abuse?

Enforce per-key and per-IP limits, surface quota headers, and provide graceful 429 responses with a Retry-After header. Use adaptive throttling to protect critical downstream systems.

Which tools help maintain a healthy API lifecycle?

Adopt OpenAPI for specs, use Postman or Swagger UI for exploratory testing, integrate contract tests into CI, and deploy observability stacks (Prometheus, Grafana, OpenTelemetry) to monitor behavior in production.

Disclaimer

This article is for educational and technical guidance only. It does not constitute legal, security, or operational advice. Evaluate risks and compliance requirements against your own environment before implementing changes.

Research

What Is an API? Practical Guide for Developers

Token Metrics Team

MIN

APIs (application programming interfaces) are the connective tissue of modern software. Whether you use mobile apps, web services, or AI agents, APIs let systems exchange data and trigger actions without sharing inner code. This guide explains what an API is, how APIs work, why they matter in crypto and AI, and practical steps to evaluate and integrate them.

What is an API? — definition and types

An API is a set of rules and definitions that allow one software program to interact with another. At its core, an API defines endpoints (URLs or RPC methods), expected inputs, responses, and error formats. APIs abstract complexity: a developer can request a price, submit a transaction, or call a machine-learning model without needing the provider’s internal implementation details.

Common API types include:

REST APIs — Use HTTP verbs (GET, POST, PUT, DELETE) and JSON payloads. Widely used for web services and easy to integrate.
GraphQL — Lets clients request exactly the fields they need in a single query, reducing over- and under-fetching.
WebSockets — Support bi-directional, low-latency streams for live updates (e.g., market feeds, chat).
gRPC / RPC — High-performance binary protocols suitable for microservices or low-latency needs.

How APIs work: protocols, endpoints, and security

APIs expose functionality through well-documented endpoints. Each endpoint accepts parameters and returns structured responses, typically JSON or protocol buffers. Key concepts include authentication, rate limiting, and versioning:

Authentication — API keys, OAuth tokens, or JWTs verify identity and access rights.
Rate limiting — Protects providers from abuse and ensures fair usage by capping requests per time window.
Versioning — Maintains backward compatibility as APIs evolve; semantic versioning or URL-based versions are common.

Security best practices involve TLS/HTTPS, least-privilege API keys, signing of critical requests, input validation to avoid injection attacks, and monitoring logs for unusual patterns. For sensitive operations (transactions, private data), prefer APIs that support granular permissions and replay protection.

APIs in crypto and AI: practical use cases

APIs power many crypto and AI workflows. In crypto, APIs provide price feeds, historical market data, exchange order placement, blockchain node interactions, and on-chain analytics. For AI, APIs expose model inference, embeddings, and data pipelines that let applications integrate intelligent features without hosting models locally.

Use-case examples:

Market data — REST or WebSocket streams deliver price ticks, order books, and trade history to analytics platforms.
On-chain access — Node APIs or indexing services offer transaction history, wallet balances, and smart-contract state.
AI inference — Model APIs return predictions, classifications, or embeddings for downstream workflows.
Automated agents — Combining market and on-chain APIs with model outputs enables monitoring agents and automated processes (with appropriate safeguards).

AI-driven research platforms and analytics providers can speed hypothesis testing by combining disparate APIs into unified datasets. For example, Token Metrics and similar services merge price, on-chain, and sentiment signals into actionable datasets for research workflows.

How to evaluate and integrate an API: checklist and best practices

Selecting and integrating an API involves technical and operational checks. Use this checklist to assess suitability:

Documentation quality — Clear examples, response schemas, error codes, and SDKs reduce integration risk.
Latency and throughput — Measure median and tail latency, and confirm rate limits align with your use case.
Reliability SLAs — Uptime guarantees, status pages, and incident history indicate operational maturity.
Data accuracy and provenance — Understand how data is sourced, normalized, and refreshed; for crypto, on-chain vs aggregated off-chain differences matter.
Security and permissions — Check auth mechanisms, key rotation policies, and encryption standards.
Cost model — Consider per-request fees, bandwidth, and tiering; estimate costs for production scale.
SDKs and community — Official SDKs, sample apps, and active developer communities speed troubleshooting.

Integration tips:

Prototype quickly with sandbox keys to validate data formats and rate limits.
Build a retry/backoff strategy for transient errors and monitor failed requests.
Cache non-sensitive responses where appropriate to reduce cost and latency.
Isolate third-party calls behind adapters in your codebase to simplify future provider swaps.

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Common implementation patterns

Several integration patterns appear repeatedly in production systems:

Aggregator pattern — Combine multiple providers to improve coverage and redundancy for market data or on-chain queries.
Event-driven — Use WebSockets or message queues to process streams and trigger downstream workflows asynchronously.
Batch processing — Fetch historical snapshots via bulk endpoints for backtesting and model training.

Choosing a pattern depends on timeliness, cost, and complexity. For exploratory work, start with REST endpoints and move to streaming once latency demands increase.

FAQ: What is an API?

Q: What’s the difference between an API and a web service?

A web service is a specific type of API that uses network protocols (often HTTP) to provide interoperable machine-to-machine interaction. All web services are APIs, but not all APIs are web services (some are in-process libraries or platform-specific interfaces).

Q: What is an endpoint in an API?

An endpoint is a specific URL or method that accepts requests and returns data or performs actions. Endpoints are typically documented with required parameters, response formats, and error codes.

Q: How do I authenticate with an API?

Common methods include API keys, OAuth 2.0 flows for delegated access, and JSON Web Tokens (JWTs). Choose mechanisms that match your security needs and rotate credentials regularly.

Q: When should I use WebSockets vs REST?

Use REST for request/response interactions and batch queries. Use WebSockets (or similar streaming protocols) when you need continuous, low-latency updates such as live market data or notifications.

Q: How can I test and sandbox an API safely?

Use provider sandbox environments or testnet endpoints for blockchain calls. Mock external APIs during unit testing and run integration tests against staging keys to validate behavior without impacting production systems.

Q: Are there standards for API design?

Yes. RESTful conventions, OpenAPI/Swagger documentation, and GraphQL schemas are common standards that improve discoverability and ease client generation. Following consistent naming, pagination, and error practices reduces onboarding friction.

Disclaimer: This article is for educational and informational purposes only. It explains technical concepts, implementation patterns, and evaluation criteria for APIs. It is not investment, legal, or security advice. Conduct your own due diligence before integrating third-party services.

Token Metrics Media LLC is a regular publication of information, analysis, and commentary focused especially on blockchain technology and business, cryptocurrency, blockchain-based tokens, market trends, and trading strategies.

Token Metrics Media LLC does not provide individually tailored investment advice and does not take a subscriber’s or anyone’s personal circumstances into consideration when discussing investments; nor is Token Metrics Advisers LLC registered as an investment adviser or broker-dealer in any jurisdiction.

Information contained herein is not an offer or solicitation to buy, hold, or sell any security. The Token Metrics team has advised and invested in many blockchain companies. A complete list of their advisory roles and current holdings can be viewed here: https://tokenmetrics.com/disclosures.html/

Token Metrics Media LLC relies on information from various sources believed to be reliable, including clients and third parties, but cannot guarantee the accuracy and completeness of that information. Additionally, Token Metrics Media LLC does not provide tax advice, and investors are encouraged to consult with their personal tax advisors.

All investing involves risk, including the possible loss of money you invest, and past performance does not guarantee future performance. Ratings and price predictions are provided for informational and illustrative purposes, and may not reflect actual future performance.

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