What is Bitcoin Mining and Is it Profitable?

Crypto Basics

What is Bitcoin Mining and Is it Profitable?

Learn everything about Bitcoin mining in this guide. Understand the process, potential earnings, and key factors that may impact profitability.

S. Vishwa

9 Minutes

Cryptocurrency mining has gained popularity as a means of earning passive income and supporting decentralized networks that power digital assets. Bitcoin, in particular, has garnered significant attention for its impact on the overall crypto market.

This comprehensive guide will assist you in evaluating the profitability of Bitcoin mining in 2024 and getting started on your mining endeavor. It will furnish you with all the necessary information to make an informed decision and embark on your mining journey.

Introduction to Bitcoin Mining

What is Bitcoin Mining?

Bitcoin mining can be compared to extracting precious metals from the earth. It is the mechanism through which new bitcoins are minted, and transactions are verified on the blockchain.

As the Bitcoin white paper describes, mining involves CPU time and electricity to add new coins to circulation.

How Does Bitcoin Mining Work?

Specialized computers, known as miners, perform Bitcoin mining, which competes to solve complex mathematical problems. These problems are designed to be computationally complex and require significant computational power to solve.

Miners race against each other to find a solution to the problem, and the first miner to successfully solve it earns the right to add the next block of transactions to the blockchain and is rewarded with newly minted bitcoins.

The Role of Proof-of-Work

The mining process in Bitcoin is based on a concept called Proof-of-Work (PoW). Miners must prove that they have performed a certain amount of computational work in order to have a chance at winning the block reward.

This work is achieved by repeatedly hashing the block's data until a specific pattern or target hash, is found. The target hash is a value set by the network and determines the difficulty of the mining process.

The Importance of Confirmation

Once a miner solves a block, it is added to the blockchain and becomes a confirmed transaction. Confirmation is critical to Bitcoin mining as it ensures that transactions are valid and irreversible.

The more confirmations a transaction has, the more secure it is considered to be. Generally, it is recommended to wait for multiple confirmations before considering a transaction final.

The Process of Bitcoin Mining

Hashing and Target Hash - The hashing process is at the core of Bitcoin mining. Hashing involves taking input data and running it through a cryptographic hash function to produce a fixed-length output.

In the case of Bitcoin mining, the input data includes the transactions to be verified and other information, such as the previous block's hash.

Miners repeatedly hash this data, changing a small portion of it known as the nonce, until a hash is generated that meets the target hash criteria set by the network.

Mining Difficulty - The mining difficulty measures how difficult it is to find a hash that meets the target criteria. The difficulty is adjusted approximately every two weeks to ensure that blocks are mined at a consistent rate.

If the network's total computational power increases, the difficulty will be increased to maintain the average block time of approximately 10 minutes.

Conversely, if the computational power decreases, the difficulty will be reduced to keep the block time consistent.

Rewards for Miners - Miners are incentivized to participate in the mining process through the rewards they receive. When a miner successfully solves a block, they are rewarded with a predetermined amount of newly minted bitcoins, known as the block reward.

Additionally, miners receive transaction fees associated with the transactions included in the block. The block reward is halved approximately every four years in an event known as the Bitcoin halving.

This event is designed to control the rate at which new bitcoins are introduced into circulation and ensure the scarcity of the cryptocurrency.

Equipment and Costs

Mining Hardware - Bitcoin mining requires specialized hardware known as Application-Specific Integrated Circuits (ASICs). These devices are specifically designed to perform the hashing calculations required for mining and are much more efficient than general-purpose computers.

ASICs come in various forms, ranging from small USB devices to large mining rigs. The cost of mining hardware can vary significantly depending on the type and performance of the ASIC.

Electricity Consumption - One of the significant costs associated with Bitcoin mining is electricity consumption. The computational power required for mining is energy-intensive and can result in high electricity bills.

The electricity consumption of mining operations has drawn criticism due to its environmental impact. To maximize profitability, miners must consider the cost of electricity and the energy efficiency of their mining equipment to maximize profitability.

Other Costs - In addition to electricity costs, miners may also incur expenses related to cooling and maintenance. Mining equipment generates significant heat and requires adequate cooling to ensure optimal performance.

Cooling systems can add to the overall cost of mining operations. Furthermore, regular maintenance and replacement of mining hardware may be necessary to keep up with the rapidly evolving technology.

Also Read - Best Bitcoin Mining Software

Profitability of Bitcoin Mining

Factors Affecting Profitability - The profitability of Bitcoin mining depends on several factors, including the price of Bitcoin, mining difficulty, electricity costs, and the efficiency of mining equipment.

The price of Bitcoin is highly volatile and can significantly impact mining profitability. When the price is high, mining can be more profitable, but when it is low, mining may not be economically viable for some miners.

Calculating Mining Profitability - To determine whether Bitcoin mining is profitable, miners need to consider the costs associated with mining, including equipment expenses, electricity costs, and any other overheads.

They also need to estimate the potential rewards from mining, considering the current block reward, transaction fees, and the likelihood of successfully mining a block. Various online calculators are available to help miners estimate their potential profits based on these factors.

Is Bitcoin Mining Profitable?

The profitability of Bitcoin mining varies depending on individual circumstances and market conditions. While some miners have achieved significant profits, others have struggled to break even or generate positive returns.

The competitiveness of the mining industry and the constantly evolving technology make it challenging for individual miners to remain profitable. The high upfront costs of mining equipment and electricity expenses can also affect potential profits.

Also Read - 8 Best and Profitable Crypto to Mine

Environmental Impact

Energy Consumption - Bitcoin mining has attracted criticism due to its high energy consumption. The computational power required for mining consumes significant electricity, contributing to carbon emissions and environmental concerns.

The Bitcoin network's energy consumption has been compared to that of entire countries. As the popularity of Bitcoin grows, there is a need for more sustainable and energy-efficient mining practices to mitigate its environmental impact.

Renewable Energy and Sustainability - Efforts are underway to promote the use of renewable energy sources for Bitcoin mining. Some mining operations are powered by renewable energy, such as solar or wind, to reduce their carbon footprint.

Adopting sustainable mining practices is crucial to address the environmental concerns of Bitcoin mining. Additionally, ongoing research and development in energy-efficient mining hardware are expected to contribute to a more sustainable future for Bitcoin mining.

Getting Started with Bitcoin Mining

1. Choosing a Mining Pool

Joining a mining pool can increase individual miners' chances of earning rewards. Mining pools allow miners to combine their computational power and work together to mine blocks more efficiently.

When a block is successfully mined, the rewards are distributed among the pool members based on their contribution. Joining a mining pool can provide miners with a more consistent income stream, especially for those with limited computational resources.

2. Setting Up Mining Hardware

Setting up mining hardware requires careful consideration of factors such as cooling, electricity supply, and network connectivity. Miners must ensure their hardware is properly configured and optimized for mining.

Adequate cooling is essential to prevent overheating and ensure optimal performance. Additionally, miners should have a stable and reliable internet connection to stay connected to the Bitcoin network.

3. Mining Software

Mining software is essential for managing and controlling the mining process. It allows miners to connect their hardware to the mining pool and monitor their mining activities.

Several mining software options are available, each with its features and compatibility with different mining hardware. Miners should choose software that is compatible with their hardware and offers the necessary features for efficient mining.

Risks and Challenges

Market Volatility - The volatile nature of Bitcoin's price poses a significant risk to mining profitability. The price of Bitcoin can fluctuate dramatically within a short period, impacting the potential rewards for miners.

Sharp price declines can lead to reduced profitability or even losses for miners. Miners should be prepared for the inherent market risks associated with Bitcoin mining and consider strategies to mitigate these risks.

Regulatory Environment - The regulatory environment surrounding Bitcoin mining varies across jurisdictions. Some countries have embraced cryptocurrencies and have favorable regulations for mining operations, while others have imposed strict regulations or outright bans.

Miners should stay informed about their respective locations' legal and regulatory developments to ensure compliance and mitigate regulatory risks.

Competition and Centralization - Bitcoin mining has become increasingly competitive, with large-scale mining operations dominating the industry. These operations have access to significant computational power and resources, which can make it difficult for individual miners to compete.

The concentration of mining power in the hands of a few entities raises concerns about centralization and the potential for network security vulnerabilities. Miners should be aware of the competitive landscape and consider the implications of centralization on the Bitcoin network.

Conclusion

Bitcoin mining plays a crucial role in the functioning and security of the Bitcoin network. It involves solving complex mathematical problems to validate transactions and mint new bitcoins.

While mining can be profitable under the right circumstances, it is a highly competitive and resource-intensive process. Miners must carefully consider the costs and risks of mining before getting involved.

The environmental impact of mining also raises important sustainability concerns that need to be addressed through the adoption of renewable energy sources and energy-efficient mining practices.

As the cryptocurrency landscape continues to evolve, miners must stay informed and adapt to changing market conditions to maximize their chances of success in the mining industry.

Disclaimer

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

Token Metrics does not recommend buying, selling, or holding any cryptocurrency. Conduct your due diligence and consult your financial advisor before making investment decisions.

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Practical Guide to Building Robust REST APIs

Token Metrics Team

REST APIs power much of the web and modern integrations—from mobile apps to AI agents that consume structured data. Understanding the principles, common pitfalls, and operational practices that make a REST API reliable and maintainable helps teams move faster while reducing friction when integrating services.

What Is a REST API and Why It Matters

Representational State Transfer (REST) is an architectural style for networked applications. A REST API exposes resources (users, accounts, prices, etc.) via predictable HTTP endpoints and methods (GET, POST, PUT, DELETE). Its simplicity, cacheability, and wide tooling support make REST a go-to pattern for many back-end services and third-party integrations.

Key behavioral expectations include statelessness (each request contains the information needed to process it), use of standard HTTP status codes, and a resource-oriented URI design. These conventions improve developer experience and enable robust monitoring and error handling across distributed systems.

Core Design Principles and Endpoint Modeling

Designing a clear resource model at the outset avoids messy ad-hoc expansions later. Consider these guidelines:

Use nouns for resources: /users/123/orders, not /getUserOrder?id=123.
Support filtering and pagination: query parameters like ?limit=50&cursor=... prevent heavy payloads and improve UX.
Version with intent: /v1/ or header-based versioning can be used. Document breaking changes and provide migration paths.
Return consistent error shapes: include machine-readable codes, human messages, and optionally documentation links.

Model relationships thoughtfully: prefer nested resources for clarity (e.g., /projects/42/tasks) but avoid excessive nesting depth. A well-documented schema contract reduces integration errors and accelerates client development.

Authentication, Authorization & Security Practices

Security for REST APIs is multi-layered. Common patterns:

Token-based auth: OAuth 2.0 bearer tokens or API keys for service-to-service calls.
Scopes and RBAC: scope tokens narrowly to minimize blast radius; implement role-based access control for complex domains.
Transport security: always require TLS (HTTPS) and enforce secure headers (HSTS, CSP where relevant).
Validate inputs: server-side validation and strict schema checks prevent injection and logic errors.

Also consider rate limiting, token expiry, and key rotation policies. For APIs that surface sensitive data, adopt least-privilege principles and audit logging so access patterns can be reviewed.

Performance, Caching & Reliability

Latency and scalability are often where APIs meet their limits. Practical levers include:

HTTP caching: use ETags, Cache-Control, and conditional requests to reduce payloads and server load.
Pagination and streaming: avoid returning entire datasets; prefer cursors or chunked responses for large collections.
CDN and edge caching: cache public or semi-static responses at the edge to reduce origin traffic.
Graceful degradation and circuit breakers: fallback behaviors for downstream failures keep core features available.

Instrument your API with observability: structured logs, distributed traces, and metrics (latency, error rates, throughput). These signals enable data-driven tuning and prioritized fixes.

Testing, Tooling & Developer Experience

Quality APIs are well-tested and easy to adopt. Include:

Contract tests: verify server responses meet the documented schema to prevent regressions.
Integration and end-to-end tests: test authentication flows, error handling, and rate-limit behaviors.
Interactive docs and SDKs: OpenAPI/Swagger specs, Postman collections, and generated client libraries lower friction for integrators.
Mock servers: let front-end and AI agent teams iterate without waiting on back-end deployments.

Automate CI checks that validate linting, schema changes, and security scanning to maintain long-term health.

REST APIs for Crypto Data and AI Agents

When REST APIs expose market data, on-chain metrics, or signal feeds for analytics and AI agents, additional considerations apply. Data freshness, deterministic timestamps, provenance metadata, and predictable rate limits matter for reproducible analytics. Design APIs so consumers can:

Request time-series data with explicit timezones and sampling resolutions.
Retrieve provenance (source, block number, or snapshot id) to allow historical reconstruction.
Subscribe to webhooks or use polling efficiently to keep agents synchronized without exceeding quotas.

AI-driven workflows often combine multiple endpoints; consistent schemas and clear quotas simplify orchestration and reduce operational surprises. For example, Token Metrics demonstrates how structured crypto insights can be surfaced via APIs to support research and model inputs for agents.

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Token Metrics provides real-time prices, trading signals, and on-chain insights all from one powerful API. Grab a Free API Key

Frequently Asked Questions

What is the difference between REST and RESTful?

"REST" refers to the architectural constraints defined by Roy Fielding. "RESTful" is an informal adjective describing APIs that follow REST principles—though implementations vary in how strictly they adhere to the constraints.

How should I version a REST API?

Use semantic intent when versioning. URL-based versions (e.g., /v1/) are explicit, while header-based or content negotiation approaches avoid URL churn. Regardless, document deprecation timelines and provide backward-compatible pathways.

When should I use REST versus GraphQL?

REST is simple and cache-friendly for resource-centric models. GraphQL excels when clients need flexible queries across nested relationships. Consider client requirements, caching strategy, and operational complexity when choosing.

How do I handle rate limiting and quotas?

Expose limit headers, return standard status codes (e.g., 429), and provide retry-after guidance. Offer tiered quotas and clear documentation so integrators can design backoffs and fallback strategies.

What tools help document and test REST APIs?

OpenAPI (Swagger) for specs, Postman for interactive exploration, Pact for contract testing, and CI-integrated schema validators are common choices. Combine these with monitoring and API gateways for observability and enforcement.

Disclaimer

This article is for educational and technical reference only. It is not financial, legal, or investment advice. Always evaluate tools and services against your own technical requirements and compliance obligations before integrating them into production systems.

Research

Mastering REST APIs: Principles, Design, Practices

Token Metrics Team

REST APIs power most modern web and mobile back ends by providing a uniform, scalable way to exchange data over HTTP. Whether you are building microservices, connecting AI agents, or integrating third‑party feeds, understanding the architectural principles, design patterns, and operational tradeoffs of REST can help you build reliable systems. This article breaks down core concepts, design best practices, security measures, and practical steps to integrate REST APIs with analytics and AI workflows.

Understanding REST API Fundamentals

REST (Representational State Transfer) is an architectural style for distributed systems. It emphasizes stateless interactions, resource-based URIs, and the use of standard HTTP verbs (GET, POST, PUT, DELETE, PATCH). Key constraints include:

Statelessness: Each request contains all necessary context, simplifying server design and enabling horizontal scaling.
Resource orientation: Resources are identified by URIs and represented in formats such as JSON or XML.
Uniform interface: Consistent use of HTTP methods and status codes improves predictability and interoperability.

When designing APIs, aim for clear resource models, intuitive endpoint naming, and consistent payload shapes. Consider versioning strategies (URL vs header) from day one to avoid breaking clients as your API evolves.

Design Patterns and Best Practices for REST APIs

Good API design balances usability, performance, and maintainability. Adopt these common patterns:

Resource naming: Use plural nouns (/users, /orders) and hierarchical paths to express relationships.
HTTP semantics: Map create/read/update/delete to POST/GET/PUT/DELETE and use PATCH for partial updates.
Pagination and filtering: Return large collections with pagination (cursor or offset) and provide filters and sort parameters.
Hypermedia (HATEOAS): Include links to related resources when appropriate to make APIs self-descriptive.
Error handling: Use structured error responses with machine-readable codes and human-friendly messages.

Document endpoints with examples and schemas (OpenAPI/Swagger). Automated documentation and SDK generation reduce integration friction and lower client-side errors.

Securing and Scaling REST APIs

Security and operational resilience are core concerns for production APIs. Consider the following layers:

Authentication & authorization: Use OAuth2, JWT, or API keys depending on threat model. Keep tokens short-lived and enforce least privilege.
Input validation: Validate all incoming data to prevent injection and logic vulnerabilities.
Rate limiting & throttling: Protect backends from abuse and noisy neighbors by implementing quotas and backoff signals.
Transport security: Enforce TLS (HTTPS) and configure secure ciphers and headers.
Observability: Expose metrics, structured logs, and distributed traces to troubleshoot latency and failure modes.

For scale, design for statelessness so instances are replaceable, use caching (HTTP cache headers, CDN, or edge caches), and partition data to reduce contention. Use circuit breakers and graceful degradation to maintain partial service during downstream failures.

Integrating REST APIs with AI, Analytics, and Crypto Workflows

REST APIs are frequently used to feed AI models, aggregate on‑chain data, and connect analytics pipelines. Best practices for these integrations include:

Schema contracts: Define stable, versioned schemas for model inputs and analytics outputs to avoid silent breakages.
Batch vs streaming: Choose between batch endpoints for bulk processing and streaming/webhook patterns for real‑time events.
Data provenance: Attach metadata and timestamps so downstream models can account for data freshness and lineage.
Testing: Use contract tests and synthetic data generators to validate integrations before deploying changes.

To accelerate research workflows and reduce time-to-insight, many teams combine REST APIs with AI-driven analytics. For example, external platforms can provide curated market and on‑chain data through RESTful endpoints that feed model training or signal generation. One such option for consolidated crypto data access is Token Metrics, which can be used as part of an analysis pipeline to augment internal data sources.

Build Smarter Crypto Apps & AI Agents with Token Metrics

Token Metrics provides real-time prices, trading signals, and on-chain insights all from one powerful API. Grab a Free API Key

FAQ: Common REST API Questions

What is the difference between REST and RESTful?

REST is an architectural style defined by constraints; "RESTful" describes services that adhere to those principles. In practice, many APIs are called RESTful even if they relax some constraints, such as strict HATEOAS.

When should I version an API and how?

Version early when breaking changes are likely. Common approaches are path versioning (/v1/) or header-based versioning. Path versioning is simpler for clients, while headers keep URLs cleaner. Maintain compatibility guarantees in your documentation.

How do I choose between REST and GraphQL?

REST is straightforward for resource-centric designs and benefits from HTTP caching and simple tooling. GraphQL excels when clients need flexible queries and to reduce over-fetching. Choose based on client needs, caching requirements, and team expertise.

What are practical rate limiting strategies?

Use token bucket or fixed-window counters, and apply limits per API key, IP, or user. Provide rate limit headers and meaningful status codes (429 Too Many Requests) to help clients implement backoff and retry strategies.

How can I test and monitor a REST API effectively?

Combine unit and integration tests with contract tests (OpenAPI-driven). For monitoring, collect metrics (latency, error rates), traces, and structured logs. Synthetic checks and alerting on SLA breaches help detect degradations early.

What is the best way to document an API?

Use OpenAPI/Swagger to provide machine-readable schemas and auto-generate interactive docs. Include examples, authentication instructions, and clear error code tables. Keep docs in version control alongside code.

Disclaimer

This article is educational and informational only. It does not constitute financial, investment, legal, or professional advice. Evaluate tools and services independently and consult appropriate professionals for specific needs.

Research

Mastering REST APIs: Principles, Design, and Best Practices

Token Metrics Team

REST APIs power much of the modern web, mobile apps, and integrations between services. Whether you are building a backend for a product, connecting to external data sources, or composing AI agents that call external endpoints, understanding REST API fundamentals helps you design reliable, maintainable, and performant systems.

What is a REST API and why it matters

Representational State Transfer (REST) is an architectural style that uses simple HTTP verbs to operate on resources identified by URLs. A REST API exposes these resources over HTTP so clients can create, read, update, and delete state in a predictable way. Key benefits include:

Stateless interactions that simplify scaling and load balancing.
Uniform interface using standard HTTP verbs (GET, POST, PUT/PATCH, DELETE).
Human-readable endpoints and predictable behavior for developers and tools.

REST is not a strict protocol; it is a set of constraints that make APIs easier to consume and maintain. Understanding these constraints enables clearer contracts between services and smoother integration with libraries, SDKs, and API gateways.

Core principles and common HTTP methods

Designing a RESTful API starts with resources and consistent use of HTTP semantics. Typical patterns include:

Resource-oriented URLs: /users/123/orders/456 rather than RPC-style method names.
HTTP methods: GET for reads, POST for creation, PUT/PATCH for updates, DELETE for deletion.
Status codes: 200 OK, 201 Created, 204 No Content, 400 Bad Request, 401 Unauthorized, 403 Forbidden, 404 Not Found, 429 Too Many Requests, 500 Server Error.
Content negotiation: Use Accept and Content-Type headers (application/json, application/xml) to support clients.

Use idempotency for safety: GET, PUT, and DELETE should be safe to retry without causing unintended side effects. POST is commonly non-idempotent unless an idempotency key is provided.

Design patterns: pagination, filtering, and versioning

As APIs grow, practical patterns help keep them efficient and stable:

Pagination: Offer cursor-based or offset-based pagination for collections. Cursor pagination generally performs better at scale.
Filtering and sorting: Support query parameters (e.g., ?status=active&sort=-created_at) and document allowed fields.
Versioning: Avoid breaking changes by putting versions in the URL (/v1/) or in headers. Maintain clear deprecation policies and migration guides.
Hypermedia (HATEOAS): Optionally include links to related resources to help clients discover available actions.

Security, performance, and operational best practices

Security and reliability are essential for production APIs. Consider these practices:

Authentication & authorization: Prefer OAuth2, JWTs, or API keys depending on your use case. Use scopes and least-privilege access.
Transport security: Enforce TLS for all endpoints and disable deprecated TLS ciphers.
Rate limiting and quotas: Protect your backend and provide clear error responses (429) with retry headers.
Caching: Use HTTP caching headers (Cache-Control, ETag) and CDN fronting for read-heavy endpoints.
Monitoring and observability: Emit structured logs, metrics, and distributed traces so you can diagnose latency, errors, and bottlenecks.

These controls reduce downtime and make integration predictable for client teams and third-party developers.

Testing, documentation, and developer experience

Good testing and clear docs accelerate adoption and reduce bugs:

Automated tests: Unit test controllers and routes, and use integration tests against a staging environment or simulated backend.
Contract testing: Tools like OpenAPI/Swagger and schema validation ensure clients and servers agree on payloads and types.
Interactive docs and SDKs: Provide OpenAPI specs, example curl commands, and autogenerated client libraries for common languages.
Postman and CI: Use Postman collections or similar for exploratory testing and include API checks in CI pipelines.

These measures improve developer productivity and reduce the risk of downstream failures when APIs evolve.

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Token Metrics provides real-time prices, trading signals, and on-chain insights all from one powerful API. Grab a Free API Key

What is the difference between REST and RESTful?

REST is the architectural style; RESTful typically describes APIs that follow REST constraints such as statelessness, resource orientation, and use of HTTP verbs. In practice the terms are often used interchangeably.

When should I use PUT vs PATCH?

PUT generally replaces a full resource and is idempotent; PATCH applies partial changes and may not be idempotent unless designed to be. Choose based on whether clients send full or partial resource representations.

How do I choose between URL versioning and header versioning?

URL versioning (/v1/) is simple and visible to clients, while header versioning is cleaner from a URL standpoint but harder for users to discover. Pick a strategy with a clear migration and deprecation plan.

What are common causes of REST API performance issues?

Typical causes include unoptimized database queries, chatty endpoints that require many requests, lack of caching, and large payloads. Use profiling, caching, and pagination to mitigate these issues.

How can REST APIs support AI agents?

AI agents often orchestrate multiple data sources and services via REST APIs. Well-documented, authenticated, and idempotent endpoints make it safer for agents to request data, trigger workflows, and integrate model outputs into applications.

What tools help with API design and documentation?

OpenAPI/Swagger, Postman, Redoc, and API gateways (e.g., Kong, Apigee) are common. They help standardize schemas, run automated tests, and generate SDKs for multiple languages.

Disclaimer

This article is educational and informational only. It does not constitute professional advice. Evaluate technical choices and platforms based on your project requirements and security needs.

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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