What is Cryptojacking?

Crypto Basics

What is Cryptojacking? - A Comprehensive Guide

Learn everything about cryptojacking in this comprehensive guide. Understand what it is and how to protect yourself from this cybersecurity threat.

S. Vishwa

9 Minutes

In today's digital age, cybercriminals are constantly coming up with new ways to exploit unsuspecting victims. One such method is cryptojacking, a type of cybercrime that involves the unauthorized use of people's devices for cryptocurrency mining.

In this comprehensive guide, we will learn everything about cryptojacking, exploring what it is, how it works, and how you can protect yourself from falling victim to this insidious threat.

Before we delve into the intricacies of cryptojacking, it is essential to have a basic understanding of cryptocurrency.

Cryptocurrency refers to digital or virtual money that takes the form of tokens or "coins." While Bitcoin is the most well-known cryptocurrency, there are approximately 3,000 other forms in circulation.

These digital currencies operate using a distributed database called the blockchain, which records all transactions and ensures their integrity.

The Role of Miners - To produce new blocks in the blockchain, cryptocurrencies rely on individuals known as miners. These miners provide computing power to solve complex mathematical problems, for which they are rewarded with cryptocurrency.

In the case of larger cryptocurrencies like Bitcoin, dedicated computer rigs are used to complete these calculations, consuming a significant amount of electricity.

The Rise and Fall of Cryptojacking - Cryptojacking emerged as a response to the high costs associated with traditional cryptocurrency mining.

By surreptitiously using other people's devices, cybercriminals can mine for cryptocurrency without the need for expensive hardware or the burden of electricity bills. The cryptocurrency of choice for cryptojackers is often Monero due to its difficulty to trace.

However, cryptojacking has faced challenges in recent years. Law enforcement crackdowns and the shutdown of prominent cryptojacking platforms like Coinhive have had a dampening effect on this form of cybercrime.

Coinhive, a site that provided JavaScript code for website owners to mine Monero using their visitors' devices, was widely abused by hackers and ultimately shut down in 2019.

How Does Cryptojacking Work?

Methods of Infection - Cybercriminals employ various methods to infect devices and initiate cryptojacking.

One common approach is through malicious links embedded in phishing emails, which load crypto mining code onto the victim's computer upon clicking.

Another method involves injecting JavaScript code into websites or online ads, which automatically executes when the victim's browser loads the content.

The Impact on Performance - Cryptojacking scripts do not directly damage computers or steal data. Instead, they exploit the device's processing power to mine cryptocurrency, resulting in decreased performance.

Victims may experience slower system speed, frequent crashes, and shorter battery life. In business settings, the collective impact of cryptojacked systems can lead to increased IT costs and electricity consumption.

The Spread of Cryptojacking - Some cryptojacking scripts possess worming capabilities, allowing them to infect other devices and servers on a network. This makes them harder to detect and remove.

Additionally, some websites may request users' permission to mine cryptocurrency while on their site, positioning it as a fair exchange for free content.

However, malicious cryptojacking scripts continue to run even after the user leaves the initial site, often remaining hidden in the background.

How to Detect Cryptojacking?

Signs of Infection - Detecting cryptojacking can be challenging, as the process is often hidden or disguised as a legitimate activity on the victim's device.

However, there are several signs to watch out for. Decreased performance, such as slow system speed and frequent crashes, is a common indicator. Overheating devices, noticeable through an unusually fast-running fan, can also suggest the presence of cryptojacking scripts.

Monitoring CPU usage, especially during periods of low media content, can reveal spikes that may be attributed to cryptojacking activities.

Monitoring CPU Usage - A useful method for detecting cryptojacking is to monitor CPU usage using system tools like the Activity Monitor or Task Manager.

Unusually high CPU usage when no resource-intensive tasks are being performed can indicate the presence of cryptojacking scripts.

However, it's important to note that some scripts may attempt to disguise themselves or mask their activities as legitimate processes, making detection more challenging.

The Importance of Vigilance - Being vigilant and proactive is crucial in the fight against cryptojacking. Regularly monitoring your device's performance, staying informed about the latest cybersecurity trends, and investing in comprehensive cybersecurity solutions can help detect and prevent cryptojacking attacks.

How to Protect Yourself from Cryptojacking?

Invest in Comprehensive Cybersecurity - To protect yourself from cryptojacking and other cyber threats, it is essential to invest in comprehensive cybersecurity solutions. Cybersecurity provider can help detect and mitigate the risks associated with cryptojacking.

Additionally, keeping your operating system and applications up to date with the latest software updates and patches is crucial.

Stay Informed About Latest Trends - Cybercriminals are constantly evolving their techniques, including the methods they use for cryptojacking.

Staying informed about the latest trends and developments in cybersecurity can help you detect and protect against emerging threats.

Utilize Browser Extensions - Browser extensions designed to block cryptojacking scripts can be an effective defense against this form of cybercrime. Extensions like minerBlock, No Coin, and Anti Miner can help prevent cryptojacking activities when browsing the web.

Leverage Ad Blockers - Since cryptojacking scripts are often delivered through online ads, installing an ad blocker can be an additional layer of protection.

Ad Blocker Plus is a popular ad-blocking tool that can detect and block malicious cryptojacking code.

Disabling JavaScript - Disabling JavaScript in your browser settings can prevent cryptojacking code from executing on your device.

However, it's important to note that disabling JavaScript may also affect the functionality of certain websites and services, so exercise caution when employing this method.

Blocking Known Cryptojacking Pages - To further protect yourself from cryptojacking, you can create a whitelist of trusted websites and block known cryptojacking pages. This approach ensures that only verified websites are allowed, reducing the risk of encountering cryptojacking scripts.

Examples of Cryptojacking Attacks

Cryptojacking attacks have been observed in various contexts, targeting both individual users and organizations. Here are some notable examples:

App Store Exploitation - In 2019, several apps were discovered in the Microsoft Store that secretly mined cryptocurrency using the resources of unsuspecting users.

These apps were downloaded by users who encountered them through keyword searches or on lists of top free apps.

Upon launching the apps, users unknowingly downloaded cryptojacking JavaScript code, resulting in significant resource consumption and slower device performance.

Compromised Websites - In 2018, the Los Angeles Times' Homicide Report page was found to have embedded cryptojacking code.

Visitors to the page had their devices used to mine the cryptocurrency Monero. The minimal impact on device performance made it difficult to detect the presence of the cryptojacking script.

Industrial Control System Attack - Also in 2018, a European water utility control system fell victim to a cryptojacking attack.

The operational technology network of the utility plant was targeted, severely impacting the plant's management capabilities.

This incident marked the first known instance of a cryptojacking attack against an industrial control system.

YouTube Ads and Router Infections - Cryptojackers have even utilized platforms like YouTube and infected routers to carry out their activities.

In early 2018, the CoinHive miner was found running on YouTube ads through Google's DoubleClick platform.

Additionally, a massive cryptojacking attack infected over 200,000 MikroTik routers in Brazil during July and August of the same year, injecting CoinHive code into a significant amount of web traffic.

Legal and Ethical Implications of Cryptojacking

The Motive Behind Cryptojacking - The primary motivation behind cryptojacking is financial gain. Mining cryptocurrencies can be highly profitable, but the costs associated with traditional mining methods often limit the potential for profit.

Cryptojacking provides an illicit yet cost-effective way for cybercriminals to mine valuable coins without incurring significant expenses.

The Victim's Perspective - From the victim's perspective, cryptojacking represents a violation of privacy and the unauthorized use of computing resources.

While the direct impact may seem minimal, the cumulative effect of multiple cryptojacked systems can result in real costs for businesses and individuals.

Cybersecurity and the Fight Against Cryptojacking

The fight against cryptojacking relies on robust cybersecurity measures and the commitment of individuals, businesses, and law enforcement agencies.

By investing in comprehensive cybersecurity solutions, staying informed about emerging threats, and adopting preventive measures, we can collectively combat the menace of cryptojacking.

Frequently Asked Questions

Q1. What types of devices are most vulnerable to cryptojacking?

Any device with internet access can potentially fall victim to cryptojacking. However, the more powerful the device (like high-performance PCs), the more attractive it is for cryptojackers.

Q2. Why is cryptojacking seen as an easier way for criminals to make money compared to other forms of cybercrime?

Cryptojacking often goes unnoticed for a long time compared to other cybercrimes like hacking or ransomware. Thus, it allows cybercriminals to continuously earn money with less risk of being detected and stopped.

Q3. Can cryptojacking affect mobile devices like smartphones and tablets?

Yes, any device with processing power and an internet connection can be a target for cryptojacking, including smartphones and tablets.

Q4. If a device is infected, is there a way to trace the mined cryptocurrency back to the cryptojacker?

Tracing the mined cryptocurrency to its source can be challenging due to the anonymity features in cryptocurrencies like Monero, which are commonly used in cryptojacking.

Q5. How does cryptojacking affect businesses differently than individual users?

For businesses, the cumulative impact of many cryptojacked systems can lead to increased IT costs, electricity consumption, and potentially compromised business operations.

Q6. What can be done if my device has already been infected with a cryptojacking script?

In case of an infection, users should run a reputable antivirus or anti-malware software that can detect and remove the script.

It's also important to update all software and operating systems to their latest versions as updates often contain security fixes.

Q7. Are there any legal consequences for those who are caught cryptojacking?

Cryptojacking is illegal and those caught engaging in this activity can face serious legal repercussions, including fines and imprisonment.

Conclusion

Cryptojacking is a form of cybercrime that exploits the computing resources of unsuspecting victims for cryptocurrency mining.

By understanding how cryptojacking works and implementing effective protective measures, we can safeguard ourselves and our devices against this insidious threat.

Through comprehensive cybersecurity, vigilance, and staying informed about the latest trends, we can play an active role in combating cryptojacking and ensuring a secure digital environment for all.

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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Mastering REST APIs: Design, Security & Best Practices

Token Metrics Team

REST APIs are the backbone of modern web services and integrations. Whether you are building internal microservices, public developer APIs, or AI-driven data pipelines, understanding REST principles, security models, and performance trade-offs helps you design maintainable and scalable systems.

What is a REST API and why it matters

REST (Representational State Transfer) is an architectural style that relies on stateless communication, uniform interfaces, and resource-oriented design. A REST API exposes resources—users, orders, metrics—via HTTP methods like GET, POST, PUT, PATCH, and DELETE. The simplicity of HTTP, combined with predictable URIs and standard response codes, makes REST APIs easy to adopt across languages and platforms. For teams focused on reliability and clear contracts, REST remains a pragmatic choice, especially when caching, intermediaries, and standard HTTP semantics are important.

Core design principles for robust REST APIs

Good REST design balances clarity, consistency, and flexibility. Key principles include:

Resource-first URLs: Use nouns (e.g., /users/, /invoices/) and avoid verbs in endpoints.
Use HTTP semantics: Map methods to actions (GET for read, POST for create, etc.) and use status codes meaningfully.
Support filtering, sorting, and pagination: Keep payloads bounded and predictable for large collections.
Idempotency: Design PUT and DELETE to be safe to retry; document idempotent behaviors for clients.
Consistent error model: Return structured error objects with codes, messages, and actionable fields for debugging.

Documenting these conventions—preferably with an OpenAPI/Swagger specification—reduces onboarding friction and supports automated client generation.

Authentication, authorization, and security considerations

Security is non-negotiable. REST APIs commonly use bearer tokens (OAuth 2.0 style) or API keys for authentication, combined with TLS to protect data in transit. Important practices include:

Least privilege: Issue tokens with minimal scopes and short lifetimes.
Rotate and revoke keys: Provide mechanisms to rotate credentials without downtime.
Input validation and rate limits: Validate payloads server-side and apply throttling to mitigate abuse.
Audit and monitoring: Log authentication events and anomalous requests for detection and forensics.

For teams integrating sensitive data or financial endpoints, combining OAuth scopes, robust logging, and policy-driven access control improves operational security while keeping interfaces developer-friendly.

Performance, caching, and versioning strategies

APIs must scale with usage. Optimize for common access patterns and reduce latency through caching, compression, and smart data modeling:

Cache responses: Use HTTP cache headers (Cache-Control, ETag) and CDN caching for public resources.
Batching and filtering: Allow clients to request specific fields or batch operations to reduce round trips.
Rate limiting and quotas: Prevent noisy neighbors from impacting service availability.
Versioning: Prefer semantic versioning in the URI or headers (e.g., /v1/) and maintain backward compatibility where possible.

Design decisions should be driven by usage data: measure slow endpoints, understand paginated access patterns, and iterate on the API surface rather than prematurely optimizing obscure cases.

Testing, observability, and AI-assisted tooling

Test automation and telemetry are critical for API resilience. Build a testing pyramid with unit tests for handlers, integration tests for full request/response cycles, and contract tests against your OpenAPI specification. Observability—structured logs, request tracing, and metrics—helps diagnose production issues quickly.

AI-driven tools can accelerate design reviews and anomaly detection. For example, platforms that combine market and on-chain data with AI can ingest REST endpoints and provide signal enrichment or alerting for unusual patterns. When referencing such tools, ensure you evaluate their data sources, explainability, and privacy policies. See Token Metrics for an example of an AI-powered analytics platform used to surface insights from complex datasets.

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FAQ: What is a REST API?

A REST API is an interface that exposes resources over HTTP using stateless requests and standardized methods. It emphasizes a uniform interface, predictable URIs, and leveraging HTTP semantics for behavior and error handling.

FAQ: REST vs GraphQL — when to choose which?

REST suits predictable, cacheable endpoints and simple request/response semantics. GraphQL can reduce over-fetching and allow flexible queries from clients. Consider developer experience, caching needs, and operational complexity when choosing between them.

FAQ: How should I version a REST API?

Common approaches include URI versioning (e.g., /v1/) or header-based versioning. The key is to commit to a clear deprecation policy, document breaking changes, and provide migration paths for clients.

FAQ: What are practical security best practices?

Use TLS for all traffic, issue scoped short-lived tokens, validate and sanitize inputs, impose rate limits, and log authentication events. Regular security reviews and dependency updates reduce exposure to known vulnerabilities.

FAQ: Which tools help with testing and documentation?

OpenAPI/Swagger, Postman, and contract-testing frameworks allow automated validations. Observability stacks (Prometheus, Jaeger) and synthetic test suites help catch regressions and performance regressions early.

Disclaimer

This article is for educational and technical guidance only. It does not provide financial, legal, or investment advice. Evaluate tools, platforms, and architectural choices based on your organization’s requirements and compliance constraints.

Research

How REST APIs Power Modern Web & AI Integrations

Token Metrics Team

REST API technology underpins much of today’s web, mobile, and AI-driven systems. Understanding REST fundamentals, design trade-offs, and operational patterns helps engineers build reliable integrations that scale, remain secure, and are easy to evolve. This article breaks down the core concepts, practical design patterns, and concrete steps to integrate REST APIs with AI and data platforms.

What is a REST API?

REST (Representational State Transfer) is an architectural style for distributed systems that uses standard HTTP methods to operate on resources. A REST API exposes resources—such as users, orders, or sensor readings—via predictable endpoints and leverages verbs like GET, POST, PUT, PATCH, and DELETE. Key characteristics include statelessness, resource-based URIs, and standardized status codes. These conventions make REST APIs easy to consume across languages, frameworks, and platforms.

Design Principles and Best Practices

Good REST API design balances clarity, stability, and flexibility. Consider these practical principles:

Resource-first URIs: Use nouns for endpoints (e.g., /api/v1/orders) and avoid verbs in URLs.
HTTP semantics: Use GET for reads, POST to create, PUT/PATCH to update, and DELETE to remove; rely on status codes for outcome signaling.
Versioning: Introduce versioning (path or header) to manage breaking changes without disrupting consumers.
Pagination and filtering: Design for large datasets with limit/offset or cursor-based pagination and clear filtering/query parameters.
Consistent error models: Return structured errors with codes and messages to simplify client-side handling.

Document endpoints using OpenAPI/Swagger and provide sample requests/responses. Clear documentation reduces integration time and surface area for errors.

Security, Rate Limits, and Monitoring

Security and observability are central to resilient APIs. Common patterns include:

Authentication & Authorization: Use token-based schemes such as OAuth2 or API keys for machine-to-machine access. Scope tokens to limit privileges.
Rate limiting: Protect backend services with configurable quotas and burst controls. Communicate limits via headers and provide informative 429 responses.
Input validation and sanitization: Validate payloads and enforce size limits to reduce attack surface.
Encryption: Enforce TLS for all transport and consider field-level encryption for sensitive data.
Monitoring and tracing: Emit metrics (latency, error rates) and distributed traces to detect regressions and bottlenecks early.

Operational readiness often separates reliable APIs from fragile ones. Integrate logging and alerting into deployment pipelines and validate SLAs with synthetic checks.

Testing, Deployment, and API Evolution

APIs should be treated as products with release processes and compatibility guarantees. Recommended practices:

Contract testing: Use tools that assert provider and consumer compatibility to avoid accidental breaking changes.
CI/CD for APIs: Automate linting, unit and integration tests, and schema validation on every change.
Backward-compatible changes: Additive changes (new endpoints, optional fields) are safer than renames or removals. Use deprecation cycles for major changes.
Sandbox environments: Offer test endpoints and data so integrators can validate integrations without impacting production.

Following a disciplined lifecycle reduces friction for integrators and supports long-term maintainability.

Integrating REST APIs with AI and Crypto Data

REST APIs serve as the connective tissue between data sources and AI/analytics systems. Patterns to consider:

Feature pipelines: Expose REST endpoints for model features or use APIs to pull time-series data into training pipelines.
Model inference: Host inference endpoints that accept JSON payloads and return predictions with confidence metadata.
Data enrichment: Combine multiple REST endpoints for on-demand enrichment—e.g., combine chain analytics with market metadata.
Batch vs. realtime: Choose between batch pulls for training and low-latency REST calls for inference or agent-based workflows.

AI-driven research platforms and data providers expose REST APIs to make on-chain, market, and derived signals available to models. For example, AI-driven research tools such as Token Metrics provide structured outputs that can be integrated into feature stores and experimentation platforms.

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What is REST vs. other API styles?

REST is an architectural style that uses HTTP and resource-oriented design. Alternatives include RPC-style APIs, GraphQL (which offers a single flexible query endpoint), and gRPC (binary, high-performance RPC). Choose based on latency, schema needs, and client diversity.

How should I secure a REST API for machine access?

Use token-based authentication (OAuth2 client credentials or API keys), enforce TLS, implement scopes or claims to limit access, and rotate credentials periodically. Apply input validation, rate limits, and monitoring to detect misuse.

When should I version an API?

Version when making breaking changes to request/response contracts. Prefer semantic versioning and provide both current and deprecated versions in parallel during transition windows to minimize client disruption.

What tools help test and document REST APIs?

OpenAPI/Swagger for documentation, Postman for manual testing, Pact for contract testing, and CI plugins for schema validation and request/response snapshots are common. Automated tests should cover happy and edge cases.

How do I implement rate limiting without harming UX?

Use tiered limits with burst capacity, return informative headers (remaining/quota/reset), and provide fallback behavior (cached responses or graceful degradation). Communicate limits in documentation so integrators can design around them.

Disclaimer

The information in this article is educational and technical in nature. It is not professional, legal, or financial advice. Readers should perform their own due diligence when implementing systems and choosing vendors.

Research

Practical Guide to Building Robust REST APIs

Token Metrics Team

REST APIs power modern web and mobile applications by providing a consistent, scalable way to exchange data. Whether you are integrating microservices, powering single-page apps, or exposing data for third-party developers, understanding REST architecture, design norms, and operational considerations is essential to build reliable services.

Overview: What a REST API Is and When to Use It

Representational State Transfer (REST) is an architectural style that leverages standard HTTP methods to manipulate resources represented as URLs. A REST API typically exposes endpoints that return structured data (commonly JSON) and uses verbs like GET, POST, PUT/PATCH, and DELETE to indicate intent. REST is not a protocol; it is a set of constraints—statelessness, uniform interface, and resource-based modeling—that make APIs predictable and cache-friendly.

When evaluating whether to build a REST API, consider use cases: straightforward CRUD operations, broad client compatibility, and caching benefit from REST. If you need strong typing, real-time streaming, or more efficient batching, compare REST to alternatives like GraphQL, gRPC, or WebSockets before deciding.

Designing RESTful Endpoints & Best Practices

Good API design starts with resource modeling and clear, consistent conventions. Practical guidelines include:

Resource naming: Use plural nouns for resource collections (e.g., /users, /orders) and hierarchical paths for relationships (/users/{id}/orders).
HTTP methods: Map actions to verbs—GET for retrieval, POST for creation, PUT/PATCH for updates, DELETE for removals.
Status codes: Return appropriate HTTP status codes (200, 201, 204, 400, 401, 403, 404, 429, 500) and include machine-readable error payloads for clients.
Versioning: Prefer URI versioning (/v1/) or content negotiation via headers; plan for backward compatibility to avoid breaking clients.
Pagination & filtering: Provide limit/offset or cursor-based pagination and consistent filter/query parameters to support large datasets.
Documentation: Maintain up-to-date, example-driven docs (OpenAPI/Swagger) and publish clear request/response schemas.

These conventions improve discoverability and reduce integration friction for third-party developers and internal teams alike.

Security & Authentication for REST APIs

Security is a primary operational concern. REST APIs must protect data in transit and enforce access controls. Key controls include:

Transport Layer Security (TLS): Enforce HTTPS for all endpoints and redirect HTTP to HTTPS to prevent eavesdropping and man-in-the-middle attacks.
Authentication: Use established schemes such as OAuth 2.0, JWTs, or API keys depending on client types. Short-lived tokens and refresh flows reduce risk from token leakage.
Authorization: Implement fine-grained access checks (role-based or attribute-based) server-side; never rely on client-side enforcement.
Input validation & rate limiting: Validate and sanitize inputs to avoid injection attacks, and apply throttles to mitigate abuse and DoS threats.
Secrets management: Store credentials and private keys in secure vaults and rotate them regularly.

For teams integrating crypto or blockchain data, AI-driven research platforms can automate risk scanning and anomaly detection. For example, Token Metrics provides analytical signals that teams can cross-reference with on-chain activity when modeling API access patterns.

Performance, Testing, and Deployment

Operational resilience depends on performance engineering and testing. Practical steps include:

Caching: Use HTTP cache headers (ETag, Cache-Control) and CDN layering for public, cacheable endpoints.
Load testing: Simulate realistic traffic shapes, including burst behavior, to size servers and tune autoscaling rules.
Observability: Emit structured logs, request traces, and metrics (latency, error rates) and instrument distributed tracing (OpenTelemetry) for root-cause analysis.
CI/CD & contract testing: Automate schema validations, run contract tests against staging environments, and promote releases only when compatibility checks pass.
Graceful degradation: Handle downstream failures with timeouts, retries with backoff, and circuit breakers to avoid cascading outages.

Adopt a measurable SLA approach and define clear error budgets to balance feature velocity and reliability.

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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

FAQ: What is a REST API?

A REST API is an application programming interface that follows REST constraints. It exposes resources via URIs and uses HTTP methods to perform operations, typically exchanging JSON payloads.

FAQ: How does REST compare to GraphQL?

REST emphasizes multiple endpoints and resource-based modeling, while GraphQL provides a single endpoint that lets clients request precisely the fields they need. Choose based on data-fetching patterns, caching needs, and client complexity.

FAQ: What authentication methods are appropriate for REST APIs?

Common methods include OAuth 2.0 for delegated access, JWTs for stateless token-based auth, and API keys for service-to-service calls. Use short-lived tokens and secure storage practices to reduce exposure.

FAQ: How should I version my API?

Versioning strategies include URI versioning (/v1/resource), header-based negotiation, or semantic compatibility practices. Aim to minimize breaking changes and provide migration guides for clients.

FAQ: What are practical ways to test a REST API?

Combine unit tests, integration tests, contract tests (e.g., using OpenAPI), and end-to-end tests. Include load and chaos testing to validate behavior under stress and partial failures.

FAQ: How can I make my REST API more resilient?

Implement retries with exponential backoff, set sensible timeouts, use circuit breakers, and degrade gracefully. Observability (tracing and metrics) is essential to detect and respond to issues quickly.

Disclaimer

This article is for educational purposes and technical guidance only. It does not constitute investment advice, recommendations, or endorsements. Evaluate tools and services independently, and follow organizational security and compliance policies when designing and deploying APIs.

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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