Integrations by Anthropic - Claude can now connect to your world

Hey Hunters, I’m excited to hunt Claude’s new Integrations! 🚀

Claude can now connect directly to tools like Jira, Confluence, Intercom, Asana, Zapier, Cloudflare, and more, thanks to the new Integrations powered by the Model Context Protocol (MCP). This makes Claude more than just an assistant — it becomes an informed teammate that can understand your work context and take actions across your apps.

Highlights:

• Connect your favorite tools and even build your own integrations in ~30 minutes

• Automate tasks like pulling HubSpot data, filing bugs from user reports, or managing Jira tickets

• Claude’s Advanced Research mode can now search across the web, Google Workspace, and your connected apps — compiling deep, cited reports in 5–45 minutes

• Web search now available globally on all paid plans

If you’re building or scaling with AI, this is a big step forward. Excited to see what the community creates with it!

this is really cool, Claude is getting more and more powerful by the day :)

All the best for the launch @kevin_garcia1 & team!

Congrats on the launch!

Wow, this is a gamechanger

Hey Team, Congrats on the launch! 🎉

I love the idea of automating tasks and creating custom integrations so easily. Plus, the Advanced Research mode sounds like a fantastic addition for anyone looking to leverage AI for deep, cited reports across multiple platforms.

Whoa, this is next-level Tony Stark vibes! Feels like Claude is the new JARVIS 🤯🔥 Just watched the demo, and I’m floored by how smooth and futuristic this feels—Claude pulling data, automating tasks, and basically becoming your AI teammate? Mind. Blown.

Living in a place where tech like this still feels like sci-fi, seeing it in action is wild. Huge congrats on the launch—this is the kind of innovation that makes me excited for the future! 🚀

🔥🔥

Congratulations on the launch of Integrations by Anthropic This solution effectively addresses the challenge of app connectivity.

How do you envision users prioritizing which apps to integrate first, and what support will you offer for optimizing those connections?

Its easy to use and useful tool to me .

Its have some unquic features

Everything around us — such as air, water, food, stones, plants, animals, etc. — is called "matter." Matter is anything that occupies space and has mass.

In ancient times, Indian philosophers classified matter into five elements: earth, water, fire, air, and sky. Greek philosophers made a similar classification.

Today, scientists classify matter based on its physical properties and chemical nature. In this chapter, we will study matter based on its physical properties. The chemical properties will be studied in later chapters.

Matter is made up of particles — earlier scientists were divided into two views: some believed that matter is continuous, like a piece of wood, while others believed that it is made up of small particles, like sand.

Activity 1.1: When we dissolve salt or sugar in water, it disappears and the water level does not rise. This means that the salt particles spread out and fit into the spaces between the water particles.
This proves that matter is made up of particles, and these particles have empty spaces between them into which other particles can fit.

How small are the particles of matter?

In Activity 1.2, when a few crystals of potassium permanganate are dissolved in water, the water becomes deeply colored. Then, repeatedly taking 10 mL of this solution and adding it to 90 mL of clear water (dilution), the solution still shows a light color even after several dilutions.

Conclusion:

A single crystal of potassium permanganate contains millions of tiny particles.

These particles keep dividing and spreading throughout the water.

This shows that the particles of matter are extremely small — so small that we can’t even imagine their size.

Example: The same experiment can be done with Dettol, and its smell can still be detected even after several dilutions.

Characteristics of Particles of Matter (Explained briefly):
1. There is space between particles

From Activities 1.1 and 1.2, we observe that salt, sugar, or potassium permanganate mix completely in water.
This means that there is space between the particles of matter, which allows other particles to enter and occupy those spaces.
2. Particles are constantly moving
Activity 1.3:
When an incense stick (agarbatti) is lit, its fragrance spreads far and wide.
This shows that particles are in constant motion and can spread throughout the surroundings.
Activity 1.4:
When ink and honey are added to water:
Ink slowly spreads throughout the water,
Honey settles at the bottom as it is heavier.
This indicates that particles spread on their own (diffusion), but the rate depends on the type of matter and temperature.
Activity 1.5:
Potassium permanganate spreads faster in hot water compared to cold water.
This shows that increasing temperature increases the speed of particles and the rate of diffusion.
Conclusion:
Particles of matter are constantly in motion.
Increasing temperature increases their movement and kinetic energy.
The particles of two different substances mix on their own — this is called diffusion, and it happens faster at higher temperatures.

"Particles of Matter Attract Each Other" — Explained briefly:
1. There is a force of attraction between particles

Activity 1.6:
From the game of forming a human chain:
When students hold each other tightly, it becomes difficult to break the chain.
This shows that in some substances, the force of attraction between particles is strong, which keeps them tightly bound together.

Activity 1.7:
When we try to break an iron nail, a piece of chalk, and a rubber band:
The iron nail is the hardest to break.
This means that the force of attraction between particles in iron is the strongest.

Activity 1.8:
It is difficult to break the surface of water with a finger, because the water particles attract each other and stay bonded.
Conclusion:
There is a force of attraction between the particles of matter.
This force varies from substance to substance — it is stronger in some, weaker in others.
This attractive force is what holds the particles together.
1.3 States of Matter explains the three main states — Solid, Liquid, and Gas.
1.3.1 Solid State:
Solids have a definite shape, boundary, and volume.
They are hard to compress (negligible compressibility).
Solids are rigid and retain their shape.

Examples: book, pencil, wood, etc.
Special cases:
A rubber band can stretch but returns to its original shape.
Sugar and salt consist of individual grains, but each grain has a fixed shape.
A sponge can be compressed due to air in it, but it is still a solid.
1.3.2 Liquid State:
Liquids do not have a fixed shape but have a fixed volume.
They flow and take the shape of the container they are in.
Liquids can be poured and measured easily.

Examples: water, milk, juice

Diffusion:
Solids, liquids, and gases can dissolve in liquids easily.
Gases like oxygen and CO₂ dissolve in water, allowing aquatic animals to breathe.
Diffusion in liquids is faster than in solids because particles are more mobile and have more space between them.
Conclusion:
Solids: Fixed shape and volume, rigid.
Liquids: No fixed shape, fixed volume, flow easily.
Diffusion is faster in liquids due to more particle movement and space.
1.3.3 The Gaseous State — Explained briefly:
Gases can spread out a lot — for example, many balloons can be filled from a single gas cylinder.
There is a large amount of empty space between gas particles, and they move very rapidly.
Gases can be easily compressed, which is why a lot of gas can be stored in a cylinder.
Conclusion from Activity 1.11:

Out of three syringes:
The one filled with air (gas) can be compressed easily.
The one with water (liquid) is harder to compress.
The one with chalk (solid) is almost impossible to compress.
Conclusion:
Gases are the most compressible form of matter.
This is because gas particles have the most empty space between them.
Key Point:
In the gaseous state, particles are far apart, move freely, and can be easily compressed.
Gaseous State — Explained briefly:
1. Gases are highly compressible.
This is why gases like LPG, CNG, and oxygen can be easily stored and transported in compressed cylinders.
2. Gases diffuse very quickly.
For example, the smell of food cooking in the kitchen spreads quickly throughout the house.
This happens because gas particles move very fast and are widely spaced.
3. Gases exert pressure.
Gas particles move rapidly and collide with each other and the walls of the container.
These collisions create pressure.
Conclusion:
Gases spread rapidly, can be compressed, and create pressure.
Because of these properties, gases are used in cylinders and as fuels.

Remote MCP servers! That is really great progress in the past months. Looking forward to trying things out!

Congratulations on introducing Integrations! It’s exciting to see Claude expand its capabilities. How do you plan to prioritize which apps and tools to integrate first based on user demand?

Congrats on the launch! This makes it so much easier to bring MCP tools to Claude dot ai (without all the configuration for every server) :) There are more and more remote (and even managed) MCP servers out there that all we need to do is to plug a single URL to equip our AI agents with so many powerful tools. For people looking for remote MCP servers compatible with Claude Integrations, I make a list of them here https://github.com/sylviangth/awesome-remote-mcp-servers

Cuemby me parece una empresa prometedora en cloud y DevOps, aunque todavía le falta visibilidad.