Diagnostics firm QuidelOrtho Corp is looking to sell its point-of-care testing unit at a valuation of $1.5 billion, the Financial Times reported.
Private equity firms ranging from Advent International to SK Capital Partners and Archimed have expressed interest in the asset, according to the FT report, which cited people familiar with the matter.
by James Xu via The Epoch Times,
The European Commission, Germany, Greece, and the Netherlands have joined the U.S.-led Pax Silica partnership, expanding a group focused on securing supply chains for artificial intelligence and other critical technologies.
The announcement came at a summit in Washington on June 23 hosted by the U.S. State Department. The partnership aims to strengthen cooperation on semiconductors, critical minerals, energy, and advanced manufacturing.
U.S. Under Secretary of State for Economic Affairs Jacob Helberg welcomed the new members.
"The European Union does not join Pax Silica as one more name on a list. It arrives as what it is: the largest single market on Earth," he said.
Helberg highlighted Germany's industrial base, Greece's shipping industry and strategic location, and the Netherlands' longstanding role in semiconductor equipment, where it has long been a key partner.
According to the U.S. State Department, members signed a declaration committing to "mutual prosperity, technological progress, and economic security." The agreement also calls for reducing excessive supply chain dependencies and building trusted technology ecosystems with private industry.
The European Union joined after EU member states authorized the European Commission to sign on behalf of the bloc.
Pax Silica was launched in Washington in December 2025. Founding members included Japan, South Korea, Singapore, and Israel, among others. They signed the initial declaration to strengthen cooperation on technologies considered critical to future economic security.
The partnership has grown steadily since then. Members now also include Australia, India, the Philippines, Sweden, the United Arab Emirates, and the United Kingdom. Taiwan has endorsed the initiative's principles through a separate joint statement but is not a formal signatory.
U.S. officials say the partnership is intended to build trusted supply chains among allies. The move forms part of broader U.S. efforts to reduce dependence on China for technologies such as advanced chips, critical minerals, and AI infrastructure.
China currently dominates global rare earth processing, accounting for roughly 80 to 90 percent of refined supply. It also holds a significant share of mining output for several key critical minerals used in electronics and renewable energy technologies.
In April, the United States and the Philippines announced plans for a 4,000-acre economic security zone in the Luzon Economic Corridor to support production for strategic supply chains under the partnership.
This zone is described by officials as the first AI-native industrial acceleration hub under Pax Silica.
Helberg said similar cooperation on critical minerals is under discussion with Kazakhstan, though no agreement has been announced. Such projects mark the initiative's move into practical application.
Further announcements on new members and projects are expected in the coming weeks.
https://www.zerohedge.com/ai/eu-joins-us-led-pax-silica-alliance-secure-ai-supply-chainsThe Trump administration is close to permitting Anthropic to restore public access to its flagship Fable 5 AI model, Axios reported on Saturday, citing a source familiar with the circumstances.
The outlet added that that restrictions on Fable 5 could be lifted as early as next week. Another official told the publication that negotiations are expected to continue over the weekend and that Anthropic is hopeful of restoring access soon.
Anthropic abruptly disabled its most advanced AI models, Mythos 5 and Fable 5, for all users after the US government's June 12 export control order.
https://breakingthenews.net/Article/US-said-to-restore-access-to-Anthropic's-Fable-5/66587213
Slovak Prime Minister Robert Fico reiterated on Saturday that his country will not participate in the European Union's €70 billion package to fund military assistance for Ukraine.
Speaking to the national broadcaster SRTV's podcast Saturday Dialogues, Fico insisted that such an approach on the bloc's part will only contribute to the continuation of the conflict. He also said he will try to persuade the EU to exclude Slovakia from all future packages, which means it would not need his country's mandate to approve such decisions.
Previously, Fico announced the decision during the Ukraine Recovery Conference in Gdansk. He also stressed that the EU should support peace initiatives instead.
https://breakingthenews.net/Article/Fico-rules-out-military-loans-to-Ukraine/66587207
Civil Aviation Organization spokesman Majid Akhavan said Iranian and UAE aviation authorities had issued the necessary permits for flights to resume from July 1.
He said the route would initially be served by Iranian airlines, with other carriers expected to be added later following the necessary reviews.
Akhavan added that the resumption of flights on other international routes remained under review and subject to regulatory approvals.
Direct-to-cell satellite technology could one day help Iranians bypass part of the Islamic Republic’s digital blockade, but it is not yet a practical solution to the country’s internet shutdown despite widespread hopes.
Internet access in Iran was cut off for months, first amid the January protests and then during the March war, before being partially restored after an 88-day nationwide blackout.
International connectivity has returned for many fixed-line and home broadband users, but the network remains degraded, unstable and heavily censored.
More than 100 days after the broader shutdown began, the pattern of restoration has been limited, selective and tightly controlled.
From conditional access tied to identity verification and the migration of businesses to domestic platforms to the creation of internet-access whitelists, the Islamic Republic appears intent on preserving its multi-layered system of censorship, surveillance and communications control.
The National Information Network, centralized gateways to the global internet, controlled mobile-network settings, identity-verification systems and device-registration mechanisms are all tools that allow the state to restrict or cut off public access to the global internet while keeping stable communication channels open for selected groups.
That is why direct-to-cell, or D2C, has attracted growing attention among Iranians. Many see the promise of direct phone-to-satellite connectivity — without a dish, terminal, domestic operator or government gateway — as a possible way out of the Islamic Republic’s digital prison.
The idea has gained enough attention that the Pentagon held talks with SpaceX about activating direct-to-cell service for Iranian citizens. According to Reuters, SpaceX requested up to $500 million to launch the service and $100 million per month to operate it.
The central question, however, is whether current versions of direct-to-cell technology can meet such expectations on the scale of Iran. For now, the answer is no: today’s systems remain limited in capacity, vulnerable to radio interference and risky for users who could be identified through Iran’s device-registration and mobile-network systems.
The central questions, however, remain: Can current versions of Direct-to-Cell technology truly meet such expectations on the scale of Iran? Is the technology still only an emergency and limited communication channel, or can it become a scalable escape route for millions of Iranian users? And if future generations of the technology operate without relying on domestic towers and operators, will Iran’s digital wall be broken?
Dependency on mobile operators and the foreign eSIM scenario
In ordinary Starlink service, the satellite connects to a dedicated ground terminal — the same dish that users must obtain, install, maintain and hide from the Islamic Republic. The phone connects to the Starlink modem through Wi-Fi.
But Direct-to-Cell is based on a different idea: an ordinary phone itself becomes the receiver and transmitter for satellite communication.
Current versions of Direct-to-Cell are mostly not independent satellite internet systems. Rather, they complement the existing coverage of mobile operators in each area, effectively turning the satellite into a space-based cell tower whose real function is to cover mobile-network dead zones.
The use of independent S-Band frequencies and the deployment of satellites in very low Earth orbit, or VLEO, closer to the Earth’s surface, are among the paths that could make D2C more relevant to Iran’s problem.
Under this scenario, foreign Starlink partner operators such as T-Mobile, Kyivstar or One NZ in New Zealand would declare Iranian territory a zone without terrestrial coverage and include it under their own service.
Politically and technically, this model comes closer to what Iranian citizens expect from the technology. In that case, a phone using a SIM card or eSIM from one of these operators could establish a D2C connection from inside Iran to SpaceX’s new-generation satellites. Reports say about 700 satellites of this type are already in orbit.
But making this scenario a reality is not limited to SpaceX’s will or decision. It requires an entire chain: frequency spectrum, regulatory licenses, compatible phones, modems, antennas, transmission power and chipsets that support new satellite bands.
Companies such as Qualcomm, MediaTek, Apple, Samsung and Google play a decisive role in this process. If phone hardware is not ready, even an advanced satellite constellation will not become a practical connection for users inside Iran.
Even under this optimistic scenario for Iran, three major obstacles remain: limited capacity, the possibility of radio interference, and the risk of users being identified through device registration and the Hamta system.
1. Capacity limits in densely populated areas
The first serious obstacle to widespread D2C deployment in Iran is capacity. This connection is not designed to replace urban internet. It is designed to deliver minimal connectivity to areas with no terrestrial coverage or weak coverage. But in Iran, the issue is not simply connecting a few users on a road or in a mountain area.
The issue is a communications blackout in cities where hundreds of thousands of people may simultaneously need messaging apps, voice and video calls, news, maps, email, financial services, and the ability to send photos and videos.
In some early tests, recorded bandwidth for a single connection reached about 14 Mbps. But this number should not be confused with the experience of urban internet speeds. In the real world, that limited bandwidth must be shared among all users across the wide area covered by each satellite.
To better understand the scale, in a city such as Tehran, if only 1% of residents simultaneously wanted a very basic 1 Mbps connection, the network would need capacity equivalent to 99 Gbps. Compared with the current capacity of each active D2C beam, which ranges from 4 to 17 Mbps, and even compared with an optimistic 150 Mbps outlook for future generations, this reveals a gap hundreds of times larger than current capabilities.
2. Radio interference from ground signals
Even if D2C can reduce the problems of capacity and dependence on domestic operators, it still faces an obstacle rooted in the physics of radio waves. To connect, a phone must receive a very weak signal from a satellite moving hundreds of kilometers above the Earth, while operating in an environment filled with nearby mobile towers, ground transmitters and local signals that are far stronger.
In this context, the ratio between the desired signal and surrounding interference determines whether the receiver can detect the satellite signal at all amid noise and terrestrial interference.
A nearby ground tower operated by MCI or Irancell could emit a signal so much stronger than the satellite signal that the phone’s receiver effectively fails to see the weaker signal or cannot build a stable connection on it.
In such a situation, the government does not need to target the satellite. It only needs to use towers, transmitters and control over mobile-network power levels to make the radio environment around the user unfavorable for satellite connectivity.
For the Islamic Republic, this type of interference could be fast, local and low-cost. So even if the satellite is beyond the government’s reach, the user’s phone remains on the ground, inside a radio environment that can be manipulated. Future versions with dedicated spectrum, better modems and more resilient protocols may reduce part of this vulnerability, but they will not eliminate it entirely.
3. Device registration and user identification
The more serious security question is how identifiable a user inside Iran would be when using D2C. In Iran, a phone is not merely a communication device. The SIM card, subscriber identity, device identity and the user’s real identity are linked together across several layers.
Every phone has a unique hardware identifier, or IMEI, which serves as the device’s identity on mobile networks. The Hamta system can link this identifier to the SIM card, activation history, ownership and, in many cases, the user’s real identity.
In such an environment, using a foreign SIM card or eSIM for satellite connectivity does not necessarily make the user anonymous. If a phone with a known IMEI suddenly tries to connect through an unauthorized satellite route using a foreign operator identifier, that behavior could become an unusual and flaggable pattern.
The combination of device registration, operator data, SIM-card databases and local monitoring tools could turn such a connection into a security risk. The key question, therefore, is how this can be done without exposing the user’s identity, location and behavioral pattern.
A strategic opportunity, not an immediate solution
Direct-to-Cell should be taken seriously, but it should not be exaggerated. For Iran, the appeal of this technology is clear: if one day an ordinary phone can connect to a satellite without a dish, separate terminal, domestic operator or Islamic Republic gateway, one of the foundations of Iran’s internet-control architecture will be challenged. But that day has not yet arrived. Current versions under development are mainly designed to cover dead zones, not to replace urban internet for tens of millions of users.
Limited capacity, the possibility of interference, and the risk of exposing and identifying users mean this technology is not currently a public and scalable escape route from Iran’s internet shutdown. Its present value is mostly as an emergency tool: sending messages, sharing locations, issuing alerts or maintaining brief communication during a crisis.
The future could be different if the next generation of satellites brings together higher capacity, independent spectrum, compatible phones, user security and global protective rules. Until then, Direct-to-Cell remains an important opening for the future — not today’s solution to the digital prison.
