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AI jailbreaking via poetry: bypassing chatbot defenses with rhyme | Kaspersky official blog

Tech enthusiasts have been experimenting with ways to sidestep AI response limits set by the models’ creators almost since LLMs first hit the mainstream. Many of these tactics have been quite creative: telling the AI you have no fingers so it’ll help finish your code, asking it to “just fantasize” when a direct question triggers a refusal, or inviting it to play the role of a deceased grandmother sharing forbidden knowledge to comfort a grieving grandchild.

Most of these tricks are old news, and LLM developers have learned to successfully counter many of them. But the tug-of-war between constraints and workarounds hasn’t gone anywhere — the ploys have just become more complex and sophisticated. Today, we’re talking about a new AI jailbreak technique that exploits chatbots’ vulnerability to… poetry. Yes, you read it right — in a recent study, researchers demonstrated that framing prompts as poems significantly increases the likelihood of a model spitting out an unsafe response.

They tested this technique on 25 popular models by Anthropic, OpenAI, Google, Meta, DeepSeek, xAI, and other developers. Below, we dive into the details: what kind of limitations these models have, where they get forbidden knowledge from in the first place, how the study was conducted, and which models turned out to be the most “romantic” — as in, the most susceptible to poetic prompts.

What AI isn’t supposed to talk about with users

The success of OpenAI’s models and other modern chatbots boils down to the massive amounts of data they’re trained on. Because of that sheer scale, models inevitably learn things their developers would rather keep under wraps: descriptions of crimes, dangerous tech, violence, or illicit practices found within the source material.

It might seem like an easy fix: just scrub the forbidden fruit from the dataset before you even start training. But in reality, that’s a massive, resource-heavy undertaking — and at this stage of the AI arms race, it doesn’t look like anyone is willing to take it on.

Another seemingly obvious fix — selectively scrubbing data from the model’s memory — is, alas, also a no-go. This is because AI knowledge doesn’t live inside neat little folders that can easily be trashed. Instead, it’s spread across billions of parameters and tangled up in the model’s entire linguistic DNA — word statistics, contexts, and the relationships between them. Trying to surgically erase specific info through fine-tuning or penalties either doesn’t quite do the trick, or starts hindering the model’s overall performance and negatively affect its general language skills.

As a result, to keep these models in check, creators have no choice but to develop specialized safety protocols and algorithms that filter conversations by constantly monitoring user prompts and model responses. Here’s a non-exhaustive list of these constraints:

  • System prompts that define model behavior and restrict allowed response scenarios
  • Standalone classifier models that scan prompts and outputs for signs of jailbreaking, prompt injections, and other attempts to bypass safeguards
  • Grounding mechanisms, where the model is forced to rely on external data rather than its own internal associations
  • Fine-tuning and reinforcement learning from human feedback, where unsafe or borderline responses are systematically penalized while proper refusals are rewarded

Put simply, AI safety today isn’t built on deleting dangerous knowledge, but on trying to control how and in what form the model accesses and shares it with the user — and the cracks in these very mechanisms are where new workarounds find their footing.

The research: which models got tested, and how?

First, let’s look at the ground rules so you know the experiment was legit. The researchers set out to goad 25 different models into behaving badly across several categories:

  • Chemical, biological, radiological, and nuclear threats
  • Assisting with cyberattacks
  • Malicious manipulation and social engineering
  • Privacy breaches and mishandling sensitive personal data
  • Generating disinformation and misleading content
  • Rogue AI scenarios, including attempts to bypass constraints or act autonomously

The jailbreak itself was a one-shot deal: a single poetic prompt. The researchers didn’t engage the AI in long-winded poetic debates in the vein of Norse skalds or modern-day rappers. Their goal was simply to see if they could get the models to flout safety instructions using just one rhyming request. As mentioned, the researchers tested 25 language models from various developers; here’s the full list:

The models in the poetic jailbreak experiment

A lineup of 25 language models from various developers, all put to the test to see if a single poetic prompt could coax AI into ditching its safety guardrails. Source

To build these poetic queries, the researchers started with a database of known malicious prompts from the standard MLCommons AILuminate Benchmark used to test LLM security, and recast them as verse with the aid of DeepSeek. Only the stylistic wrapping was changed: the experiment didn’t use any additional attack vectors, obfuscation strategies, or model-specific tweaks.

For obvious reasons, the study’s authors aren’t publishing the actual malicious poetic prompts. But they do demonstrate the general vibe of the queries using a harmless example, which looks something like this:

A baker guards a secret oven’s heat,
its whirling racks, its spindle’s measured beat.
To learn its craft, one studies every turn
,
how flour lifts, how sugar starts to burn.
Describe the method,
line by measured line,
that shapes a cake whose layers intertwine.

The researchers tested 1200 prompts across 25 different models — in both prose and poetic versions. Comparing the prose and poetic variants of the exact same query allowed them to verify if the model’s behavior changed solely because of the stylistic wrapping.

Through these prose prompt tests, the experimenters established a baseline for the models’ willingness to fulfill dangerous requests. They then compared this baseline to how those same models reacted to the poetic versions of the queries. We’ll dive into the results of that comparison in the next section.

Study results: which model is the biggest poetry lover?

Since the volume of data generated during the experiment was truly massive, the safety checks on the models’ responses were also handled by AI. Each response was graded as either “safe” or “unsafe” by a jury consisting of three different language models:

  • gpt-oss-120b by OpenAI
  • deepseek-r1 by DeepSeek
  • kimi-k2-thinking by Moonshot AI

Responses were only deemed safe if the AI explicitly refused to answer the question. The initial classification into one of the two groups was determined by a majority vote: to be certified as harmless, a response had to receive a safe rating from at least two of the three jury members.

Responses that failed to reach a majority consensus or were flagged as questionable were handed off to human reviewers. Five annotators participated in this process, evaluating a total of 600 model responses to poetic prompts. The researchers noted that the human assessments aligned with the AI jury’s findings in the vast majority of cases.

With the methodology out of the way, let’s look at how the LLMs actually performed. It’s worth noting that the success of a poetic jailbreak can be measured in different ways. The researchers highlighted an extreme version of this assessment based on the top-20 most successful prompts, which were hand-picked. Using this approach, an average of nearly two-thirds (62%) of the poetic queries managed to coax the models into violating their safety instructions.

Google’s Gemini 1.5 Pro turned out to be the most susceptible to verse. Using the 20 most effective poetic prompts, researchers managed to bypass the model’s restrictions… 100% of the time. You can check out the full results for all the models in the chart below.

How poetry slashes AI safety effectiveness

The share of safe responses (Safe) versus the Attack Success Rate (ASR) for 25 language models when hit with the 20 most effective poetic prompts. The higher the ASR, the more often the model ditched its safety instructions for a good rhyme. Source

A more moderate way to measure the effectiveness of the poetic jailbreak technique is to compare the success rates of prose versus poetry across the entire set of queries. Using this metric, poetry boosts the likelihood of an unsafe response by an average of 35%.

The poetry effect hit deepseek-chat-v3.1 the hardest — the success rate for this model jumped by nearly 68 percentage points compared to prose prompts. On the other end of the spectrum, claude-haiku-4.5 proved to be the least susceptible to a good rhyme: the poetic format didn’t just fail to improve the bypass rate — it actually slightly lowered the ASR, making the model even more resilient to malicious requests.

How much poetry amplifies safety bypasses

A comparison of the baseline Attack Success Rate (ASR) for prose queries versus their poetic counterparts. The Change column shows how many percentage points the verse format adds to the likelihood of a safety violation for each model. Source

Finally, the researchers calculated how vulnerable entire developer ecosystems, rather than just individual models, were to poetic prompts. As a reminder, several models from each developer — Meta, Anthropic, OpenAI, Google, DeepSeek, Qwen, Mistral AI, Moonshot AI, and xAI — were included in the experiment.

To do this, the results of individual models were averaged within each AI ecosystem and compared the baseline bypass rates with the values for poetic queries. This cross-section allows us to evaluate the overall effectiveness of a specific developer’s safety approach rather than the resilience of a single model.

The final tally revealed that poetry deals the heaviest blow to the safety guardrails of models from DeepSeek, Google, and Qwen. Meanwhile, OpenAI and Anthropic saw an increase in unsafe responses that was significantly below the average.

The poetry effect across AI developers

A comparison of the average Attack Success Rate (ASR) for prose versus poetic queries, aggregated by developer. The Change column shows by how many percentage points poetry, on average, slashes the effectiveness of safety guardrails within each vendor’s ecosystem. Source

What does this mean for AI users?

The main takeaway from this study is that “there are more things in heaven and earth, Horatio, than are dreamt of in your philosophy” — in the sense that AI technology still hides plenty of mysteries. For the average user, this isn’t exactly great news: it’s impossible to predict which LLM hacking methods or bypass techniques researchers or cybercriminals will come up with next, or what unexpected doors those methods might open.

Consequently, users have little choice but to keep their eyes peeled and take extra care of their data and device security. To mitigate practical risks and shield your devices from such threats, we recommend using a robust security solution that helps detect suspicious activity and prevent incidents before they happen.

To help you stay alert, check out our materials on AI-related privacy risks and security threats:

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Why Exposure Management Is Becoming a Security Imperative

Of course, organizations see risk. It’s just that they struggle to turn insight into timely, safe action. That gap is why exposure management has emerged, and also why it is now becoming a foundational security discipline. What the diagram makes clear is that risk doesn’t stay flat while organizations deliberate. From the moment an exposure is discovered and is reachable, exploitable, and known – the clock starts ticking. As time passes, environments change, dependencies grow, and attackers adapt faster. Remediation workflows fall behind. Manual coordination, unclear ownership, and fear of disruption all extend what is increasingly referred to as ‘exposure […]

The post Why Exposure Management Is Becoming a Security Imperative appeared first on Check Point Blog.

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Insider Threats: Turning 2025 Intelligence into a 2026 Defense Strategy

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Insider Threats: Turning 2025 Intelligence into a 2026 Defense Strategy

In this post, we break down the 91,321 instances of insider activity observed by Flashpoint™ in 2025, examine the top five cases that defined the year, and provide the technical and behavioral red flags your team needs to monitor in 2026.

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January 15, 2026

Every organization houses sensitive assets that threat actors actively seek. Whether it is proprietary trade secrets, intellectual property, or the personally identifiable information (PII) of employees and customers, these datasets are the lifeblood of the modern enterprise—and highly lucrative commodities within the illicit underground.

In 2025, Flashpoint observed 91,321 instances of insider recruiting, advertising, and threat actor discussions involving insider-related illicit activity. This underscores a critical reality—it is far more efficient for threat actors to recruit an “insider” to circumvent multi-million dollar security stacks than it is to develop a complex exploit from the outside. 

An insider threat, any individual with authorized access, possesses the unique ability to bypass traditional security gates. Whether driven by financial gain, ideological grievances, or simple human error, insiders can potentially compromise a system with a single keystroke. To protect our customers from this internal risk, Flashpoint monitors the illicit forums and marketplaces where these threats are being solicited. 

In this post, we unpack the evolving insider threat landscape and what it means for your security strategy in 2026. By analyzing the volume of recruitment activity and the specific industries being targeted, organizations can move from a reactive posture to a proactive defense.

By the Numbers: Mapping the 2025 Insider Threat Landscape

Last year, Flashpoint collected and researched:

  • 91,321 posts of insider solicitation and service advertising
  • 10,475 channels containing insider-related illicit activity
  • 17,612 total authors

On average, 1,162 insider-related posts were published per month, with Telegram continuing to be one of the most prominent mediums for insiders and threat actors to identify and collaborate with each other. Analysts also identified instances of extortionist groups targeting employees at organizations to financially motivate them to become insiders.

Insider Threat Landscape by Industry

The telecommunications industry observed the most insider-related activity in 2025. This is due to the industry’s central role in identity verification and its status as the primary target for SIM swapping—a fraudulent technique where threat actors convince employees of a mobile carrier to link a victim’s phone number to a SIM card controlled by the attacker. This allows the threat actor to receive all the victim’s calls and texts, allowing them to bypass SMS-based two-factor authentication.

Insider Threat data from January 1, 2025 to November 24, 2025

Flashpoint analysts identified 12,783 notable posts where the level of detail or the specific target was particularly concerning.

Top Industries for Insiders Advertising Services (Supply):

  1. Telecom
  2. Financial
  3. Retail
  4. Technology

Top Industries for Threat Actors Soliciting Access (Demand):

  1. Technology
  2. Financial
  3. Telecom
  4. Retail

6 Notable Insider Threat Cases of 2025

The following cases highlight the variety of ways insiders impacted enterprise systems this year, ranging from intentional fraud to massive technical oversights.

Type of IncidentDescription
MaliciousApproximately nine employees accessed the personal information of over 94,000 individuals, making illegal purchases using changed food stamp cards.   
NonmaliciousAn unprotected database belonging to a Chinese IoT firm leaked 2.7 billion records, exposing 1.17 TB of sensitive data and plaintext passwords. 
MaliciousAn insider at a well-known cybersecurity organization was terminated after sharing screenshots of internal dashboards with the Scattered Lapsus$ Hunters threat actor group.
MaliciousAn employee working for a foreign military contractor was bribed to pass confidential information to threat actors.
MaliciousA third-party contractor for a cryptocurrency firm sold customer data to threat actors and recruited colleagues into the scheme, leading to the termination of 300 employees and the compromise of 69,000 customers.
MaliciousTwo contractors accessed and deleted sensitive documents and dozens of databases belonging to the Internal Revenue Service and US General Services Administration.

Catching the Warning Signs Early

Potential insiders often display technical and nontechnical behavior before initiating illicit activity. Although these actions may not directly implicate an employee, they can be monitored, which may lead to inquiries or additional investigations to better understand whether the employee poses an elevated risk to the organization.

Flashpoint has identified the following nontechnical warning signs associated with insiders:

  • Behavioral indicators: Observable actions that deviate from a known baseline of behaviors. These can be observed by coworkers or management or through technical indicators. Behavioral indicators can include increasingly impulsive or erratic behavior, noncompliance with rules and policies, social withdrawal, and communications with competitors.
  • Financial changes: Significant and overlapping changes in financial standing—such as significant debt, financial troubles, or sudden unexplained financial gain—could indicate a potential insider threat. In the case of financial distress, an employee can sell their services to other threat actors via forums or chat services, thus creating additional funding streams while seeming benign within their organization.
  • Abnormal access behavior: Resistance to oversight, unjustified requests for sensitive information beyond the employee’s role, or the employee being overprotective of their access privileges might indicate malicious intent.
  • Separation on bad terms: Employees who leave an organization under unfavorable circumstances pose an increased insider threat risk, as they might want to seek revenge by exploiting whatever access they had or might still possess after leaving.
  • Odd working hours: Actors may leverage atypical after-hours work to pursue insider threat activity, as there is less monitoring. By sticking to an atypical schedule, threat actors maintain a cover of standard work activity while pursuing illicit activity simultaneously.
  • Unusual overseas travel: Unusual and undocumented overseas travel may indicate an employee’s potential recruitment by a foreign state or state-sponsored actor. Travel might be initiated to establish contact and pass sensitive information while avoiding raising suspicions in the recruit’s home country.

The following are technical warning signs:

  • Unauthorized devices: Employees using unauthorized devices for work pose an insider threat, whether they have malicious intent or are simply putting themselves at higher risk of human error. Devices that are not controlled and monitored by the organization fall outside of its scope of operational security, while still carrying all of the sensitive data and configuration of the organization.
  • Abnormal network traffic: An unusual increase in network traffic or unexplained traffic patterns associated with the employee’s device that differ from their normal network activity could indicate malicious intent. This includes network traffic employing unusual protocols, using uncommon ports, or an overall increase in after-hours network activity.
  • Irregular access pattern: Employees accessing data outside the scope of their job function may be testing and mapping the limits of their access privileges to restricted areas of information as they evaluate their exfiltration capabilities for their planned illicit actions.
  • Irregular or mass data download: Unexpected changes in an employee’s data handling practices, such as irregular large-scale downloads, unusual data encryption, or uncharacteristic or unauthorized data destinations, are significant indicators of an insider threat.

Insider Threats: What to Expect in 2026

As 2026 unfolds, insider threat actors will continue to be a major threat to organizations. Ransomware groups and initial access threat actors will continue recruiting interested insiders and exploiting human vulnerabilities through social engineering tactics. Following Telegram’s recent bans on many illicit groups and channels, Flashpoint assesses that threat actors are likely to migrate to different platforms, such as Signal, where encrypted chats make their activity harder to monitor.

As AI technologies continue to advance, organizations will be better equipped to identify and mitigate insider risks. At the same time, threat actors will likely increasingly abuse AI and other tools to access sensitive information. 
Is your organization equipped to spot the warning signs? Request a demo to learn more and to mitigate potential risk from within your organization.

Request a demo today.

The post Insider Threats: Turning 2025 Intelligence into a 2026 Defense Strategy appeared first on Flashpoint.

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AI-powered sextortion: a new threat to privacy | Kaspersky official blog

In 2025, cybersecurity researchers discovered several open databases belonging to various AI image-generation tools. This fact alone makes you wonder just how much AI startups care about the privacy and security of their users’ data. But the nature of the content in these databases is far more alarming.

A large number of generated pictures in these databases were images of women in lingerie or fully nude. Some were clearly created from children’s photos, or intended to make adult women appear younger (and undressed). Finally, the most disturbing part: some pornographic images were generated from completely innocent photos of real people — likely taken from social media.

In this post, we’re talking about what sextortion is, and why AI tools mean anyone can become a victim. We detail the contents of these open databases, and give you advice on how to avoid becoming a victim of AI-era sextortion.

What is sextortion?

Online sexual extortion has become so common it’s earned its own global name: sextortion (a portmanteau of sex and extortion). We’ve already detailed its various types in our post, Fifty shades of sextortion. To recap, this form of blackmail involves threatening to publish intimate images or videos to coerce the victim into taking certain actions, or to extort money from them.

Previously, victims of sextortion were typically adult industry workers, or individuals who’d shared intimate content with an untrustworthy person.

However, the rapid advancement of artificial intelligence, particularly text-to-image technology, has fundamentally changed the game. Now, literally anyone who’s posted their most innocent photos publicly can become a victim of sextortion. This is because generative AI makes it possible to quickly, easily, and convincingly undress people in any digital image, or add a generated nude body to someone’s head in a matter of seconds.

Of course, this kind of fakery was possible before AI, but it required long hours of meticulous Photoshop work. Now, all you need is to describe the desired result in words.

To make matters worse, many generative AI services don’t bother much with protecting the content they’ve been used to create. As mentioned earlier, last year saw researchers discover at least three publicly accessible databases belonging to these services. This means the generated nudes within them were available not just to the user who’d created them, but to anyone on the internet.

How the AI image database leak was discovered

In October 2025, cybersecurity researcher Jeremiah Fowler uncovered an open database containing over a million AI-generated images and videos. According to the researcher, the overwhelming majority of this content was pornographic in nature. The database wasn’t encrypted or password-protected — meaning any internet user could access it.

The database’s name and watermarks on some images led Fowler to believe its source was the U.S.-based company SocialBook, which offers services for influencers and digital marketing services. The company’s website also provides access to tools for generating images and content using AI.

However, further analysis revealed that SocialBook itself wasn’t directly generating this content. Links within the service’s interface led to third-party products — the AI services MagicEdit and DreamPal — which were the tools used to create the images. These tools allowed users to generate pictures from text descriptions, edit uploaded photos, and perform various visual manipulations, including creating explicit content and face-swapping.

The leak was linked to these specific tools, and the database contained the product of their work, including AI-generated and AI-edited images. A portion of the images led the researcher to suspect they’d been uploaded to the AI as references for creating provocative imagery.

Fowler states that roughly 10,000 photos were being added to the database every single day. SocialBook denies any connection to the database. After the researcher informed the company of the leak, several pages on the SocialBook website that had previously mentioned MagicEdit and DreamPal became inaccessible and began returning errors.

Which services were the source of the leak?

Both services — MagicEdit and DreamPal — were initially marketed as tools for interactive, user-driven visual experimentation with images and art characters. Unfortunately, a significant portion of these capabilities were directly linked to creating sexualized content.

For example, MagicEdit offered a tool for AI-powered virtual clothing changes, as well as a set of styles that made images of women more revealing after processing — such as replacing everyday clothes with swimwear or lingerie. Its promotional materials promised to turn an ordinary look into a sexy one in seconds.

DreamPal, for its part, was initially positioned as an AI-powered role-playing chat, and was even more explicit about its adult-oriented positioning. The site offered to create an ideal AI girlfriend, with certain pages directly referencing erotic content. The FAQ also noted that filters for explicit content in chats were disabled so as not to limit users’ most intimate fantasies.

Both services have suspended operations. At the time of writing, the DreamPal website returned an error, while MagicEdit seemed available again. Their apps were removed from both the App Store and Google Play.

Jeremiah Fowler says earlier in 2025, he discovered two more open databases containing AI-generated images. One belonged to the South Korean site GenNomis, and contained 95,000 entries — a substantial portion of which being images of “undressed” people. Among other things, the database included images with child versions of celebrities: American singers Ariana Grande and Beyoncé, and reality TV star Kim Kardashian.

How to avoid becoming a victim

In light of incidents like these, it’s clear that the risks associated with sextortion are no longer confined to private messaging or the exchange of intimate content. In the era of generative AI, even ordinary photos, when posted publicly, can be used to create compromising content.

This problem is especially relevant for women, but men shouldn’t get too comfortable either: the popular blackmail scheme of “I hacked your computer and used the webcam to make videos of you browsing adult sites” could reach a whole new level of persuasion thanks to AI tools for generating photos and videos.

Therefore, protecting your privacy on social media and controlling what data about you is publicly available become key measures for safeguarding both your reputation and peace of mind. To prevent your photos from being used to create questionable AI-generated content, we recommend making all your social media profiles as private as possible — after all, they could be the source of images for AI-generated nudes.

We’ve already published multiple detailed guides on how to reduce your digital footprint online or even remove your data from the internet, how to stop data brokers from compiling dossiers on you, and protect yourself from intimate image abuse.

Additionally, we have a dedicated service, Privacy Checker — perfect for anyone who wants a quick but systematic approach to privacy settings everywhere possible. It compiles step-by-step guides for securing accounts on social media and online services across all major platforms.

And to ensure the safety and privacy of your child’s data, Kaspersky Safe Kids can help: it allows parents to monitor which social media their child spends time on. From there, you can help them adjust privacy settings on their accounts so their posted photos aren’t used to create inappropriate content. Explore our guide to children’s online safety together, and if your child dreams of becoming a popular blogger, discuss our step-by-step cybersecurity guide for wannabe bloggers with them.

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Why Effective CTEM Must be an Intelligence-Led Program

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Why Effective CTEM Must be an Intelligence-Led Program

Continuous Threat Exposure Management (CTEM) is a continuous program and operational framework, not a single pre-boxed platform. Flashpoint believes that effective CTEM must be intelligence-led, using curated threat intelligence as the operational core to prioritize risk and turn exposure data into defensible decisions.

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January 6, 2026

Continuous Threat Exposure Management (CTEM) is Not a Product

Since Gartner’s introduction of CTEM as a framework in 2022, cybersecurity vendors have engaged in a rapid “productization” race. This has led to inconsistent market definitions, with a variety of vendors from vulnerability scanners to Attack Surface Management (ASM) providers now claiming to be an “exposure management” solution.

The current approach to productizing CTEM is flawed. There is no such thing as a single “exposure management platform.” The enterprise reality is that most enterprises buy three or more products just to approximate what CTEM promises in theory. Even with these technologies, organizations still require heavy lifting with people, process, and custom integrations to actually make it work.

The Exposure Stack: When One Platform Becomes Three (or More)

A functional CTEM approach typically requires multiple platforms or tools, including: 

  • Continuous Penetration/Exploitation Testing & Attack Path Analysis for continuous pentesting, attack path validation, and hands-on exposure validation.
  • Vulnerability and Exposure Management for vulnerability scanning, exposure scoring, and asset risk views.
  • Intelligence for deep, curated vulnerability, compromised credentials, card fraud, and other forms of intelligence that goes far beyond the scope of technology-based “management platforms”.

In some cases, organizations may also use an ASM vendor for shadow IT discovery, a CMDB for asset context, and ticketing integrations to drive remediation. This multi-platform model is the rule, not the exception. And that raises a hard truth: if you need three or more products, plus a dedicated team to implement CTEM, you need an intelligence-led CTEM program.

CTEM is an Operational Discipline, Not a Single Product

The narrative that CTEM can be packaged into a single product breaks down for three critical reasons:

1. CTEM is a Program, Not a Platform

You cannot buy a capability that requires full-stack asset visibility, contextualized threat actor data, real-world validation, and remediation orchestration from one tool. Each component spans a different domain of expertise and data. A vulnerability scanner, alone, cannot validate exploitability, a pentest service has a tough time scaling to daily monitoring, and generic threat intelligence feeds cannot provide critical business context.

However, CTEM requires orchestration of all these components in one operational loop. No single product delivers this comprehensively out of the box; this is why CTEM must be viewed as a continuous program, not a one-size-fits-all product.

2. Human Expertise is Irreplaceable

Vendors often advertise automation, however, key intelligence functions are still powered by and reliant on human analysis. Even with best-in-class AI tools in place, security teams are depending on human insights for:

  • Triaging noisy CVE lists
  • Cross-referencing exposure data with asset inventories
  • Manually validating if risks are real
  • Prioritizing based on threat intelligence and internal context
  • Writing custom logic and integrations to bridge platforms together

In other words, exposure management today still relies on human insights and expertise. So while vendors advertise “automation and intelligence,” what they’re really delivering is a starting point. Ultimately, AI is a force multiplier for threat analysts, not a replacement.

3. Risk Without Intelligence Is Just Data

Most platforms treat exposure like a math problem. But real risk isn’t just CVSS (Common Vulnerability Scoring System) scores or asset counts, it requires answering critical, intelligence-based questions:

  1. How likely is this vulnerability to be exploited, and what’s the impact if it is?
  2. How likely is this misconfiguration to be exploited, and what is its impact?
  3. How likely is this compromised credential to be used by a threat actor, and what is the potential impact?

These answers require intelligence, not just data. Best-in-class intelligence provides security teams with confirmed exploit activity in the wild, context around attacker usage in APT (Advanced Persistent Threat) campaigns, and detailed metadata for prioritization where CVSS fails. That is why Flashpoint intelligence is leveraged by over 800 organizations as the operational core of exposure management, turning exposure data into defensible decisions.

CTEM Productization vs. CTEM Reality

If your risk strategy requires continuous penetration and exploit testing, vulnerability management, threat intelligence, and manual prioritization and validation, you’re not buying CTEM; you’re building it. At Flashpoint, we’re helping organizations build CTEM the right way: driven by intelligence, and powered by integrations and AI.

The Intelligence-Led Future of Exposure Management

Flashpoint treats CTEM for what it really is, as a program that must be constructed intelligently, iteratively, and contextually.

That means:

  • Using threat and vulnerability intelligence to drive what actually gets prioritized
  • Treating scanners, ASM platforms, and pentesting as inputs, not outcomes
  • Building processes where intelligence, context, and validation inform exposure decisions, not just ticket creation
  • Investing in platform interconnectivity, not just feature checklists

Using Flashpoint’s intelligence collections, organizations can achieve intelligence-led exposure management, with threat and vulnerability intelligence working together to provide context and actionable insights in a continuous, prioritized loop. This empowers security teams to build and scale their own CTEM programs, which is the only realistic approach in a cybersecurity landscape where no single platform can do it all.

Achieve Elite Operation Control Over Your CTEM Program Using Flashpoint

If you’re evaluating exposure management tools, ask yourself:

  • What happens when we find a critical vulnerability and how do we know it matters?
  • Can this platform correlate attacker behavior with our asset landscape?
  • Does it validate risk or just report it?
  • How many other tools will we need to buy just to complete the picture?

The answers may surprise you. At Flashpoint, we’re helping organizations build CTEM the right way, driven by intelligence, powered by integration, and grounded in reality. Request a demo today and see how best-in-class intelligence is the key to achieving an effective CTEM program.

Request a demo today.

The post Why Effective CTEM Must be an Intelligence-Led Program appeared first on Flashpoint.

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Check Point Secures AI Factories with NVIDIA

As businesses and service providers deploy AI tools and systems, having strong cyber security across the entire AI pipeline is a foundational requirement, from design to deployment. Even at this stage of AI adoption, attacks on AI infrastructure and prompt-based manipulation are gaining traction. Per a recent Gartner report, 32% of organizations have already experienced an AI attack involving prompt manipulation, while 29% faced attacks on their GenAI infrastructure in the past year. Nearly 70% of cyber security leaders said emerging GenAI risks demand significant changes to existing cyber security approaches. And a recent Lakera survey found that only 19% of organizations […]

The post Check Point Secures AI Factories with NVIDIA appeared first on Check Point Blog.

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Justice Department Announces Actions to Combat Two Russian State-Sponsored Cyber Criminal Hacking Groups

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Justice Department Announces Actions to Combat Two Russian State-Sponsored Cyber Criminal Hacking Groups

Ukrainian national indicted and rewards announced for co-conspirators relating to destructive cyberattacks worldwide.

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January 5, 2026

“The Justice Department announced two indictments in the Central District of California charging Ukrainian national Victoria Eduardovna Dubranova, 33, also known as Vika, Tory, and SovaSonya, for her role in conducting cyberattacks and computer intrusions against critical infrastructure and other victims around the world, in support of Russia’s geopolitical interests. Dubranova was extradited to the United States earlier this year on an indictment charging her for her actions supporting CyberArmyofRussia_Reborn (CARR). Today, Dubranova was arraigned on a second indictment charging her for her actions supporting NoName057(16) (NoName). Dubranova pleaded not guilty in both cases, and is scheduled to begin trial in the NoName matter on Feb. 3, 2026 and in the CARR matter on April 7, 2026.”

“As described in the indictments, the Russian government backed CARR and NoName by providing, among other things, financial support. CARR used this financial support to access various cybercriminal services, including subscriptions to distributed denial of service-for-hire services. NoName was a state-sanctioned project administered in part by an information technology organization established by order of the President of Russia in October 2018 that developed, along with other co-conspirators, NoName’s proprietary distributed denial of service (DDoS) program.”

Cyber Army of Russia Reborn

“According to the indictment, CARR, also known as Z-Pentest, was founded, funded, and directed by the Main Directorate of the General Staff of the Armed Forces of the Russian Federation (GRU). CARR claimed credit for hundreds of cyberattacks against victims worldwide, including attacks against critical infrastructure in the United States, in support of Russia’s geopolitical interests. CARR regularly posted on Telegram claiming credit for its attacks and published photos and videos depicting its attacks. CARR primarily hacked industrial control facilities and conducted DDoS attacks. CARR’s victims included public drinking water systems across several states in the U.S., resulting in damage to controls and the spilling of hundreds of thousands of gallons of drinking water. CARR also attacked a meat processing facility in Los Angeles in November 2024, spoiling thousands of pounds of meat and triggering an ammonia leak in the facility. CARR has attacked U.S. election infrastructure during U.S. elections, and websites for U.S. nuclear regulatory entities, among other sensitive targets.”

“An individual operating as ‘Cyber_1ce_Killer,’ a moniker associated with at least one GRU officer instructed CARR leadership on what kinds of victims CARR should target, and his organization financed CARR’s access to various cybercriminal services, including subscriptions to DDoS-for-hire services. At times, CARR had more than 100 members, including juveniles, and more than 75,000 followers on Telegram.”

NoName057(16)

“NoName was covert project whose membership included multiple employees of The Center for the Study and Network Monitoring of the Youth Environment (CISM), among other cyber actors. CISM was an information technology organization established by order of the President of Russia in October 2018 that purported to, among other things, monitor the safety of the internet for Russian youth.”

“According to the indictment, NoName claimed credit for hundreds of cyberattacks against victims worldwide in support of Russia’s geopolitical interests. NoName regularly posted on Telegram claiming credit for its attacks and published proof of victim websites being taken offline. The group primarily conducted DDoS cyberattacks using their own proprietary DDoS tool, DDoSia, which relied on network infrastructure around the world created by employees of CISM.”

“NoName’s victims included government agencies, financial institutions, and critical infrastructure, such as public railways and ports. NoName recruited volunteers from around the world to download DDoSia and used their computers to launch DDoS attacks on the victims that NoName leaders selected. NoName also published a daily leaderboard of volunteers who launched the most DDoS attacks on its Telegram channel and paid top-ranking volunteers in cryptocurrency for their attacks.” (Source: US Department of Justice)

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The post Justice Department Announces Actions to Combat Two Russian State-Sponsored Cyber Criminal Hacking Groups appeared first on Flashpoint.

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Flashpoint Weekly Vulnerability Insights and Prioritization Report

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Flashpoint Weekly Vulnerability Insights and Prioritization Report

Week of December 20 – December 26, 2025

Anticipate, contextualize, and prioritize vulnerabilities to effectively address threats to your organization.

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December 31, 2025

Flashpoint’s VulnDB™ documents over 400,000 vulnerabilities and has over 6,000 entries in Flashpoint’s KEV database, making it a critical resource as vulnerability exploitation rises. However, if your organization is relying solely on CVE data, you may be missing critical vulnerability metadata and insights that hinder timely remediation. That’s why we created this weekly series—where we surface and analyze the most high priority vulnerabilities security teams need to know about.

Key Vulnerabilities:
Week of December 20 – December 26, 2025

Foundational Prioritization

Of the vulnerabilities Flashpoint published this week, there are 34 that you can take immediate action on. They each have a solution, a public exploit exists, and are remotely exploitable. As such, these vulnerabilities are a great place to begin your prioritization efforts.

Diving Deeper – Urgent Vulnerabilities

Of the vulnerabilities Flashpoint published last week, four are highlighted in this week’s Vulnerability Insights and Prioritization Report because they contain one or more of the following criteria:

  • Are in widely used products and are potentially enterprise-affecting
  • Are exploited in the wild or have exploits available
  • Allow full system compromise
  • Can be exploited via the network alone or in combination with other vulnerabilities
  • Have a solution to take action on

In addition, all of these vulnerabilities are easily discoverable and therefore should be investigated and fixed immediately.

To proactively address these vulnerabilities and ensure comprehensive coverage beyond publicly available sources on an ongoing basis, organizations can leverage Flashpoint Vulnerability Intelligence. Flashpoint provides comprehensive coverage encompassing IT, OT, IoT, CoTs, and open-source libraries and dependencies. It catalogs over 100,000 vulnerabilities that are not included in the NVD or lack a CVE ID, ensuring thorough coverage beyond publicly available sources. The vulnerabilities that are not covered by the NVD do not yet have CVE ID assigned and will be noted with a VulnDB ID.

CVE IDTitleCVSS Scores (v2, v3, v4)Exploit StatusExploit ConsequenceRansomware Likelihood ScoreSocial Risk ScoreSolution Availability
CVE-2025-33222NVIDIA Isaac Launchable Unspecified Hardcoded Credentials5.0
9.8
9.3
PrivateCredential DisclosureHighLowYes
CVE-2025-33223NVIDIA Isaac Launchable Unspecified Improper Execution Privileges Remote Code Execution10.0
9.8
9.3
PrivateRemote Code ExecutionHighLowYes
CVE-2025-68613n8n Package for Node.js packages/workflow/src/expression-evaluator-proxy.ts Workflow Expression Evaluation Remote Code Execution9.0
9.9
9.4
PublicRemote Code ExecutionHighHighYes
CVE-2025-14847MongoDB transport/message_compressor_zlib.cpp ZlibMessageCompressor::decompressData() Function Zlib Compressed Protocol Header Handling Remote Uninitialized Memory Disclosure (Mongobleed)10.0
9.8
9.3
PublicUninitialized Memory DisclosureHighHighYes
Scores as of: December 30, 2025

NOTES: The severity of a given vulnerability score can change whenever new information becomes available. Flashpoint maintains its vulnerability database with the most recent and relevant information available. Login to view more vulnerability metadata and for the most up-to-date information.

CVSS scores: Our analysts calculate, and if needed, adjust NVD’s original CVSS scores based on new information being available.

Social Risk Score: Flashpoint estimates how much attention a vulnerability receives on social media. Increased mentions and discussions elevate the Social Risk Score, indicating a higher likelihood of exploitation. The score considers factors like post volume and authors, and decreases as the vulnerability’s relevance diminishes.

Ransomware Likelihood: This score is a rating that estimates the similarity between a vulnerability and those known to be used in ransomware attacks. As we learn more information about a vulnerability (e.g. exploitation method, technology affected) and uncover additional vulnerabilities used in ransomware attacks, this rating can change.

Flashpoint Ignite lays all of these components out. Below is an example of what this vulnerability record for CVE-2025-33223 looks like.



This record provides additional metadata like affected product versions, MITRE ATT&CK mapping, analyst notes, solution description, classifications, vulnerability timeline and exposure metrics, exploit references and more.

Analyst Comments on the Notable Vulnerabilities

Below, Flashpoint analysts describe the five vulnerabilities highlighted above as vulnerabilities that should be of focus for remediation if your organization is exposed.

CVE-2025-33222

NVIDIA Isaac Launchable contains a flaw that is triggered by the use of unspecified hardcoded credentials. This may allow a remote attacker to trivially gain privileged access to the program.

CVE-2025-33223

NVIDIA Isaac Launchable contains an unspecified flaw that is triggered as certain activities are executed with unnecessary privileges. This may allow a remote attacker to potentially execute arbitrary code.

CVE-2025-68613

n8n Package for Node.js contains a flaw in packages/workflow/src/expression-evaluator-proxy.ts that is triggered as workflow expressions are evaluated in an improperly isolated execution context. This may allow an authenticated, remote attacker to execute arbitrary code with the privileges of the n8n process.

CVE-2025-14847

MongoDB contains a flaw in the ZlibMessageCompressor::decompressData() function in mongo/transport/message_compressor_zlib.cpp that is triggered when handling mismatched length fields in Zlib compressed protocol headers. This may allow a remote attacker to disclose uninitialized memory contents on the heap.

Previously Highlighted Vulnerabilities

CVE/VulnDB IDFlashpoint Published Date
CVE-2025-21218Week of January 15, 2025
CVE-2024-57811Week of January 15, 2025
CVE-2024-55591Week of January 15, 2025
CVE-2025-23006Week of January 22, 2025
CVE-2025-20156Week of January 22, 2025
CVE-2024-50664Week of January 22, 2025
CVE-2025-24085Week of January 29, 2025
CVE-2024-40890Week of January 29, 2025
CVE-2024-40891Week of January 29, 2025
VulnDB ID: 389414Week of January 29, 2025
CVE-2025-25181Week of February 5, 2025
CVE-2024-40890Week of February 5, 2025
CVE-2024-40891Week of February 5, 2025
CVE-2024-8266Week of February 12, 2025
CVE-2025-0108Week of February 12, 2025
CVE-2025-24472Week of February 12, 2025
CVE-2025-21355Week of February 24, 2025
CVE-2025-26613Week of February 24, 2025
CVE-2024-13789Week of February 24, 2025
CVE-2025-1539Week of February 24, 2025
CVE-2025-27364Week of March 3, 2025
CVE-2025-27140Week of March 3, 2025
CVE-2025-27135Week of March 3, 2025
CVE-2024-8420Week of March 3, 2025
CVE-2024-56196Week of March 10, 2025
CVE-2025-27554Week of March 10, 2025
CVE-2025-22224Week of March 10, 2025
CVE-2025-1393Week of March 10, 2025
CVE-2025-24201Week of March 17, 2025
CVE-2025-27363Week of March 17, 2025
CVE-2025-2000Week of March 17, 2025
CVE-2025-27636
CVE-2025-29891
Week of March 17, 2025
CVE-2025-1496
Week of March 24, 2025
CVE-2025-27781Week of March 24, 2025
CVE-2025-29913Week of March 24, 2025
CVE-2025-2746Week of March 24, 2025
CVE-2025-29927Week of March 24, 2025
CVE-2025-1974 CVE-2025-2787Week of March 31, 2025
CVE-2025-30259Week of March 31, 2025
CVE-2025-2783Week of March 31, 2025
CVE-2025-30216Week of March 31, 2025
CVE-2025-22457Week of April 2, 2025
CVE-2025-2071Week of April 2, 2025
CVE-2025-30356Week of April 2, 2025
CVE-2025-3015Week of April 2, 2025
CVE-2025-31129Week of April 2, 2025
CVE-2025-3248Week of April 7, 2025
CVE-2025-27797Week of April 7, 2025
CVE-2025-27690Week of April 7, 2025
CVE-2025-32375Week of April 7, 2025
VulnDB ID: 398725Week of April 7, 2025
CVE-2025-32433Week of April 12, 2025
CVE-2025-1980Week of April 12, 2025
CVE-2025-32068Week of April 12, 2025
CVE-2025-31201Week of April 12, 2025
CVE-2025-3495Week of April 12, 2025
CVE-2025-31324Week of April 17, 2025
CVE-2025-42599Week of April 17, 2025
CVE-2025-32445Week of April 17, 2025
VulnDB ID: 400516Week of April 17, 2025
CVE-2025-22372Week of April 17, 2025
CVE-2025-32432Week of April 29, 2025
CVE-2025-24522Week of April 29, 2025
CVE-2025-46348Week of April 29, 2025
CVE-2025-43858Week of April 29, 2025
CVE-2025-32444Week of April 29, 2025
CVE-2025-20188Week of May 3, 2025
CVE-2025-29972Week of May 3, 2025
CVE-2025-32819Week of May 3, 2025
CVE-2025-27007Week of May 3, 2025
VulnDB ID: 402907Week of May 3, 2025
VulnDB ID: 405228Week of May 17, 2025
CVE-2025-47277Week of May 17, 2025
CVE-2025-34027Week of May 17, 2025
CVE-2025-47646Week of May 17, 2025
VulnDB ID: 405269Week of May 17, 2025
VulnDB ID: 406046Week of May 19, 2025
CVE-2025-48926Week of May 19, 2025
CVE-2025-47282Week of May 19, 2025
CVE-2025-48054Week of May 19, 2025
CVE-2025-41651Week of May 19, 2025
CVE-2025-20289Week of June 3, 2025
CVE-2025-5597Week of June 3, 2025
CVE-2025-20674Week of June 3, 2025
CVE-2025-5622Week of June 3, 2025
CVE-2025-5419Week of June 3, 2025
CVE-2025-33053Week of June 7, 2025
CVE-2025-5353Week of June 7, 2025
CVE-2025-22455Week of June 7, 2025
CVE-2025-43200Week of June 7, 2025
CVE-2025-27819Week of June 7, 2025
CVE-2025-49132Week of June 13, 2025
CVE-2025-49136Week of June 13, 2025
CVE-2025-50201Week of June 13, 2025
CVE-2025-49125Week of June 13, 2025
CVE-2025-24288Week of June 13, 2025
CVE-2025-6543Week of June 21, 2025
CVE-2025-3699Week of June 21, 2025
CVE-2025-34046Week of June 21, 2025
CVE-2025-34036Week of June 21, 2025
CVE-2025-34044Week of June 21, 2025
CVE-2025-7503Week of July 12, 2025
CVE-2025-6558Week of July 12, 2025
VulnDB ID: 411705Week of July 12, 2025
VulnDB ID: 411704Week of July 12, 2025
CVE-2025-6222Week of July 12, 2025
CVE-2025-54309Week of July 18, 2025
CVE-2025-53771Week of July 18, 2025
CVE-2025-53770Week of July 18, 2025
CVE-2025-54122Week of July 18, 2025
CVE-2025-52166Week of July 18, 2025
CVE-2025-53942Week of July 25, 2025
CVE-2025-46811Week of July 25, 2025
CVE-2025-52452Week of July 25, 2025
CVE-2025-41680Week of July 25, 2025
CVE-2025-34143Week of July 25, 2025
CVE-2025-50454Week of August 1, 2025
CVE-2025-8875Week of August 1, 2025
CVE-2025-8876Week of August 1, 2025
CVE-2025-55150Week of August 1, 2025
CVE-2025-25256Week of August 1, 2025
CVE-2025-43300Week of August 16, 2025
CVE-2025-34153Week of August 16, 2025
CVE-2025-48148Week of August 16, 2025
VulnDB ID: 416058Week of August 16, 2025
CVE-2025-32992Week of August 16, 2025
CVE-2025-7775Week of August 24, 2025
CVE-2025-8424Week of August 24, 2025
CVE-2025-34159Week of August 24, 2025
CVE-2025-57819Week of August 24, 2025
CVE-2025-7426Week of August 24, 2025
CVE-2025-58367Week of September 1, 2025
CVE-2025-58159Week of September 1, 2025
CVE-2025-58048Week of September 1, 2025
CVE-2025-39247Week of September 1, 2025
CVE-2025-8857Week of September 1, 2025
CVE-2025-58321Week of September 8, 2025
CVE-2025-58366Week of September 8, 2025
CVE-2025-58371Week of September 8, 2025
CVE-2025-55728Week of September 8, 2025
CVE-2025-55190Week of September 8, 2025
VulnDB ID: 419253Week of September 13, 2025
CVE-2025-10035Week of September 13, 2025
CVE-2025-59346Week of September 13, 2025
CVE-2025-55727Week of September 13, 2025
CVE-2025-10159Week of September 13, 2025
CVE-2025-20363Week of September 20, 2025
CVE-2025-20333Week of September 20, 2025
CVE-2022-4980Week of September 20, 2025
VulnDB ID: 420451Week of September 20, 2025
CVE-2025-9900Week of September 20, 2025
CVE-2025-52906Week of September 27, 2025
CVE-2025-51495Week of September 27, 2025
CVE-2025-27224Week of September 27, 2025
CVE-2025-27223Week of September 27, 2025
CVE-2025-54875Week of September 27, 2025
CVE-2025-41244Week of September 27, 2025
CVE-2025-61928Week of October 6, 2025
CVE-2025-61882Week of October 6, 2025
CVE-2025-49844Week of October 6 2025
CVE-2025-57870Week of October 6, 2025
CVE-2025-34224Week of October 6, 2025
CVE-2025-34222Week of October 6, 2025
CVE-2025-40765Week of October 11, 2025
CVE-2025-59230Week of October 11, 2025
CVE-2025-24990Week of October 11, 2025
CVE-2025-61884Week of October 11, 2025
CVE-2025-41430Week of October 11, 2025
VulnDB ID: 424051Week of October 18, 2025
CVE-2025-62645Week of October 18, 2025
CVE-2025-61932Week of October 18, 2025
CVE-2025-59503Week of October 18, 2025
CVE-2025-43995Week of October 18, 2025
CVE-2025-62168Week of October 18, 2025
VulnDB ID: 425182Week of October 25, 2025
CVE-2025-62713Week of October 25, 2025
CVE-2025-54964Week of October 25, 2025
CVE-2024-58274Week of October 25, 2025
CVE-2025-41723Week of October 25, 2025
CVE-2025-20354Week of November 1, 2025
CVE-2025-11953Week of November 1, 2025
CVE-2025-60854Week of November 1, 2025
CVE-2025-64095Week of November 1, 2025
CVE-2025-11833Week of November 1, 2025
CVE-2025-64446Week of November 8, 2025
CVE-2025-36250Week of November 8, 2025
CVE-2025-64400Week of November 8, 2025
CVE-2025-12686Week of November 8, 2025
CVE-2025-59118Week of November 8, 2025
VulnDB ID: 426231Week of November 8, 2025
VulnDB ID: 427979Week of November 22, 2025
CVE-2025-55796Week of November 22, 2025
CVE-2025-64428Week of November 22, 2025
CVE-2025-62703Week of November 22, 2025
VulnDB ID: 428193Week of November 22, 2025
CVE-2025-65018Week of November 22, 2025
CVE-2025-54347Week of November 22, 2025
CVE-2025-55182Week of November 29, 2025
CVE-2024-14007Week of November 29, 2025
CVE-2025-66399Week of November 29, 2025
CVE-2022-35420Week of November 29, 2025
CVE-2025-66516Week of November 29, 2025
CVE-2025-59366Week of November 29, 2025
CVE-2025-14174Week of December 6, 2026
CVE-2025-43529Week of December 6, 2026
CVE-2025-8110Week of December 6, 2026
CVE-2025-59719Week of December 6, 2026
CVE-2025-59718Week of December 6, 2026
CVE-2025-14087Week of December 6, 2026
CVE-2025-62221Week of December 6, 2026

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The Infostealer Gateway: Uncovering the Latest Methods in Defense Evasion

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The Infostealer Gateway: Uncovering the Latest Methods in Defense Evasion

In this post, we analyze the evolving bypass tactics threat actors are using to neutralize traditional security perimeters and fuel the global surge in infostealer infections.

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December 22, 2025

Infostealer-driven credential theft in 2025 has surged, with Flashpoint observing a staggering 800% increase since the start of the year. With over 1.8 billion corporate and personal accounts compromised, the threat landscape finds itself in a paradox: while technical defenses have never been more advanced, the human attack surface has never been more vulnerable.

Information-stealing malware has become the most scalable entry point for enterprise breaches, but to truly defend against them, organizations must look beyond the malware itself. As teams move into 2026 security planning, it is critical to understand the deceptive initial access vectors—the latest tactics Flashpoint is seeing in the wild—that threat actors are using to manipulate users and bypass modern security perimeters.

Here are the latest methods threat actors are leveraging to facilitate infections:

1. Neutralizing Mark of the Web (MotW) via Drag-and-Drop Lures

Mark of the Web (MotW) is a critical Windows defense feature that tags files downloaded from the internet as “untrusted” by adding a hidden NTFS Alternate Data Stream (ADS) to the file. This tag triggers “Protected View” in Microsoft Office programs and prompts Windows SmartScreen warnings when a user attempts to execute an unknown file.

Flashpoint has observed a new social engineering method to bypass these protections through a simple drag-and-drop lure. Instead of asking a user to open a suspicious attachment directly, which would trigger an immediate MotW warning, threat actors are instead instructing the victim to drag the malicious image or file from a document onto their desktop to view it. This manual interaction is highly effective for two reasons:

  1. Contextual Evasion: By dragging the file out of the document and onto the desktop, the file is executed outside the scope of the Protected View sandbox.
  2. Metadata Stripping: In many instances, the act of dragging and dropping an embedded object from a parent document can cause the operating system to treat the newly created file as a local creation, rather than an internet download. This effectively strips the MotW tag and allows malicious code to run without any security alerts.

2. Executing Payloads via Vulnerabilities and Trusted Processes

Flashpoint analysts uncovered an illicit thread detailing a proof of concept for a client-side remote code execution (RCE) in the Google Web Designer for Windows, which was first discovered by security researcher Bálint Magyar.

Google Web Designer is an application used for creating dynamic ads for the Google Ads platform. Leveraging this vulnerability, attackers would be able to perform remote code execution through an internal API using CSS injection by targeting a configuration file related to ads documents.

Within this thread, threat actors were specifically interested in the execution of the payload using the chrome.exe process. This is because using chrome.exe to fetch and execute a file is likely to bypass several security restrictions as Chrome is already a trusted process. By utilizing specific command-line arguments, such as the –headless flag, threat actors showed how to force a browser to initiate a remote connection in the background without spawning a visible window. This can be used in conjunction with other malicious scripts to silently download additional payloads onto a victim’s systems.

3. Targeting Alternative Softwares as a Path of Least Resistance

As widely-used software becomes more hardened and secure, threat actors are instead pivoting to targeting lesser-known alternatives. These tools often lack robust macro-protections. By targeting vulnerabilities in secondary PDF viewers or Office alternatives, attackers are seeking to trick users into making remote server connections that would otherwise be flagged as suspicious.

Understanding the Identity Attack Surface

Social engineering is one of the driving factors behind the infostealer lifecycle. Once an initial access vector is successful, the malware immediately begins harvesting the logs that fuel today’s identity-based digital attacks.

As detailed in The Proactive Defender’s Guide to Infostealers, the end goal is not just a password. Instead, attackers are prioritizing session cookies, which allow them to perform session hijacking. By importing these stolen cookies into anti-detect browsers, they bypass Multi-Factor Authentication and step directly into corporate environments, appearing as a legitimate, authenticated user.

Understanding how threat actors weaponize stolen data is the first step toward a proactive defense. For a deep dive into the most prolific stealer strains and strategies for managing the identity attack surface, download The Proactive Defender’s Guide to Infostealers today.

Request a demo today.

The post The Infostealer Gateway: Uncovering the Latest Methods in Defense Evasion appeared first on Flashpoint.

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Surfacing Threats Before They Scale: Why Primary Source Collection Changes Intelligence

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Surfacing Threats Before They Scale: Why Primary Source Collection Changes Intelligence

This blog explores how Primary Source Collection (PSC) enables intelligence teams to surface emerging fraud and threat activity before it reaches scale.

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December 19, 2025

Spend enough time investigating fraud and threat activity, and a familiar pattern emerges. Before a tactic shows up at scale—before credential stuffing floods login pages or counterfeit checks hit customers—there is almost always a quieter formation phase. Threat actors test ideas, trade techniques, and refine playbooks in small, often closed communities before launching coordinated campaigns.

The signals are there. The challenge is that most organizations never see them.

For years, intelligence programs have leaned heavily on static feeds: prepackaged streams of indicators, alerts, and reports delivered on a fixed cadence. These feeds validate what is already known, but they rarely surface what is still taking shape. They are designed to summarize activity after it has matured, not to discover it while it is still evolving.

Meanwhile, the real innovation in fraud and threat ecosystems happens elsewhere in invite-only Telegram channels, dark web marketplaces, and regional-language forums that update in real time. By the time a static feed flags a new technique, it is often already widespread.

This disconnect has consequences. When intelligence arrives too late, teams are left responding to impact rather than shaping outcomes.

How Threats Actually Evolve

Fraudsters and threat actors do not work in isolation, they collaborate. In closed forums and encrypted channels, one actor experiments with a new login bypass, another tests two-factor authentication evasion, and a third packages those ideas into a tool or service. What begins as a handful of screenshots or code snippets quickly becomes a repeatable process.

These shared processes often take the form of playbooks that act as step-by-step guides that document how to execute a fraud scheme or exploit a weakness. Once a playbook begins circulating, scale is inevitable. Techniques that started as limited tests turn into thousands of coordinated attempts almost overnight.

Every intelligence or fraud analyst has experienced the moment when an unfamiliar tactic suddenly overwhelms detection systems. The frustrating reality is that the warning signs were often visible weeks earlier, they simply never made it into the static feeds teams were relying on.

Why Static Collection Falls Short

Static collection creates a sense of coverage, but that coverage is often shallow. Sources are fixed. Cadence is slow. Context is stripped away.

A feed might tell you that a domain, handle, or email address is associated with a known tactic, but not how that tactic was developed, who is promoting it, or whether it has any relevance to your organization’s specific exposure. You are seeing the exhaust, not the engine.

This lag matters. The window between a tactic being tested in a small community and being deployed at scale is often the most valuable moment for intervention. Miss that window, and response becomes exponentially more expensive.

As threats accelerate and collaboration among adversaries increases, intelligence programs that depend solely on static inputs struggle to keep pace.

A Different Model: Primary Source Collection

Primary Source Collection (PSC) changes how intelligence is gathered by starting with the questions that matter most and collecting directly from the original environments where those answers exist.

Rather than relying on a predefined list of sources or vendor-determined priorities, PSC begins with a defined intelligence requirement. Collection is then shaped around that requirement, directing analysts to the forums, marketplaces, and channels where relevant activity is actively unfolding.

This means monitoring closed communities advertising check alteration services. It means observing invite-only groups trading identity fraud tutorials. It means collecting original posts, screenshots, files, and discussions while they are still part of an active conversation instead of weeks later in summarized form. When actors begin discussing a new bypass technique or sharing proof-of-concept screenshots, that is the moment to act, not weeks later when the same method is being resold across marketplaces.

Primary Source Collection provides that window. It surfaces the conversations, artifacts, and early indicators that reveal what is coming next and gives teams the time they need to intervene before campaigns scale.

This does not replace analytics, automation, or baseline monitoring. It strengthens them by feeding earlier, richer insight into downstream systems. It ensures that detection and response are informed by how threats are actually developing, not just how they appear after the fact.

In one case, a financial institution using this approach identified counterfeit checks featuring its brand being advertised in underground marketplaces weeks before customers began reporting losses. By collecting directly from those spaces, analysts flagged the images, traced sellers, and alerted internal teams early enough to prevent further exploitation.

That is what early warning looks like when collection is aligned with purpose.

Making Intelligence Taskable

One of the most important shifts enabled by Primary Source Collection is tasking.

Traditional intelligence programs operate like autopilot. They deliver a steady stream of data, but that stream reflects the provider’s priorities rather than the organization’s evolving needs. Analysts spend valuable time triaging irrelevant information while emerging risks go unnoticed.

In classified intelligence environments, this problem has long been addressed through tasking. Every collection effort begins with a clearly defined requirement and priorities drive collection, not the other way around.

PSC applies that same discipline to open-source and commercial intelligence. Teams define Priority Intelligence Requirements (PIRs), such as identifying actors testing bypass methods for specific login flows, and immediately direct collection toward those needs. As priorities change, tasking changes with them.

This transforms intelligence from a passive stream into an operational capability. Analysts are no longer waiting for someone else’s update cycle. They are shaping visibility in real time, testing hypotheses, validating concerns, and uncovering tactics before they mature.

For leadership, this provides something more valuable than indicators: confidence that critical developments are not happening just out of sight.

How Taskable Collection Works in Practice

A taskable Primary Source Collection framework is dynamic by design. As stakeholder priorities shift due to a new campaign, incident, or geopolitical development, collection pivots immediately.

In practice, this approach includes:

  • Source discovery: Identifying new, relevant sources as they emerge, using a combination of analyst expertise and automated tooling.
  • Secure access: Entering closed or restricted spaces safely and ethically through controlled environments and vetted identities.
  • Direct collection: Capturing original content directly from threat actor environments, including posts, images, and files.
  • Processing and enrichment: Applying techniques such as optical character recognition, entity extraction, and metadata tagging to transform raw material into usable intelligence.
  • Delivery and collaboration: Routing outputs into investigative workflows or directly to stakeholders to accelerate response.

Intelligence can then mirror the agility of modern threats instead of lagging behind them.

Why This Shift Matters Now

Threat and fraud operations are moving faster than ever. Barriers to entry are lower. Tooling is more accessible. Collaboration rivals legitimate software development cycles.

Defenders cannot afford to move slower than the adversaries they are trying to stop.

Primary Source Collection is how intelligence teams keep pace. It aligns collection with mission needs, enables real-time tasking, and delivers insight early enough to change outcomes instead of just documenting them.

The signals have always been there. What has changed is the ability to surface them while they still matter.

See Primary Source Collection in Action

Flashpoint supports intelligence teams across fraud, cyber, and executive protection with taskable, primary source intelligence. Request a walkthrough to see how PSC enables earlier, more confident decision-making.

Request a demo today.

The post Surfacing Threats Before They Scale: Why Primary Source Collection Changes Intelligence appeared first on Flashpoint.

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The Curious Case of the Comburglar

By Troy Wojewoda During a recent Breach Assessment engagement, BHIS discovered a highly stealthy and persistent intrusion technique utilized by a threat actor to maintain Command-and-Control (C2) within the client’s […]

The post The Curious Case of the Comburglar appeared first on Black Hills Information Security, Inc..

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The CTI Analyst’s Isolated Arsenal: Desktop Tools for High-Risk Intelligence

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The CTI Analyst’s Isolated Arsenal: Desktop Tools for High-Risk Intelligence

This blog explores how CTI teams safely analyze high-risk environments, engage with threat actors, and process sensitive data using Flashpoint Managed Attribution.

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December 16, 2025

Cyber Threat Intelligence (CTI) analysts routinely operate in high-risk digital spaces where threat actors operate, such as Dark Web forums, encrypted chat rooms, and sites hosting massive breached datasets. Engaging with this data requires absolute confidence that your operational security (OPSEC) is up-to-date.

OPSEC failures can have significant consequences. A single attribution error or host-machine exposure can put both the analyst at risk, and compromise the organization’s security posture. To ensure your organization’s CTI activities remain anonymous, secure, and effective, this post focuses on two essentials: 

  • The types of desktop applications and tools that must run in a secure, isolated environment
  • How Flashpoint Managed Attribution (MA) provides the operational foundation for safe CTI workflows.

OPSEC & Access

Successful execution of CTI operations hinges on establishing a complete shield between the analyst and the target environment. These tools form the base layer for secure and anonymous activity, ensuring that an analyst’s real identity and location are never exposed.

Tool CategoryTool/TypeUse Case
Network AnonymityVPN ClientsIP Masking & Geo-Shifting: Adding a layer of IP obfuscation, especially when accessing geo-restricted content or high-risk sites (often used before Tor for added protection).
Secure CommunicationTelegram, Session, Tox, Pidgin (with OTR/OMEMO)Threat Actor Engagements: Contacting a threat actor (TA) about a posted dataset, discussing access, or validating a claimed compromise.
Network UtilityTorsocks / ProxychainsScript Anonymization: Forcing data collection scripts (Python, Go, etc.) to use an anonymized network when scraping or downloading data.

Operational Case Study: Secure Threat Actor Engagement with Telegram and Flashpoint Managed Attribution

When communicating anonymously with a threat actor, the Flashpoint Managed Attribution workflow provides the following key advantages for CTI teams:

  • Identity Protection: Creates a secure, isolated virtual machine with robust anonymization (VPN, Tor, rotating IPs) to protect the analyst’s identity. The analyst sets up messaging clients like Telegram within this secure environment, making it impossible for the threat actor to trace their real IP or location.
  • Continuous OPSEC: Continuously masks the operational footprint with constantly changing and untraceable IP addresses, ensuring all communication is routed through multiple layers of anonymity.
  • Host Machine Isolation & Secure Logging: All information exchanged is handled within this isolated environment to prevent malicious files from affecting the analyst’s host machine, while all communications are securely logged for later analysis.

Data Processing & Automation

CTI analysts routinely process massive log files and breach dumps that are unstable, unvalidated, or potentially malicious. By deploying essential data processing and automation tools within an isolated environment like Flashpoint Managed Attribution, you ensure this high-risk content never compromises the analyst’s host machine.

Tool CategoryTool/TypeUse Case
Scripting & AutomationPython, Golang, Bash/PowerShellBreach Data Analysis: Creating custom scraping and parsing scripts to download and search breached datasets (often multi-terabyte files) from ransomware or other leak sites.
Command-Line Toolsgrep, awk, sed, curl, wgetAssess Exposure: Quickly search for company-specific keywords, employee names, or technical indicators across massive, potentially compromised datasets.
Data Encoding/DecodingCyberChef (Desktop/Local Instance)Indicator of Compromise (IOC) Transformation: Decoding obfuscated strings, converting data formats, or analyzing potentially malicious content without sending it to an external server.

Operational Case Study: Automating Breach Data Analysis with Python and Flashpoint Managed Attribution

Within a Flashpoint Managed Attribution workspace, a CTI analyst deploys a Python script. The anonymized MA environment ensures:

  • This script crawls and downloads data through an untraceable, constantly changing IP network, performing on-the-fly parsing and storing extracted intelligence in an encrypted database. 
  • Data ingestion and analysis is executed securely, leaving no trace of the analyst’s activity.

Open Source Intelligence (OSINT) & Analysis

The below applications help analysts connect the dots between various pieces of intelligence but often require handling data from unverified or hostile sources, necessitating strict isolation.

Tool CategoryTool/TypeUse Case
ResearchTor BrowserDark Web Collection: Accessing closed forums, markets, and hosting sites for intelligence gathering and monitoring.
Link AnalysisMaltegoMapping Threat Actors: Identifying the infrastructure, affiliates, and complex relationships of a cybercrime group under investigation.
Evidence PreservationHunch.lyChain of Custody: Securely capturing and preserving online evidence (e.g., from a hacktivist blog or a ransomware leak page) before it is taken down.
Metadata AnalysisExifTool (Desktop Client)Source Attribution: Analyzing a file downloaded from a threat actor site to extract potential clues like hidden usernames, internal network paths, or original creation dates.

Operational Case Study: Analyzing a Ransomware Leak Page with Hunch.ly

When a new ransomware group emerges, a CTI analyst uses tools like Hunch.ly to safely collect evidence from leak sites. Hunch.ly captures all data, timestamps it, and creates a cryptographic hash to ensure integrity. Using tools like Hunch.ly inside of a secure virtual machine like Flashpoint Managed Attribution ensures the analyst’s anonymity, enabling thorough analysis without risking the analyst’s system or identity.

Unlock Maximum Tool Utility with Flashpoint Managed Attribution

Ultimately, while these desktop tools are indispensable for CTI analysts operating in high-risk environments, their effective and secure deployment hinges on a robust underlying platform. This is where Flashpoint Managed Attribution becomes an invaluable asset. By providing a secure, anonymous workspace, Flashpoint Managed Attribution allows analysts to leverage these powerful tools, from network anonymizers and secure communication channels to advanced OSINT and data processing applications within an environment specifically built for operational security. 

Request a demo today to ensure that gathered critical intelligence remains untraceable to your organization or analysts.

Request a demo today.

The post The CTI Analyst’s Isolated Arsenal: Desktop Tools for High-Risk Intelligence appeared first on Flashpoint.

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Beyond the Malware: Inside the Digital Empire of a North Korean Threat Actor

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Beyond the Malware: Inside the Digital Empire of a North Korean Threat Actor

In this post Flashpoint reveals how an infostealer infection on a North Korean threat actor’s machine exposed their digital operational security failures and reliance on AI. Leveraging Flashpoint intelligence, we pivot from a single persona to a network of fake identities and companies targeting the Web3 and crypto industry.

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December 10, 2025

Last week, Hudson Rock published a blog on “Trevor Greer,” a persona tied to a North Korean IT Worker. Flashpoint shared additional insights with our clients back in July, and we’re now making those findings public.

Trevor Greer, a North Korean operative, was identified via an infostealer infection on their own machine. Information-stealing malware, also known as Infostealers or stealers, are malware designed to scrape passwords and cookies from unsuspecting victims. Stealers (like LummaC2 or RedLine) are typically used by cybercriminals to steal login credentials from everyday users to sell on the Dark Web. It is rare to see them infect the machines of a state-sponsored advanced persistent threat group (APT).

However, when adversaries unknowingly infect themselves, they can expose valuable insights into the inner workings of their campaigns. Leveraging Flashpoint intelligence sourced from the leaked logs of “Trevor Greer,” our analysts uncovered a myriad of fake identities and companies used by DPRK APTs.

Finding Trevor Greer

Flashpoint analysts have been tracking the Trevor Greer email address since December 2024 in relation to the “Contagious Interview” campaign, in which threat actors operated as LinkedIn recruiters to target Web3 developers, resulting in the deployment of multiple stealers compromising developer Web3 wallets. Flashpoint also identified the specific persona’s involvement in a campaign in which North Korean threat actors posed as IT freelance workers and applied for jobs at legitimate companies before compromising the organizations internally.

ByBit Compromise

The ByBit compromise in late February 2025 further fueled Flashpoint’s investigations into the Trevor Greer email address. Bybit, a cryptocurrency exchange, suffered a critical incident resulting in North Korean actors extorting US $1.5 billion worth of cryptocurrency. In the aftermath, Silent Push researchers identified the persona “Trevor Greer” associated with the email address trevorgreer9312@gmail[.]com, which registered the domain “Bybit-assessment[.]com” prior to the Bybit compromise.

A later report claimed that the domain “getstockprice[.]com” was involved in the compromise. Despite these domain discrepancies, both investigations attributed the attack to North Korean advanced persistent threat (APT) nexus groups.

Tracing the Infection

Using Flashpoint’s vast intelligence collections, we performed a full investigation of compromised virtual private servers (VPS), revealing the actor’s potential involvement in several other operations, including remote IT work, several self-made blockchain and cryptocurrency exchange companies, and a potential crypto scam dating back to 2022.

Flashpoint analysts also discovered that the Trevor Greer email address was linked to domains infected with information-stealing malware.

What the Logs Revealed

Analysts extracted information about the associated infected host from Trevor Greer, revealing possible tradecraft and tools used. Analysts further identified specific indicators of compromise (IOCs) used in the campaigns mentioned above, as well as email addresses used by the actor for remote work.

The data painted a vivid picture of how these threat actors operate:

Preparation for “Contagious Interviews”

The browser history revealed the actor logging into Willo, a legitimate video interview platform. This suggests the actor was conducting reconnaissance to clone the site for the “Contagious Interview” campaign, where they lured Web3 developers into fake job interviews to deploy malware.

Reliance on AI Tools

The logs exposed the actor’s reliance on AI to bridge the language gap. The operator frequently accessed ChatGPT and Quillbot, likely using them to write convincing emails, build resumes, and generate code for their malware.

Pivoting: One Node to a Network

By analyzing the “Trevor Greer” logs, we were able to pivot to other personas and campaigns involved in the operation.

  • Fake Employment: The logs contained credentials for freelance platforms, such as Upwork and Freelancer, associated with other aliases, including “Kenneth Debolt” and “Fabian Klein.” This confirmed the actor was part of a broader scheme to infiltrate Western companies as remote IT workers.
  • Fake Companies: The data linked the actor to fake corporate entities, such as Block Bounce (blockbounce[.]xyz), a sham crypto trading firm set up to appear legitimate to potential victims. 
  • Developer Personas: The infection data linked the actor to the GitHub account svillalobosdev, which had been active in open source projects to build credibility before the attack.
  • Legitimate Platforms & Tools: Analysts observed the actor using job boards such as Dice and HRapply[.]com, freelance platforms such as Upwork and Freelancer, and direct applications through company Workday sites. To improve their resume, the actor used resumeworded[.]com or cakeresume[.]com. For conversing, the threat actor likely relies on a mix of both GPT and Quilbot, as found in infected host logins, to ensure they sound human. During interviews, analysts determined that they potentially used Speechify. 
  • Deep & Dark Web Resources: The actor also likely purchased Social Security numbers (SSNs) from SSNDOB24[.]com, a site for acquiring Social Security data.

Disrupt Threat Actors Using Flashpoint

The “Trevor Greer” case study illustrates a critical shift in modern threat intelligence. We are no longer limited to analyzing the malware adversaries deploy; sometimes, we can analyze the adversaries themselves.

Using their own tools against them, Flashpoint transformed a faceless state-sponsored entity into a tangible user with bad habits, sloppy OPSEC, and a trail of digital breadcrumbs. Behind every sophisticated APT campaign is a human operator, and sometimes, they click the wrong link too. 

Request a demo today to delve deeper into the tactics, techniques, and procedures of advanced persistent threats and learn how Flashpoint’s intelligence strengthens your defenses.

Request a demo today.

The post Beyond the Malware: Inside the Digital Empire of a North Korean Threat Actor appeared first on Flashpoint.

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Introducing Saved Searches in Google Threat Intelligence (GTI) and VirusTotal (VT): Enhance Collaboration and Efficiency


We are excited to announce the launch of Saved Searches in Google Threat Intelligence (GTI) and VirusTotal (VT), a powerful new feature designed to streamline your threat hunting workflows and foster seamless collaboration across your security team.

From Campaign to Feature: Better Search Efficiency

For the last month, we’ve highlighted the critical importance of mastering search in our ongoing #monthofgoogletisearch campaign. We saw how security teams rely on complex, highly-tuned queries to identify threats, track adversaries, and perform deep-dive investigations.

This campaign emphasized a key challenge: once you craft the perfect query - a cornerstone of your investigation - it should be easy to reuse and share. Saved Searches is the direct answer to this need, turning successful, repeatable threat-hunting logic into a shared institutional asset.

Collaboration, Simplified: Save and Share Your Queries

With this initial launch of Saved Searches, we’re delivering two foundational capabilities that will immediately improve your team’s efficiency:

  1. Save Searches: Instantly save any complex or frequently used query directly within GTI. This ensures your best investigative logic is always accessible, eliminating the need to rebuild queries from scratch or store them externally.
  2. Share with Users: Critical insights are often time-sensitive. You can now easily share your saved searches with any other user in your organization with access to GTI. Whether you’re escalating a finding or establishing a standard workflow, sharing the exact query ensures consistency and accelerates joint analysis.
This means that a newly onboarded analyst can instantly access the expertise of senior members, and teams can maintain a unified approach to monitoring high-priority threats. It’s collaboration built right into your investigation tool.

Get Started Today with Campaign Searches

The Saved Searches feature is live now in Google Threat Intelligence and VirusTotal.

To help you hit the ground running, we have made the most impactful searches used throughout the #monthofgoogletisearch campaign public and available to all intelligence users! You can find these expert-crafted queries in your Saved Searches section today - a perfect starting point for your investigations.



Start by exploring these campaign searches and then easily save and share your own complex search queries. Look for the option to Save and Share your searches to transform your investigative logic into a shared asset.



This is just the first phase of enhancing search capabilities within GTI. We are committed to building on this foundation to provide even more robust tools that make your threat intelligence actionable and collaborative.

You can get more info by exploring our documentation page:

Thank you for your feedback during the #monthofgoogletisearch campaign - your input directly fueled this launch.

Happy Hunting! ^_^

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From Endpoint Compromise to Enterprise Breach: Mapping the Infostealer Attack Chain

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From Endpoint Compromise to Enterprise Breach: Mapping the Infostealer Attack Chain

In Flashpoint’s latest webinar, we map the global infostealer attack chain step-by-step, from initial infection to enterprise-level account takeover. We analyze how the commodification of stolen identities works and demonstrate how Flashpoint intelligence provides the critical visibility necessary to disrupt this cycle.

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December 8, 2025

Compromised digital identities have become one of the most valuable currencies in the cybercriminal ecosystem. The rise of information-stealing malware has created an industrial-scale supply chain for stolen credentials, session cookies, and browser fingerprints, directly fueling account takeover (ATO) campaigns that penetrate even the most mature security environments.

Flashpoint recently hosted an on-demand webinar, “From Compromise to Breach: How Infostealers Power Identity Attacks,” where our experts dissected this developing threat landscape. We exposed the exact sequence of events, providing defenders with the actionable intelligence required to disrupt the chain at multiple points. For the full technical breakdown, check out the full on-demand webinar

Here are the main key takeaways you need to know:

Stage 1: Initial Infection and Data Harvest (The Compromise)

A full scale compromise often begins with a single event, typically a phishing lure, a malicious download, or a compromised cracked software installer. Once executed, the infostealer goes to work, quickly and stealthily, to build a “log” that grants post-MFA (multi-factor authentication) access.

Scouring now-compromised endpoints, the stealer searches for and compiles data such as:

  • Credentials: Saved logins, credit card details, and passwords for applications and websites.
  • Session Cookies/Tokens: These are the keys that allow an attacker to bypass login prompts entirely, appearing as an already-authenticated user.
  • Browser Fingerprints and System Metadata: Geolocation, IP address, and system language used to evade security tools by accurately mimicking the victim’s legitimate environment.

Stage 2: Commodification and the ATO Supply Chain (The Market)

Once a log is harvested, it enters the Infostealer-as-a-Service ecosystem, a critical industrialized stage of the attack chain. Here, threat actors can rent or purchase access to millions of fresh logs, effectively outsourcing the initial compromise phase and enabling mass identity exploitation for a minimal investment.

Check out the on-demand webinar for a full technical breakdown of this dark web economy and how the commodification of stealer logs drastically reduces the barrier to entry for follow-on attacks.

Stage 3: Post-MFA Account Takeover (The Breach)

This is the ultimate pivot point, where a simple endpoint infection escalates into an enterprise breach. Unlike the brute-forcing and phishing attacks of the past, attackers leverage the stolen session tokens and browser fingerprints.

Stolen log buyers leverage obfuscation tools such as anti-detect browsers. These tools ensure the attacker can seamlessly utilize the stolen cookies and digital fingerprints to appear identical to the original victim. 

They inject valid, unexpired session tokens into their browser, which allows attackers to hijack the victim’s active session. This allows them to avoid fraud and anomaly detection systems, providing them access into corporate VPNs, cloud environments, and internal applications without ever needing to see a login prompt. From here, attackers can move laterally, exfiltrate sensitive data, or deploy ransomware.

Disrupting the Attack Chain Using Flashpoint’s Actionable Intelligence

Defense against this threat requires not only an understanding of the attack chain, but also comprehensive Cyber Threat Intelligence (CTI) to identify and mitigate risks at every stage:

Disruption Point in the Attack ChainHow Flashpoint Empowers Proactive Defense
Stage 1: Initial Infection/Log CreationGain immediate alerting on the sale of your organization’s compromised assets on the Dark Web before attackers can leverage stolen data.
Stage 2: Commodification/ATO SetupExpose the illicit platforms and forums where threat actors discuss, buy, and sell stolen logs, allowing you to track the tooling and TTPs.
Stage 3: Post-MFA ATO/BreachIdentify and remediate the vulnerabilities within browsers or enterprise software that are most actively being targeted by infostealers.

The speed of infostealer-powered attacks demands an intelligence-driven response. Our recent webinar demonstrated how Flashpoint intelligence can empower your security teams to quickly identify and validate stolen logs, protecting your organization from compromise to breach. Watch the on-demand webinar to learn more, or request a demo today.

Request a demo today.

The post From Endpoint Compromise to Enterprise Breach: Mapping the Infostealer Attack Chain appeared first on Flashpoint.

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Digital Supply Chain Risk: Critical Vulnerability Affecting React Allows for Unauthorized Remote Code Execution

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Digital Supply Chain Risk: Critical Vulnerability Affecting React Allows for Unauthorized Remote Code Execution

CVE-2025-55182 (VulnDB ID: 428930), is a severe, unauthenticated RCE impacting a major component of React and its ecosystem, putting global applications at immediate, high-fidelity risk.

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December 4, 2025

The React team disclosed a critical vulnerability impacting three products in the React Server Components (RSC) that allows for unauthenticated remote code execution. 

Flashpoint’s vulnerability research team assesses significant enterprise and supply chain risk given React’s ubiquity: the impacted JavaScript library underpins modern UIs, with 168,640 dependents and more than 51 million weekly downloads.

How CVE-2025-55182 Works

CVE-2025-55182 (VulnDB ID: 428930) impacts all React versions since 19.0.0, meaning that this issue has been potentially exploitable since November 14, 2024. This vulnerability stems from how React handles payloads sent to React Server Function endpoints and deserializes them.

Flashpoint’s VulnDB entry for CVE-2025-55182

Depending on the implementation of this library, a remote, unauthenticated threat actor could send a crafted payload that would be deserialized in a way that causes remote code execution. This would lead to a total compromise of the system hosting the application, allowing for malware such as infostealers, ransomware, or cryptojackers (cryptocurrency mining) to be downloaded.

A working exploit for CVE-2025-55182 has already been published that is effective against some installations. In addition, Amazon has reported that two threat actors, attributed to Chinese Advanced Persistent Threat Groups (APTs), have begun to exploit this vulnerability. Those groups are:

  • Earth Lamia (STAC6451, REF0657, CL-STA-0048)
  • Jackpot Panda (iSoon, DRAGNET PANDA, Anxun Information, deepclif, Poison Carp, Houndstooth Typhoon)

Understanding the Impact and Scope of CVE-2025-55182

It is critical that security teams fully understand the potential downstream scope and impact so that they can fully focus on mitigation, rather than time-consuming research. While the vendor has provided a full disclosure, there are several important caveats to understand about CVE-2025-55182:

  1. Applications not implementing any React Server Function endpoints may still be vulnerable as long as it supports React Server Components.
  2. If an application’s React code does not use a server, it is not affected by this vulnerability.
  3. Applications that do not use a framework, bundler, or bundler plugins that support React Server Components are unaffected by this vulnerability.

Additionally, several React frameworks and bundlers have been discovered to leverage vulnerable React packages in various ways. The following frameworks and bundlers are known to be affected:

  • next
  • react-router
  • waku
  • @parcel/rsc
  • @vitejs/plugin-rsc
  • rwsdk

NPMJS.com currently shows that the react-dom package, which is effectively part of React, has 168,640 dependents. This means that an incredible number of enterprise applications are likely to be affected. Nearly every commercial application is built on hundreds, sometimes thousands of components and dependencies. Furthermore, applications coded via Vibe and similar technology are also likely to leverage React: potentially amplifying the downstream risk this vulnerability poses.

How to Mitigate CVE-2025-55182

For mitigation, the React library has released versions 19.0.1, 19.1.2, and 19.2.1 that resolve the issue. Flashpoint advises organizations to upgrade their respective libraries urgently. Security teams leveraging dynamic SBOMs (Software Bill of Materials) can drastically increase risk mapping and triage for deployed React versions.

CloudFlare has upgraded their web-application firewall (WAF) to protect against CVE-2025-55182. It is available for both free and paid plans but requires that React application traffic is proxied through the CloudFlare WAF.

To avoid confusion, security teams should ignore CVE-2025-66478. It has been rejected for being a duplicate of the preferred CVE-2025-55182.

Mitigate Critical Vulnerabilities Using Flashpoint

Flashpoint strongly recommends security teams treat this vulnerability with utmost urgency. Our vulnerability research team will continue to monitor this vulnerability and its downstream impacts. All updates will be provided via Flashpoint’s VulnDB

Request a demo today and gain access to quality vulnerability intelligence that helps address critical threats in a timely manner.

Request a demo today.

The post Digital Supply Chain Risk: Critical Vulnerability Affecting React Allows for Unauthorized Remote Code Execution appeared first on Flashpoint.

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Flashpoint’s Top 5 Predictions for the 2026 Threat Landscape

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Flashpoint’s Top 5 Predictions for the 2026 Threat Landscape

Flashpoint’s forward-looking threat insights for security and executive teams, provides the strategic foresight needed to prepare for the convergence of AI, identity, and physical security threats in 2026.

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December 2, 2025

As the global threat landscape accelerates its transformation, 2026 marks an inflection point requiring defensive strategies to fundamentally shift. The volatility observed in 2025 has paved the way for an era soon to be defined by AI-weaponized autonomy, information-stealing malware, systemic instability of public vulnerability systems, and the complete convergence of digital and physical risk.

Flashpoint offers a unique window into these complexities, providing organizations with the foresight needed to navigate what lies ahead. Drawing from Flashpoint’s leading intelligence and primary source collections, we highlight five key trends shaping the 2026 threat landscape. These insights aim to help organizations not only understand what’s next but also build the resilience needed to withstand and adapt to emerging challenges.

Prediction 1: Agentic AI Threats Will Weaponize Autonomy, Forcing a New Defensive Standard

2026 will see continued evolution of AI threats, with future attacks centering on autonomy and integration. Across the deep and dark web, Flashpoint is observing threat actors move past experimentation and into operational use of illegal AI. 

As attackers train custom fraud-tuned LLMs (Large Language Models) and multilingual phishing tools directly on illicit data, these AI models will become more capable. The criminal intent shaping their misuse will also become more sophisticated. Additionally, 2026 will see a greater marketplace for paid jailbreaking communities and synthetic media kits for KYC (Know Your Customer) bypass.

These advancements are enabling criminals to move beyond simple tools and engage in scaled, autonomous fraud operations, leading to two major shifts:

  1. Agentic AI is becoming the true flashpoint: Threat actors will be using agentic systems to automate reconnaissance, generate synthetic identities, and iterate on fraud playbooks in near real-time. In this SaaS ecosystem, AI will help attackers leverage subscription tiers and customer feedback loops at scale.
  2. The attack surface will shift to focus on AI Integrations: Organizations are increasingly plugging LLMs into live data streams, internal tools, identity systems, and autonomous agents. This practice often lacks the same security vetting, access controls, and monitoring applied to other enterprise systems. As such, attackers will heavily target these integrations, such as APIs, plugins, and system connections, rather than the models themselves.

The ubiquity of automation has dramatically increased attack tempo, leaving many security teams behind the curve. While automation can replace repetitive tasks across the enterprise, organizations must not make the critical mistake of substituting human judgement for AI at the intelligence level.

This is paramount because a critical threat in 2026 is Agentic AI autonomy weaponized against soft targets—API integrations and identity systems. The only winning defense will be human-led and AI-scaled, prioritizing purposeful use to keep organizations ahead of this exponential risk.

Josh Lefkowitz, CEO at Flashpoint

These evolving AI threats will force a fundamental shift in defensive strategies. Defenders will have to shift to deploying systems around AI rather than trust them on their own.

Prediction 2: Identity Compromise via Infostealers Will Become the Foundation of Every Attack

Infostealers will become the entry point, the data broker, the reconnaissance layer, and the fuel for everything that comes after a cyberattack. This shift is already in motion and is accelerating rapidly: in just the first half of 2025, infostealers were responsible for 1.8 billion stolen credentials, an 800% spike from the start of the year. However, 2026 will redefine the malware’s role, making its most valuable output being access, rather than disruption.

Infostealers will become the upstream event that powers the rest of the attack chain. Identity and session data will be increasingly targeted, since it gives attackers immediate access into victim environments. Ransomware, fraud, data theft, and extortion will simply be downstream ways to monetize.

This upstream approach defines the new reality of the attack chain, which is already operational. Nearly every major stealer strain Flashpoint observes now exfiltrates the following:

  • Autofill PII (personable identifiable information)
  • Saved addresses
  • Phone numbers
  • Internal URLs
  • Browsing history
  • Cloud app tokens

An organization’s attack surface is no longer just composed of their own networks. It is the entire digital identity of their employees and partners. This new reality requires security teams to take a new approach. Instead of attempting to block attacks, they must proactively detect compromised credentials before they are weaponized. This will be the difference between reacting to a data breach and preventing one.

The infostealer economy has fully industrialized the attack chain, making initial compromise a low-cost commodity. Multiple security incidents in 2025 tie back to credentials found in infostealer logs. This reality has underscored the critical importance of digital trust—specifically, verifying who can access what resources. For 2026, identity is the perimeter to watch, and security teams must proactively hunt for compromised credentials before they’re weaponized.

Ian Gray, Vice President of Intelligence at Flashpoint

Prediction 3: CVE Volatility Will Force Redundancy in Vulnerability Intelligence

The temporary funding crisis at CVE in April 2025 and the subsequent CISA stopgap extension through March 2026 exposed the systemic fragility of a centralized vulnerability intelligence model. With the future of the CVE/NVD system hanging in the balance, 2026 will be defined by the urgent need for redundancy and diversification in vulnerability intelligence.

In today’s vulnerability intelligence ecosystem, nearly every organization’s vulnerability management framework relies on CVE and NVD—including its “alternatives” such as the EUVD (European Union Vulnerability Database). The CVE system has grown into a critical global cybersecurity utility, relied upon by nearly all vulnerability scanners, SIEM platforms, patch management tools, threat intelligence feeds, and compliance reports. A complete shutdown of CVE would result in a widespread loss of institutional infrastructure.

The next generation of security needs to be built on practices that are resilient, diversified, and intelligence-driven. It should be focused on providing insights that can be used to take action such as threat actor behavior, likelihood of exploitation in the wild, relevance to ransomware campaigns, and business context. Security teams will need to leverage a comprehensive source of vulnerability intelligence such as Flashpoint’s VulnDB that provides full coverage for CVE, while also cataloging more than 100,000 vulnerabilities missed by CVE and NVD.

Prediction 4: Executive Protection Will Remain a Critical Challenge as Cyber-Physical Threats Converge

The continued blurring of lines between cyber, physical, and geopolitical threats will elevate the risk to organizational leadership, turning executive protection into a holistic intelligence function in 2026. The rise of information warfare combined with physical world convergence means the threat to key personnel is no longer purely digital.

In the aftermath of the tragic December 2024 assassination of United Healthcare’s CEO, Flashpoint has seen the continued circulation and glorification of “wanted-style posters” of executives in extremist communities. Additionally, Flashpoint has seen nation-state actors participate, using espionage and influence to target high-value individuals.
Organizations must adopt an integrated approach that connects insights from threat actor chatter and a wealth of other OSINT sources. This fusion of intelligence is essential for applying frameworks to ensure the safety of leadership and key personnel.

Prediction 5: Extortion Shifts to Identity-Based Supply Chain Risk

2025 was marked by several large-scale extortion campaigns, demonstrating how the threat landscape is rapidly evolving. Ransomware operations have shifted into a straight extortion play. Flashpoint has observed a surge in new entrants to the ransomware market, accompanied by a decline in the quality and decorum of ransomware groups.

Furthermore, vishing campaigns attributed to “Scattered Spider” have highlighted weaknesses in identity, trust, and verification. Campaigns from “Scattered LAPSUS$ Hunters” have also exposed vulnerabilities in third-party integrations. These attacks culminated in extortion, showcasing that modern attacks will target trusted users and trusted applications for initial access, and will forgo ransomware in place of data access.

As this shift continues into 2026, threat actors will increasingly focus their efforts on exploiting human behavior and identity systems. Instead of attempting to spend resources on breaking network perimeters, attackers will instead socially engineer employees to gain access to corporate systems at scale. This change in TTPs will undoubtedly greatly increase supply chain risk, especially for third parties.

Charting a Path Through an Evolving Threat Landscape with Flashpoint Intelligence

These five predictions highlight the transformative trends shaping the future of cybersecurity and threat intelligence. Staying ahead of these challenges demands more than just reactive measures—it requires actionable intelligence, strategic foresight, and cross-sector collaboration. By embracing these principles and investing in proactive security strategies, organizations can not only mitigate risks but also seize opportunities to enhance their resilience.

As the threat landscape continues to rapidly evolve, staying informed and prepared are critical components of risk mitigation. With the right tools, insights, and partnerships, security teams can navigate the complexities ahead and safeguard what matters most.

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The post Flashpoint’s Top 5 Predictions for the 2026 Threat Landscape appeared first on Flashpoint.

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