• Cisco Talos has discovered new threats, including the ransomware CyberLock, Lucky_Gh0$t, and a newly-discovered malware we call “Numero,” all of which masquerade as legitimate AI tool installers. 
• CyberLock ransomware, developed using PowerShell, primarily focuses on encrypting specific files on the victim’s system. The threat actor deceitfully claims in the ransom note that the payments will be allocated for humanitarian aid in various regions, including Palestine, Ukraine, Africa and Asia. 
• Lucky_Gh0$t ransomware is yet another variant of the Yashma ransomware, which is the sixth iteration of the Chaos ransomware series, featuring only minor modifications to the ransomware binary. 
• The newly-identified destructive malware, Numero, affects victims by manipulating the graphical user interface (GUI) components of their Windows OSs, rendering systems completely unusable. 

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AI has increasingly proliferated across various business verticals, leading to a transformation of industries through automation, data-driven decision-making and enhanced customer engagements. However, as AI continues to propel multiple industry sectors forward, malicious actors are exploiting its popularity by distributing a range of malware disguised as AI solutions’ installers and tools.  

Threat actors are employing a variety of techniques and channels to distribute these fraudulent installers, including SEO-poisoning tactics to manipulate search engine rankings and cause their malicious websites or download links to appear at the top of search engine results, as well as platforms such as Telegram or social media messengers. 

As a result, unsuspecting businesses in search of AI solutions may be deceived into downloading counterfeit tools in which malware is embedded. This practice poses a significant risk, as it not only compromises sensitive business data and financial assets but also undermines trust in legitimate AI market solutions. Therefore, organizations and users must exercise extreme caution, meticulously verify sources, and rely exclusively on reputable vendors to avoid falling prey to these threats. 

Talos has recently uncovered multiple threats masquerading as AI solutions being circulated in the wild, including the CyberLock and Lucky_Gh0$t ransomware families, along with a newly discovered destructive malware, dubbed “Numero.” The legitimate versions of these AI tools are particularly popular within the B2B sales domain and the technology and marketing sectors, indicating that individuals and organizations in these industries are particularly at risk of being targeted by these malicious threats. 

CyberLock ransomware 

Talos observed a threat actor creating a lookalike fake AI solution website with the domain ‘novaleadsai[.]com’, likely masquerading as the original website domain ‘novaleads.app’, a lead monetization platform designed to help businesses maximize the value of their leads through various services and performance-based models. 

On the fake website, the actor persuades users to download the product with an offer of free access to the tool for the first 12 months, followed with a monthly subscription of $95. The threat actor also used an SEO manipulation technique that made their fake website appear in the top search results for online search engines.   

When a user downloads the fake AI product as a ZIP archive, it contains a .NET executable with the file name ‘NovaLeadsAI.exe’. The executable was compiled on Feb. 2, 2025, which is on the same day the fake domain ‘novaleadsai[.]com’ was created.  

The ‘NovaLeadsAI.exe’ file is the loader that has the CyberLock ransomware PowerShell script embedded as the resource file. When the victim runs the loader executable, it deploys the ransomware. 

CyberLock ransom note 

The CyberLock ransomware appeared to be operating as early as Feb. 2025. The ransom note claims that the threat actor has obtained full access to sensitive business documents, personal files and confidential databases, demanding a hefty ransom in exchange for decryption keys. Victims are instructed to communicate with the threat actor by emailing ‘cyberspectreislocked@onionmail[.]org’. 

The CyberLock threat actor demands that the USD $50,000 ransom be paid exclusively in Monero (XMR) cryptocurrency and employs psychological tactics by falsely claiming that the ransom payments will be used for humanitarian aid in regions like Palestine, Ukraine, Africa and Asia. The actor splits the payment into two separate wallets, complicating defenders’ tracking efforts. 

The ransom note is structured to intimidate and manipulate victims by threatening to expose stolen data if payment is not made within three days. However, Talos did not see any evidence of data exfiltration functionality within the ransomware code. 

CyberLock, the PowerShell ransomware 

CyberLock ransomware is written in PowerShell, embedded with the CSharp code and delivered to the victims as an embedded resource of the .NET loader. 

When CyberLock is executed, it initially uses the functions GetConsoleWindow from kernel32.dll and ShowWindow from user32.dll to hide the PowerShell window. Then it generates a secret by decrypting the encrypted public key and uses it to derive the AES key and IV during the encryption process. 

CyberLock has the capability to elevate privileges and re-execute itself with administrative privileges if it is not already running in an elevated context.   

CyberLocker enumerates folders and files of the logical partitions with the labels ‘C:’, ‘D:’ and ‘E:’. It encrypts the targeted files using AES and appends the file extension ‘.cyberlock’ to the encrypted files.  

The targeted file extensions and the categories are shown below: 

Category	File Extensions
Text Documents	.txt, .doc, .docx, .odt, .rtf, .md, .rst, .tex, .sty
Spreadsheets	.xls, .xlsx, .ods, .csv, .tsv
Presentations	.ppt, .pptx, .odp, .potx, .ppsx
PDF & eBooks	.pdf, .pdfx, .epub, .mobi, .azw, .azw3, .chm, .hlp
Images	.jpg, .jpeg, .png, .gif, .bmp, .tiff, .raw, .svg, .jfif, .ico, .webp
Audio	.mp3, .wav, .ogg, .aac, .flac, .m4a, .m4b, .caf, .mp3g
Video	.avi, .mp4, .mov, .mkv, .wmv, .webm, .3gp, .flv, .m4v, .vob, .mts, .m2ts, .ts, .mxf, .divx, .mpeg, .mpg, .ram, .rm
Archives & Disk Images	.zip, .rar, .7z, .tar, .gz, .xz, .tar.gz, .tar.bz2, .iso, .iso9660, .img, .dmg, .cdr, .zipx, .cab, .zpaq, .seam, .rar5
Executables & Scripts	.exe, .bat, .cmd, .sh, .ps1, .vbs, .js, .appx, .apk, .ipa, .deb, .rpm, .whl
Code & Programming	.html, .css, .scss, .xml, .json, .yaml, .cfg, .sql, .pl, .rb, .py, .lua, .h, .c, .cpp, .m, .swift, .java, .asm, .psm1
Database Files	.sql, .mdb, .accdb, .db, .sqlite, .sqlitedb, .db3, .sqlite3
System & Config	.log, .bak, .tmp, .swp, .ini, .plist, .xmlrpc, .dsk, .xcv
Fonts	.ttf, .otf, .woff, .woff2, .eot, .pfb
Design & Graphics	.ai, .psd, .indd, .eps, .fla, .swf
Backup & Virtual Machine	.vhd, .vmdk, .qcow2, .gho, .vpb
GIS & Maps	.gpx, .kml, .shp
Other Files	.torrent, .bup, .ifo, .bin, .dll, .msi, .sys, .qif, .pages, .key, .numbers, .rdata, .seed, .3dxml, .kdbx

After encrypting the targeted files, CyberLock creates a ransom note on the victim machine desktop with the file name ‘ReadMeNow.txt’. Ransom note contents are written into it from the embedded strings in the ransomware PowerShell script. 

Talos observed that the ransomware actor sets a wallpaper to the victim machine’s desktop after dropping the ransom note. The threat actor downloads a header image from a cybersecurity organization’s blog post to the victim machine user profile applications temporary folder. They configure the path of the downloaded image to the registry key “Wallpaper” and enable the wallpaper through PowerShell commands. Talos not fully certain of the actor’s motive for setting the victim machine’s desktop wallpaper to a security research blog post header image. 

Finally, CyberLock uses the living-off-the-land binary (LoLBin) ‘cipher.exe’ with the ‘/w’ option to erase free space on the victim’s hard drive partitions, hindering forensic recovery of deleted files. 

‘Cipher.exe’ is a built-in Windows command-line tool for managing file and folder encryption. One of its features allows users to prevent recovery of deleted files by overwriting free space with the ‘/w’ option. This was designed by Microsoft for legitimate purposes, such as securely wiping disks before reallocating them or complying with data protection laws to ensure sensitive data is unrecoverable by unauthorized parties.  

Threat actors often misuse this feature to eliminate their malicious footprints or permanently delete files from victim machines. This technique was previously utilized by a Russian APT in their attacks, as noted by Volexity researchers. However, Talos has not observed any indication that this activity is related to the activity described in prior reporting. 

Lucky_Gh0$t ransomware as fake ChatGPT installer  

Talos discovered a threat actor distributing Lucky_Gh0$t ransomware in the wild, archived in a self-extracting archive (SFX) ZIP installer with the file name ‘ChatGPT 4.0 full version – Premium.exe’. 

The malicious SFX installer included a folder that contained the Lucky_Gh0$t ransomware executable with the filename ‘dwn.exe’, which imitates the legitimate Microsoft executable ‘dwm.exe’. The folder also contained legitimate Microsoft open-source AI tools that are available on their GitHub repository for developers and data scientists working with AI, particularly within the Azure ecosystem. The threat actor’s intention in including the legitimate tools in the SFX archive is likely to evade the anti-malware file scanners detections by masquerading as a legitimate package.  

The SFX script executes the ransomware when a victim runs the malicious SFX installer file. 

Lucky_Gh0$t ransomware is the Yashma ransomware variant with most features unchanged, including the evasion techniques, deleting the volume shadow copies and backups, and AES-256 and RSA-2048 encryption techniques. Talos observed a few minor modifications in the Lucky_Gh0$t binary with targeted file size limits that are to be considered by the ransomware during encryption. 

Lucky_Gh0$t targets files on the victim machine that are approximately less than 1.2GB in size and encrypts the files with the RSA-encrypted AES key, appending a 4-digit random alphanumeric characters as the file extension. The targeted files category for encryption include: 

• Text, code and config files 
• Microsoft Office and Adobe files 
• Media formats and images 
• Archives and installers 
• Backup and database files 
• Android package kit, Java Server Pages and Active server pages 
• Certificate files 
• Visual Studio Solutions and PostScripts 

For the targeted files with a size larger than 1.2GB, the ransomware creates a new file the same size of the original file and writes a single character “?” as the file content. It appends a 4-digit random alphanumeric character file extension to the new file and deletes the original file, exhibiting destructive behavior. 

Lucky_Gh0$t ransomware provides a personal ID to the victims in their ransom note. For further communication regarding ransom payment and decryption, it instructs the victims to contact the threat actor using a secure messenger platform at ‘getsession[.]org’ with a unique session ID.

Numero pretending to be an AI video creation tool  

Talos recently discovered a new destructive malware in the wild that we call “Numero,” designed to imitate the AI video creation tool installer, InVideo AI. InVideo AI is an online platform widely used for marketing videos, social media content, explainer videos and presentations. The threat actor impersonates the product and the organization names in the malicious file’s metadata. 

The fake installer is a dropper containing a malicious Windows batch file, VB script and the Numero executable with the file name ‘wintitle.exe’. When the victim runs the fake installer, it drops the malicious components in a folder at the local user profile’s application temporary folder. Then it executes the dropped Windows batch file through Windows shell in an infinite loop. It first runs the Numero malware and then halts the execution for 60 seconds by executing the VB script through cscript.  

After resuming the execution, the batch file terminates the Numero malware process and restarts its execution. By implementing the infinite loop in the batch file, the Numero malware is continuously run on the victim machine. 

Numero’s behavior is consistent with window manipulator malware. Numero is a 32-bit windows executable written in C++ and was compiled on Jan. 24, 2025.  

Numero evades analysis by checking the process handles of various malware analysis tools and debuggers including IDA, x64 debugger, x32debugger, ollydbg, scylla, windbg, reshacker, ImportREC, Immunity debugger, Zeta debugger and Rock debugger. 

Numero malware creates and executes the thread in an infinite loop. The thread code interacts with the Windows GUI and manipulates the victim’s desktop window using the Windows APIs GetDesktopWindow, EnumChildWindows and SendMessageW. It monitors the victim machine desktop window continuously and hooks to the child window created in the victim desktop. Numero overwrites the window title, buttons and contents with the numeric string ‘1234567890’, corrupting the victim machine to become unusable.  

Coverage  

Ways our customers can detect and block this threat are listed below.  

Cisco Secure Endpoint (formerly AMP for Endpoints) is ideally suited to prevent the execution of the malware detailed in this post. Try Secure Endpoint for free here.  

Cisco Secure Email (formerly Cisco Email Security) can block malicious emails sent by threat actors as part of their campaign. You can try Secure Email for free here.  

Cisco Secure Firewall (formerly Next-Generation Firewall and Firepower NGFW) appliances such as Threat Defense Virtual, Adaptive Security Appliance and Meraki MX can detect malicious activity associated with this threat.  

Cisco Secure Network/Cloud Analytics (Stealthwatch/Stealthwatch Cloud) analyzes network traffic automatically and alerts users of potentially unwanted activity on every connected device.  

Cisco Secure Malware Analytics (Threat Grid) identifies malicious binaries and builds protection into all Cisco Secure products.  

Cisco Secure Access is a modern cloud-delivered Security Service Edge (SSE) built on Zero Trust principles.  Secure Access provides seamless transparent and secure access to the internet, cloud services or private application no matter where your users work.  Please contact your Cisco account representative or authorized partner if you are interested in a free trial of Cisco Secure Access.  

Umbrella, Cisco’s secure internet gateway (SIG), blocks users from connecting to malicious domains, IPs and URLs, whether users are on or off the corporate network.   

Cisco Secure Web Appliance (formerly Web Security Appliance) automatically blocks potentially dangerous sites and tests suspicious sites before users access them.   

Additional protections with context to your specific environment and threat data are available from the Firewall Management Center.  

Cisco Duo provides multi-factor authentication for users to ensure only those authorized are accessing your network.   

Open-source Snort Subscriber Rule Set customers can stay up to date by downloading the latest rule pack available for purchase on Snort.org.  

Snort SIDs for the threats are: 

• Snort 2: 64901, 64902, 64899, 64900, 64897, 64898, 64896 
• Snort 3: 301207, 301206, 301205 

ClamAV detections are also available for this threat:   

• Ps1.Ransomware.CyberLock-10045054-0 
• Win.Dropper.CyberLock-10045058-0 
• Win.Dropper.LuckyGhost-10045078-0 
• Win.Ransomware.LuckyGhost-10045080-0 
• Win.Loader.Numero-10045084-0 
• Win.Dropper.Numero-10045088-0 
• Win.Malware.Numero-10045090-0 
• Win.Malware.Numero-10045093-0 

Indicators of Compromise 

IOCs for this threat can be found in our GitHub repository here. 

Cisco Talos Blog – ​Read More

Malware doesn’t stick to one platform or play fair. One day it’s a Python stealer. The next, it’s an Android RAT or a Node.js backdoor quietly pinging its C2. Then it hits Linux, flooding your network with suspicious connections. 

Modern threats are unpredictable. They move across systems and languages, often slipping past tools that weren’t built for this level of complexity. 

ANY.RUN’s cloud-based sandbox gives companies and SOC teams the flexibility to investigate these threats.

One sandbox where you can analyze, detect, and understand malware and phishing, no matter the OS, architecture, or language. With support for Windows, Linux, and Android, you can choose the environment that fits your sample and see how the same threat behaves across platforms. Just upload, launch, and start investigating. 

Let’s see how cybersecurity teams use ANY.RUN to detect and analyze malware written in languages like Python and Node.js, and built to target different systems. 

Malware Written in Node.js: Unpacking GootLoader’s Multi-Stage Execution 

JavaScript isn’t just for websites anymore, and that’s part of the problem. Threat actors increasingly use JavaScript and Node.js to build droppers, stealers, and loaders that can bypass traditional defenses.  

For businesses, these threats often arrive disguised as legitimate files, especially in environments where document sharing and template downloads are common. Once executed, they can trigger multi-stage infections, establish persistence, and pull down additional payloads without leaving obvious traces. 

To see how a Node.js-based attack unfolds in the real world, let’s analyze a live GootLoader infection inside the ANY.RUN sandbox. 

View analysis of Node.js threat 

The attack begins when a user lands on a compromised website while searching for something business-related, like a contract template.  

The site delivers a ZIP file containing a trojanized JavaScript file posing as a common library (e.g., jQuery). Once opened, the script runs via wscript.exe, launching a heavily obfuscated payload. 

ANY.RUN’s Script Tracer logs and deobfuscates this activity in real time, giving analysts full visibility into each execution step. 

We can see all the completed processes of the attack from the right side of the screen, where the process tree is. Here is what we discover here: 

Once executed, the first-stage payload drops a second-stage JavaScript file onto the victim’s system and creates a scheduled task to run it immediately and ensure persistence.  

The task launches the second-stage script, initially again through wscript.exe (PID 7828), which then transfers execution to cscript.exe (PID 7896). This script spawns a PowerShell process (PID 8092), which further deobfuscates and runs another PowerShell script. 

This PowerShell script conducts extensive system reconnaissance, collecting environment variables, OS version, running processes, and more. It communicates with the attacker’s command and control (C2) server by sending compressed and encoded data embedded in HTTP headers, complicating detection. 

After establishing communication, the PowerShell script downloads additional payloads, often storing them within the Windows registry to avoid being written to disk. These payloads may include a loader and a secondary component such as a Cobalt Strike Beacon or other post-exploitation tools. 

Python-Based Malware: A Stealthy Threat to Business Environments 

Python isn’t just a favorite among developers, it’s increasingly used by attackers to create lightweight, modular, and evasive malware. Its readability and cross-platform flexibility make it an ideal choice for building custom stealers, droppers, and loaders that are easy to modify and hard to catch. 

For businesses, Python-based malware like Pentagon Stealer poses a real threat. It’s designed to quietly siphon off browser data, crypto wallet credentials, communication tokens, and personal files, often without dropping anything obvious to disk. 

To see how it operates in the wild, let’s break down a real sample of the Python variant of Pentagon Stealer in the ANY.RUN sandbox. 

View analysis of Pentagon Stealer 

The infection starts with an encrypted dropper, which launches a hidden Python script using AES encryption in CBC mode. Once decrypted, the stealer sets up persistence and scans the system for valuable data. 

In ANY.RUN’s sandbox, Pentagon’s behavior is clearly exposed across each stage of the infection chain. 

Data theft detection: The stealer harvests browser credentials, cookies, and data from apps like Atomic and Exodus. This activity is automatically flagged by the sandbox, giving analysts immediate insight into what data was accessed and how. 

C2 communication: Pentagon communicates with domains like pentagon[.]cy and stealer[.]cy, while variants such as BLX upload stolen data to gofile.io. These indicators are collected and displayed in the IOC section, making it easy to pivot, enrich threat intel, or block infrastructure in other systems. 

MITRE ATT&CK mapping: The sandbox automatically links observed behavior to ATT&CK tactics and techniques. For Pentagon, this includes: 

• Credentials from Web Browsers: The malware extracts saved usernames, passwords, and cookies from Chromium-based browsers, compromising access to email, cloud apps, and internal systems. 

• Credentials in Files: It scans user directories for sensitive files, like password.txt or wallet backups, that may contain unprotected login credentials. 

• System Information Discovery: Pentagon gathers OS details, hardware info, and environment variables to tailor its behavior or decide whether to proceed with the attack. 

• Query Registry: The stealer accesses Windows Registry keys to detect installed software, security tools, and persistence mechanisms. 

• Service Stop: It disables security-related services like Windows Defender to avoid detection and ensure uninterrupted operation of follow-up payloads. 

With this mapping, teams get a full picture of the attack’s intent and progression without manually stitching logs together. 

Android Malware: How Salvador Stealer Hijacks Banking Credentials 

Salvador Stealer is a highly deceptive Android malware disguised as a legitimate banking app. Behind its clean interface lies a full-fledged phishing and data exfiltration machine, designed to steal everything from government ID numbers and personal information to net banking credentials and one-time passwords.  

For both individuals and financial institutions, Salvador poses a serious threat, combining technical sophistication with aggressive credential harvesting and real-time data leaks via Telegram and phishing servers. 

To uncover the full behavior of Salvador Stealer and observe its actions in real time, we executed the sample inside ANY.RUN’s Android environment. 

View full analysis session 

Inside the interactive Android VM, we could clearly observe each stage of the infection, uncovering its tactics, visualizing the phishing interface, and tracing data exfiltration with minimal manual effort. 

We see that Salvador Stealer operates in two stages: 

• Dropper APK – Silently installs and triggers the second-stage payload. 

• Base.apk (Payload) – The actual credential-stealing component. 

Dropper APK Behavior 

The dropper APK is engineered to install the second-stage malware without the user’s knowledge. It uses specific permissions and intent filters in its AndroidManifest.xml. 

Inside ANY.RUN, we observed the dropper launching a new activity immediately after execution, behavior consistent with silent installations. 

Payload Behavior & Phishing Interface 

Once executed, the payload connects to Telegram, used as a Command and Control (C2) channel and triggers the “starts itself from another location” signature, confirming it was deployed via dropper. 

Real-Time Credential Exfiltration 

After submission, all user data is immediately exfiltrated to: 

• A phishing website controlled by the attacker 

• A Telegram bot used as a backup C2 channel 

ANY.RUN’s HTTPS MITM Proxy mode captured this behavior clearly, allowing us to inspect the exact HTTP requests, destination URLs, and the contents of the exfiltrated data in plaintext.  

This level of visibility is critical when dealing with mobile malware that uses encrypted channels. Teams can immediately verify whether sensitive information was stolen, where it was sent, and how it was packaged, all without reverse-engineering the app or relying on guesswork. It shortens investigation time, boosts detection accuracy, and helps teams extract actionable IOCs in minutes. 

Linux Malware: Uncovering Mirai’s Network Flood Inside the Sandbox 

While Linux systems are often seen as more secure, they’re far from immune, especially when it comes to IoT-targeting malware like Mirai. Built to infect vulnerable devices with weak or default credentials, Mirai turns compromised routers, IP cameras, and other Linux-based systems into part of a massive botnet used for coordinated DDoS attacks. 

In our sandbox session, we ran a Mirai sample inside a Linux virtual environment, revealing exactly how this malware behaves post-infection. 

View the full analysis session 

After running the analysis, the malware began scanning the internet for additional targets, sending out a flood of connection attempts to IP addresses across various ports. The spike in outbound activity was visible in the sandbox’s network traffic tab, highlighting Mirai’s worm-like behavior as it looked to propagate further. 

To add another layer of detection, Suricata rules were triggered during the session, automatically flagging the traffic as malicious and confirming the presence of a Mirai variant. This kind of signature-based alert is crucial for quickly validating what you’re looking at without needing to manually inspect every packet. 

By analyzing Mirai in ANY.RUN, cyber security teams gain: 

• A real-time view of malicious scanning and propagation behavior 

• Easy access to network IOCs, including contacted IPs, ports, and protocols 

• Automated rule-based detection (Suricata) to validate threats instantly 

• A safe environment to test Linux-specific malware, which is often harder to analyze in traditional sandboxes 

Whether you’re defending enterprise infrastructure or monitoring connected devices, ANY.RUN’s support for Linux malware analysis makes it easier to uncover threats that operate below the radar of Windows-based defenses.  

Going Deeper with Pre-Installed Developer Tools 

Not every sample can be cracked with just behavioral analysis, some require deeper inspection, debugging, or code-level investigation. ANY.RUN’s pre-installed development software set is perfect for these purposes. 

Available for Windows 10 (64-bit) VMs, this configuration equips analysts with a curated toolkit tailored for reverse engineering, unpacking, and scripting, all without needing to set anything up manually. 

By selecting the “Development” software set before starting a session, users instantly gain access to tools like Python, Node.js, x64dbg, Detect It Easy, dnSpy, HxD, DebugView, Process Hacker, and more to investigate complex malware like custom loaders, obfuscated stealers, or scripts in Node.js or Python. 

Let’s look at two real-world use cases where this set has been used: 

Example 1: Extracting MSI Files Without Execution 

Using Lessmsi, analysts can safely unpack .msi files and inspect their contents without running them, critical for avoiding accidental payload execution. In one session, this was combined with Detect It Easy (DiE) to analyze extracted binaries and flag suspicious file signatures or packers. 

View analysis session 

Example 2: Debugging Obfuscated Malware with x64dbg 

In another session, x64dbg was used to step through malware execution line by line, helping analysts understand how the sample unpacked itself and interacted with system components; insights that static analysis alone couldn’t reveal. 

View analysis session 

Having these tools built into the sandbox means your team can dig deeper without wasting time setting things up. It speeds up investigations, helps catch more sophisticated threats, and gets you closer to answers when every minute counts. 

A Smarter Way to Investigate Multi-Platform Threats 

Modern malware doesn’t limit itself to one environment, and neither should your analysis. From Windows loaders and Python stealers to Android banking malware and Linux-based botnets, today’s threats are built to adapt. The same sample can behave differently depending on where it runs, dropping different payloads, using OS-specific evasion techniques, or communicating with separate C2 infrastructure. 

Using a different tool for each platform only slows your team down and increases the risk of missing critical behavior. 

ANY.RUN brings everything together in one place. One sandbox where you can detect, investigate, and understand threats, no matter the OS, architecture, or language. Launch analysis sessions across Windows, Linux, and even real Android environments to see how malware acts in each context. 

• Faster Investigations Across Platforms: Skip the tool-switching and analyze samples across operating systems, Windows, Linux, and Android, from one streamlined interface. 

• Deeper Insight into Complex Samples: Whether it’s a Node.js loader or a Python stealer, trace execution, follow obfuscated logic, and unpack evasive behavior with ANY.RUN’s Script Tracer, Pre-Installed Dev toolkit. 

• Clear View of Network Behavior: See how malware communicates, even over encrypted channels or uncommon protocols using HTTPS MITM Proxy and Suricata rule integration. 

• Complete Context Behind Every Attack: Understand the full attack chain, from persistence to exfiltration, through mapped behavior, process trees, ATT&CK matrix, and comprehensive logs. 

• Cloud-Based, Ready-to-Go Malware Analysis: Skip complex setups. Launch your session in seconds with debuggers, interpreters, and network tools already built in. 

• Built for Teamwork and Collaboration: ANY.RUN makes it easy for teams to work together. Share live sessions, tag behaviors, and keep everyone, from analysts to managers, on the same page.  

Join ANY.RUN with your business email to get a 14-day trial of advanced features and see how much faster and deeper your malware investigations can be. 

The post How to Analyze Node.js, Python, Android, and Linux Malware with ANY.RUN  appeared first on ANY.RUN’s Cybersecurity Blog.

ANY.RUN’s Cybersecurity Blog – ​Read More

For an email attack to succeed, the first thing cybercriminals need to do is get their messages in front of potential victims. In a recent post, we covered how scammers leveraged notifications from GetShared — a fully legitimate service for sharing large files. Today, we examine another method for delivering malicious emails. The operators behind this scam have learned to insert custom text into genuine thank-you messages sent by Microsoft 365 to its new business subscribers.

A genuine Microsoft email with a nasty surprise inside

The attack kicks off with a legitimate email in which Microsoft thanks the recipient for purchasing a Microsoft 365 Apps for Business subscription. The email does, in fact, arrive from the Redmond tech giant’s legitimate address: microsoft-noreply@microsoft.com. One would be hard-pressed to imagine an email address with a more trusted reputation, so the message easily gets past any email server filters.

One more time, just so we’re clear: this is an honest-to-goodness email from Microsoft. The contents match a typical purchase confirmation. In the screenshot below, the company thanks the recipient for buying 55 Microsoft 365 Apps for Business subscriptions worth a total of $587.95.

The crux of the scam lies in the text attackers add to the Billing information section. Typically, this section contains the subscriber company’s name and the billing address. However, the scammers swap out that information for their own phone number, plus a note encouraging the recipient to call “Microsoft” if they need any assistance. The types of “purchased” subscriptions suggest that the scammers are targeting company employees.

They prey on a common employee fear: making an expensive, unnecessary purchase could cause trouble at work. And since resolving the issue by email isn’t an option (the message comes from a no-reply address), the victim is left with little choice but to call the phone number provided.

Who answers the calls, and what happens next?

If the victim takes the bait and decides to call to inquire about the subscriptions they’ve supposedly purchased, the scammers deploy social engineering tricks.

A Reddit user, who’d received a similar email and called the number, shared their experience. According to the victim, the person who answered the call insisted on installing some support software, and sent an EXE file. The subsequent conversation suggests that the file contained a RAT of some kind.

The victim didn’t suspect anything was amiss until the scammer promised to refund money to their bank account. That was a red flag, as they shouldn’t have had access to the victim’s banking details. The scammer went on to ask the victim to sign in to their online banking to check if the transaction had gone through.

The victim believes that the software installed on their computer was malware that would have allowed the attackers to intercept their login credentials. Fortunately, they recognized the danger early enough and hung up. Within the same thread, other Reddit users reported similar emails containing various contact details.

How scammers send phishing emails from a genuine Microsoft address

How, exactly, the attackers manage to send Microsoft notifications to their victims is still something of a mystery. The most plausible explanation came from another Reddit user, who suggested that the scam operators were using stolen credentials or trial versions to access Microsoft 365. By using BCC or simply entering the victim’s email address when purchasing a subscription, they can send messages like the one shown in the screenshot above.

An alternative theory is that the scammers gain access to an account with an active Microsoft 365 subscription and then use the billing-information resend feature — specifying the target user as the recipient.

Whichever is true, the attackers’ goal is to replace the billing information — the only part of the Microsoft notification they can alter — with their own phone number.

How to protect yourself against such attacks

Malicious actors keep finding new loopholes in well-known, perfectly legitimate services to use for phishing campaigns and scams. That’s why, to keep an organization secure, you need not only technical protections but also administrative controls. Here’s what we recommend:

• Train your employees to spot potential threats early. This process can be automated with an e-learning tool like Kaspersky Automated Security Awareness Platform.
• Install a robust security solution on every corporate device to fend off spyware, remote access Trojans, and other malware.

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