Microsoft has released its monthly security update for April 2026, which includes 165 vulnerabilities affecting a wide range of products, including eight Microsoft marked as “critical.” 

CVE-2026-23666 is a critical Denial of Service (DoS) vulnerability that affects the .NET framework. Successful exploitation could allow the attacker to deny service over the network.

CVE-2026-32157 is a critical use after free vulnerability in the Remote Desktop Client that results in code execution. Attack requires an authorized user on the client to connect to a malicious server, which could result in code execution on the client. 

CVE-2026-32190 is a critical user after free vulnerability in Microsoft Office that can result in local code execution. Attacker is remote but attack is carried out locally.  Code from the local machine needs to be executed to exploit the vulnerability. 

CVE-2026-33114 is a critical untrusted pointer deference vulnerability in Microsoft Office Word that could allow the attacker to execute code locally. Code from the local machine needs to be executed to exploit this vulnerability.

CVE-2026-33115 is a critical use after free vulnerability in Microsoft Office word that can result in local code execution. Similar to CVE-2026-33114 and CVE-2026-32190 the attacker is remote, but code needs to be executed from the local machine to exploit the vulnerability.

CVE-2026-33824 is a critical double free vulnerability in the Widows Internet Key Exchange (IKE) extension, allowing remote code execution. An unauthenticated attacker can send specially crafted packets to a Windows machine with IKE version 2 enabled to potentially enable remote code execution. Additional mitigations can include blocking inbound traffic on UDP ports 500 and 4500 if IKE is not in use.

CVE-2026-33826 is a critical improper input validation in Windows Active Directory that can result in code execution over an adjacent network. Requires an authenticated attacker to send specially crafted RPC calls to an RPC host. Can result in remote code execution. Note that successful exploitation requires the attacker be in the same restricted Active Directory domain as the target system.

CVE-2026-33827 is a critical race condition vulnerability in Windows TCP/IP that can result in remote code execution. Successful exploitation requires the attacker to win a race condition along with additional actions prior to exploitation to prepare the target environment. An unauthenticated actor can send specially crafted IPv6 packets to a Windows node where IPSec is enabled to potentially achieve remote code execution. 

CVE-2026-32201 is an important improper input validation vulnerability in Microsoft Office SharePoint that can allow an unauthorized user to perform spoofing. An attacker that successfully exploits this vulnerability could view some sensitive information and make changes to disclosed information. This vulnerability has already been detected as being exploited in the wild.

The majority of the remaining vulnerabilities are labeled as important with a two moderate and one low vulnerability also being patched.  Talos would like to highlight the several additional  important vulnerabilities that Microsoft has deemed as “more likely” to be exploited.

·      CVE-2026-0390 – UEFI Secure Boot Security Feature Bypass Vulnerability

·      CVE-2026-26151 – Remote Desktop Spoofing Vulnerability

·      CVE-2026-26169 – Windows Kernel Memory Information Disclosure Vulnerability

·      CVE-2026-26173 – Windows Ancillary Function Driver for WinSock Elevation of Privilege Vulnerability

·      CVE-2026-26177 – Windows Ancillary Function Driver for WinSock Elevation of Privilege Vulnerability

·      CVE-2026-26182 – Windows Ancillary Function Driver for WinSock Elevation of Privilege Vulnerability

·      CVE-2026-27906 – Windows Hello Security Feature Bypass Vulnerability

·      CVE-2026-27908 – Windows TDI Translation Driver (tdx.sys) Elevation of Privilege Vulnerability

·      CVE-2026-27909 – Windows Search Service Elevation of Privilege Vulnerability

·      CVE-2026-27913 – Windows BitLocker Security Feature Bypass Vulnerability

·      CVE-2026-27914 – Microsoft Management Console Elevation of Privilege Vulnerability

·      CVE-2026-27921 – Windows TDI Translation Driver (tdx.sys) Elevation of Privilege Vulnerability

·      CVE-2026-27922 – Windows Ancillary Function Driver for WinSock Elevation of Privilege Vulnerability

·      CVE-2026-32070 – Windows Common Log File System Driver Elevation of Privilege Vulnerability

·      CVE-2026-32075 – Windows UPnP Device Host Elevation of Privilege Vulnerability

·      CVE-2026-32093 – Windows Function Discovery Service (fdwsd.dll) Elevation of Privilege Vulnerability

·      CVE-2026-32152 – Desktop Window Manager Elevation of Privilege Vulnerability

·      CVE-2026-32154 – Desktop Window Manager Elevation of Privilege Vulnerability

·      CVE-2026-32155 – Desktop Window Manager Elevation of Privilege Vulnerability

·      CVE-2026-32162 – Windows COM Elevation of Privilege Vulnerability

·      CVE-2026-32202 – Windows Shell Spoofing Vulnerability

·      CVE-2026-32225 – Windows Shell Security Feature Bypass Vulnerability

·      CVE-2026-33825 – Microsoft Defender Elevation of Privilege Vulnerability

A complete list of all other vulnerabilities Microsoft disclosed this month is available on its update page. In response to these vulnerability disclosures, Talos is releasing a new Snort rule set that detects attempts to exploit some of them. Please note that additional rules may be released at a future date and current rules are subject to change pending additional information. Cisco Security Firewall customers should use the latest update to their ruleset by updating their SRU. Open-source Snort Subscriber Rule Set customers can stay up to date by downloading the latest rule pack available for purchase on Snort.org.  

The rules included in this release that protect against the exploitation of many of these vulnerabilities are: 1:65902-1:65903, 1:66242-1:66251, 1:66259-1:66260, 1:66264-1:66267, 1:66275-1:66276 

The following Snort 3 rules are also available: 1:301398, 1:301468-1:3101472, 1:301475, 1:301477-1:301478, 1:301480

Cisco Talos Blog – ​Read More

Across the Talos 2025 Year in Review, state-sponsored threat activity from China, Russia, North Korea, and Iran all had varying motivations, such as espionage, disruption, financial gain, and geopolitical influence.

But when you look at how these operations actually unfold, similar tactics, techniques, and procedures (TTPs) keep appearing: access through vulnerabilities and identity, and access that remains under the radar for a considerable period of time.

Here are the dominant themes from the state-sponsored section of the Talos Year in Review, available now.

China

China-nexus threat activity stood out this year for both volume and efficiency, with Talos investigations increasing by nearly 75% compared to 2024.

Newly disclosed vulnerabilities were exploited almost immediately (e.g., ToolShell), sometimes before patches were widely available. At the same time, long-standing, unpatched vulnerabilities in networking devices and widely used software continued to provide reliable entry points for these types of adversary.

Once inside, the focus shifts to persistence. Web shells, custom backdoors, tunneling tools, and credential harvesting all support long-term access. 

There’s also more overlap than ever before between state-sponsored and financially motivated activity. It is likely that in some cases, state-sponsored actors conducted operations for personal profit alongside espionage-focused missions, while in others, cybercriminals collected valuable information during an attack that could be sold to espionage-motivated actors for further exploitation, providing them dual revenue streams.

Russia

Russian-linked cyber activity remains closely tied to their geopolitical objectives, particularly the war in Ukraine.

Many operations continue to rely on unpatched, older vulnerabilities (especially in networking devices) to gain initial access. These flaws provide a dependable way in for adversaries and support long-term intelligence gathering.

Russia’s offensive cyber activity is highly correlated with developments in the larger geopolitical sphere. For example, the announcement of sanctions intended to apply pressure on Russia by both the U.S. and E.U. often corresponded with our observed levels of Russian cyber activity.

Common malware families like Dark Crystal RAT (DCRAT), Remcos RAT, and Smoke Loader appeared frequently in Talos investigations on operations against Ukraine in 2025. These families aren’t exclusive to Russia-nexus threat actors, but they continue to be effective in environments where patching and visibility are inconsistent, and should therefore be high priority targets for defense and monitoring.

North Korea

North Korea cyber operations leaned heavily into social engineering and insider access in 2025. These operations were both for financial and espionage purposes.

Campaigns like Contagious Interview (orchestrated by Famous Chollima) used fake recruiters from legitimate companies to socially engineering targets to execute code or hand over credentials. From there, actors stole cryptocurrency, exfiltrated data, and established persistent access.

North Korean cyber actors also pulled off the largest cryptocurrency heist in history in 2025, stealing $1.5 billion. Additionally, thousands of IT workers used stolen identities and AI-generated profiles to secure positions at Fortune 500 companies, generating billions in annual revenue for North Korea’s nuclear weapons and ballistic missiles programs.

Iran

Iranian cyber threat activity in 2025 combined visible disruption with long-term access.

Hacktivist operations increased by 60% in response to geopolitical events, particularly the Israel-Hamas conflict. These campaigns, which include distributed denial-of-service (DDoS) attacks, defacements, and other disruptive operations, are often designed to generate attention and shape narratives.

At the same time, more traditional advanced persistent threat (APT) activity focused on persistence. Groups such as ShroudedSnooper targeted sectors like telecommunications, using custom compact backdoors designed to blend into normal traffic and remain undetected. 

ShroudedSnooper is an APT that public reporting widely attributes to Iran’s Ministry of Intelligence and Security (MOIS). It is very likely an initial access group that passes operations off to secondary threat actors for long term espionage or destructive attacks.

For current threat intelligence related to the developing conflict in Iran, follow our coverage on the Talos blog.

Guidance for defenders

Though the state-sponsored activity that we tracked for the Talos Year in Review have different objectives, they still have the same reliance on gaining and maintaining access. The following guidance is recommended for security teams:

• Don’t ignore older systems: Both newly disclosed and long-known vulnerabilities are actively exploited. 
• Prioritize identity security: Credentialed access and social engineering remain reliable entry points. 
• Increase visibility into network and edge infrastructure: These systems are common targets for persistent access.
• Expect activity to follow global events: Sanctions, conflicts, and political developments often correlate with spikes in activity. Follow the Talos blog to keep informed of new state sponsored activity and campaigns.
• Inspect for long-term presence: Many state-sponsored operations are designed to persist stealthily over time, not trigger immediate disruption. 

Cisco Talos Blog – ​Read More

The smart-home craze has connected everything — from your lightbulbs to your tea kettle — to the internet, and the adult industry isn’t sitting this one out: manufacturers are releasing more smart models than ever. While syncing a sex toy to your smartphone unlocks some cool extra features, it also opens the door to potential security and privacy headaches. The good news? You can significantly lower most of these risks just by tweaking your settings and adjusting your usage habits.

How sex-toy apps actually work

To be clear upfront, while researchers have successfully hijacked sex toys in controlled experiments, the odds of a hacker remotely taking over your vibrator in the real world are pretty slim. In this post, we focus on the more realistic risks: your privacy and the safety of your data.

Most modern adult toys link up with the manufacturer’s app. These apps offer a range of usage options: you can control the device yourself, or hand over the remote to a partner — anywhere in the world via the internet.

Beyond just basic controls, many of these apps have social features: private messaging, group chats, calls, and even video sessions. In fact, you don’t even need a physical device to use some of them; you just create an account. Because of this, some of these services have essentially evolved into niche dating platforms.

The toy and your phone talk to each other via Bluetooth — with minimal risks. To handle social features or remote control, the app connects to a cloud server. This creates a constant stream of data moving back and forth: everything from commands to private messages.

Here’s the catch: even if you only use the app to control your toy locally via Bluetooth, you still get connected to that cloud server. That means you’re inheriting all the security and privacy risks.

The main risks of using sex-toy apps

Sex-toy apps are typically free. In practice, this means the primary way these services make money is by collecting data — which is often excessive. It’s not hard to find buyers of this information; it could be ad services, data brokers, or other companies interested in building detailed user profiles.

Developers of intimate apps suffer from frequent data breaches, and in this sense they’re no different from many other online services that spring a leak regularly. However, unlike a breach at an online pet food store, a data leak from a sex toy app can have much more serious consequences for the user. For sex industry workers, such as those who use webcams, these data breaches pose a direct threat to their physical safety.

Vulnerabilities within the service’s infrastructure warrant special attention. These types of bugs can be exploited by hackers to gain unauthorized access to other people’s accounts.

The inclusion of broad social features essentially turns sex-toy apps into just another messaging platform. However, while we usually know if mainstream messengers use end-to-end encryption, or what vulnerabilities they face, every sex-toy app has to be evaluated individually.

Without end-to-end encryption, user chats may be accessible on the server side. This means that if the service is compromised, the contents of those messages could end up in the hands of hackers. Furthermore, the sex toy manufacturer itself, or its individual employees, could have access to your chats.

Finally, the user’s account and everything in it can be hijacked by bad actors if it isn’t protected by a strong password and, ideally, two-factor authentication.

How to lower the risks when using sex-toy apps

Now that we’ve covered the threats, let’s talk about how to defend yourself. The most obvious choice is to skip installing the app altogether. Thankfully, most sex toys still come with physical buttons — unlike, say, smart mattresses, which often require an app just to function. For those who want the extra features, here are some practical tips for setting up and using these services.

Create an account with a dedicated email address

Set up a separate email address just for registering your account in the intimate app. This should be a “clean” email with no links to any other online services you use. Naturally, the username for this email account shouldn’t include your real name or any other easily identifiable info.

Using an anonymous email protects your reputation if the app suffers a data breach. The risk of this happening is far from theoretical. For instance, back in 2015, a hacking group named The Impact Team leaked the user database of Ashley Madison, a dating site for people seeking extramarital affairs.

To create an anonymous email, pick a service that doesn’t require a phone number at all, or lets you skip that step. Besides your real name, we also recommend leaving out your birth date, your usual social media handles, and any other details that could lead back to you.

Don’t sign up via Google, Apple, social media, or your phone number

The reasoning here is basically the same as the previous point. However, it’s worth highlighting that signing up through Google, Apple, social media, or your phone number is actually just about the worst way to go.

Using Google or social media accounts gives the app permission to, among other things, access certain data from those profiles. In the context of intimate apps, this is especially risky because it creates a direct link between highly sensitive data and your real-world identity.

Keep your real info out of your profile

Once you’re in the app, don’t use any information that could be traced back to you. Come up with an anonymous handle (if you’re feeling uninspired, use a random nickname generator), pick a fake birthday, and choose a random location.

Using fictional info means you don’t have to sweat being outed if the service ever leaks your data. You’re also protecting yourself from stalking, blackmail, and other threats that come with someone being able to pin your real identity to your account.

Hide your face and distinguishing marks when sharing private media

As we’ve mentioned throughout this post, these apps often include social features used for swapping intimate photos and videos. Even if you trust the person you’re chatting with, those files can be saved, forwarded, or used without your consent. When combined with other account info, they can make it easy to figure out who you are.

We recommend never sending intimate media that shows your face or anything else that identifies you — think recognizable home decor, personal items, documents, unique clothing, tattoos, or jewelry.

Set a strong password and enable two-factor authentication, if available

If a hacker breaks into your sex toy account, they’re getting access to your most private data. Because of that, your account needs a rock-solid password. Just to be clear, here’s what we mean by a strong password:

• It’s at least 16 characters long.
• It uses a mix of uppercase and lowercase letters, numbers, and special characters (like $ or @).
• It’s not a real word or a well-known phrase.
• It’s unique and not reused for any of your other accounts.
• It doesn’t include personal info that’s easy for an outsider to find.

We also recommend turning on two-factor authentication (2FA) if the service offers it. Your best bet is to use 2FA one-time codes from an authenticator app, as it’s the most secure and completely anonymous option. You can dive deeper into creating and storing secure passwords, as well as different 2FA methods, in our dedicated blogposts.

Grant only the necessary app permissions

Every mobile app asks for permission to access certain features of your phone like Bluetooth, location, your camera, or your storage. Every extra “yes” you give expands the amount of data the app can scoop up.

We suggest being extra cautious about what you let these services see, especially when it comes to sex-toy apps. By tightening these permissions, you cut down on the amount of info that can be collected or shared without your say-so.

Take a second to think about the absolute bare minimum you’re willing to allow a sex-toy app to access. For example, there’s usually no reason for it to track your location or access your camera and mic. If you do want to upload photos, it’s better to grant access only to specific files rather than giving the app the keys to your entire photo library.

Stop apps from tracking your activity

In your iOS settings, you can block apps from collecting data about what you do and linking it to a single advertising ID. This practice, known as tracking, allows companies to stitch together data from different apps, websites, and services to build a comprehensive profile of you for targeted ads or behavioral analysis.

We strongly recommend disabling tracking for all sex-toy apps so that sensitive details about your private life don’t end up as part of your advertising profile.

Unfortunately, Android doesn’t have an exact equivalent for this setting. To minimize data collection on those devices, you’ll need to turn off ad personalization, and manually delete or reset your advertising ID every now and then. You can find more tips on dodging ad tracking in our dedicated guide.

Keep your apps and operating system up to date

Updates aren’t just about shiny new features; they also fix security bugs. Outdated versions of apps and operating systems often have vulnerabilities that hackers are just waiting to exploit.

Staying on top of your updates helps close these gaps, and lowers the risk of data breaches or unauthorized access. To make sure you don’t miss any critical fixes, it’s best to turn on automatic updates whenever possible.

Security is in your hands

Smart sex-toys and their companion apps naturally handle sensitive data, which means they require extra care when it comes to setup and daily use. That said, you can eliminate — or at least significantly reduce — most risks by following basic security rules. Essentially, it comes down to sharing as little personal info as possible with the app and, of course, using a rock-solid password.

Want more tips on keeping your intimate life private in the digital age? Check out these posts:

• Watching porn safely: a guide for grown-ups
• How to watch porn safely and discreetly
• Fifty shades of sextortion
• AI and the new reality of sextortion
• Google forcing Android System SafetyCore on users to scan for nudes

Kaspersky official blog – ​Read More

At the NDSS Symposium 2026 in San Diego in February, a group of respected researchers presented a study unveiling the AirSnitch attack, which bypasses the Wi-Fi client isolation feature — also commonly known as guest network or device isolation. This attack allows connecting to a single wireless network via an access point, and then gaining access to other connected devices, including those using entirely different service set identifiers (SSIDs) on that same hardware. Targeted devices could easily be running on wireless subnets protected by WPA2 or WPA3 protocols. The attack doesn’t actually break encryption; instead, it exploits the way access points handle group keys and packet routing.

In practical terms, this means that a guest network provides very little in the way of real security. If your guest and employee networks are running on the same physical device, AirSnitch allows a connected attacker to inject malicious traffic into neighboring SSIDs. In some cases, they can even pull off a full-blown man-in-the-middle (MitM) attack.

Wi-Fi security and the role of isolation

Wi-Fi security is constantly evolving; every time a practical attack is made against the latest generation of protection, the industry shifts toward more complex algorithms and procedures. This cycle started with the FMS attacks used to crack WEP encryption keys, and continues to this day: recent examples include the KRACK attacks on WPA2, and the FragAttacks, which impacted every security protocol version from WEP all the way through WPA3.

Attacking modern Wi-Fi networks effectively (and quietly) is no small feat. Most professionals agree that using WPA2/WPA3 with complex keys and separating networks based on their purpose is usually enough for protection. However, only specialists really know that client isolation was never actually standardized within the IEEE 802.11 protocols. Different manufacturers implement isolation in completely different ways — using Layer 2 or Layer 3 of network architecture; in other words, handling it at either the router or the Wi-Fi controller level — meaning the behavior of isolated subnets varies wildly depending on your specific access point or router model.

While marketing claims that client isolation is perfect for keeping restaurant or hotel guests from attacking one another — or ensuring corporate visitors can’t access anything but the internet — in reality, isolation often relies on people not trying to hack it. This is exactly what the AirSnitch research highlights.

Types of AirSnitch attacks

The name AirSnitch doesn’t just refer to a single vulnerability, but a whole family of architectural flaws found in Wi-Fi access points. It’s also the name of an open-source tool used to test routers for these specific weaknesses. However, security professionals need to keep in mind that there’s only a very thin line between testing and attacking.

The model for all these attacks is the same: a malicious client is connected to an access point (AP) where isolation is active. Other users — the targets — are connected to the same SSID or even different SSIDs on that same AP. This is a very realistic scenario; for example, a guest network might be open and unencrypted, or an attacker could simply get the guest Wi-Fi password by posing as a legitimate visitor.

For certain AirSnitch attacks, the attacker needs to know the victim’s MAC or IP address beforehand.  Ultimately, how effective each attack is depends on the specific hardware manufacturer (more on that below).

GTK attack

After the WPA2/WPA3 handshake, the access point and the clients agree on a Group Transient Key (GTK) to handle broadcast traffic. In this scenario, the attacker wraps packets destined for a specific victim inside a broadcast traffic envelope. They then send these directly to the victim while spoofing the access point’s MAC address. This attack only allows for traffic injection, meaning the attacker won’t receive a response. However, even that is enough to deliver malicious ICMPv6 routing advertisements, or DNS and ARP messages to the client — effectively bypassing isolation. This is the most universal version of the attack working on any WPA2/WPA3 network that uses a shared GTK. That said, some enterprise-grade access points support GTK randomization for each individual client, which renders this specific method ineffective.

Broadcast packet redirection

This version of the attack doesn’t even require the attacker to authenticate at the access point first. The attacker sends packets to the AP with a broadcast destination address (FF:FF:FF:FF:FF:FF) and the ToDS flag set to 1.  As a result, many access points treat this packet as legitimate broadcast traffic; they encrypt it using the GTK, and blast it out to every client on the subnet, including the victim. Just like in the previous method, traffic specifically meant for a single victim can be pre-packaged inside.

Router redirection

This attack exploits an architectural gap between Layer 2 and Layer 3 security found in some manufacturers’ hardware. The attacker sends a packet to the access point, setting the victim’s IP address as the destination at the network layer (L3).  However, at the wireless layer (L2), the destination is set to the access point’s own MAC address, so the isolation filter doesn’t trip. The routing subsystem (L3) then dutifully routes the packet back out to the victim, bypassing the L2 isolation entirely. Like the previous methods, this is another transmit-only attack where the attacker can’t see the reply.

Port stealing to intercept packets

The attacker connects to the network using a spoofed version of the victim’s MAC address, and floods the network with ARP responses claiming, “this MAC address is on my port and SSID”.  The target network’s router updates its MAC tables, and starts sending the victim’s traffic to this new port instead. Consequently, traffic intended for the victim ends up with the attacker — even if the victim is connected to a completely different SSID.

In a scenario where the attacker connects via an open, unencrypted network, this means traffic meant for a client on a WPA2/WPA3-secured network is actually broadcast over the open air, where not only the attacker but anyone nearby can sniff it.

Port stealing to send packets

In this version, the attacker connects directly to the victim’s Wi-Fi adapter, and bombards it with ARP requests spoofing the access point’s MAC address. As a result, the victim’s computer starts sending its outgoing traffic to the attacker instead of the network. By running both stealing attacks simultaneously, an attacker can, in several scenarios, execute a full MitM attack.

Practical consequences of AirSnitch attacks

By combining several of the techniques described above, a hacker can pull off some pretty serious moves:

• Complete bidirectional traffic interception for a MitM attack. This means they can snatch and modify data moving between the victim and the access point without the victim ever knowing.
• Hopping between SSIDs. An attacker sitting on a guest network can reach hosts on a locked-down corporate network if both are running off the same physical access point.
• Attacks on RADIUS. Since many companies use RADIUS authentication for their corporate Wi-Fi, an attacker can spoof the access point’s MAC address to intercept initial RADIUS authentication packets. From there, they can brute-force the shared secret. Once they have that, they can spin up a rogue RADIUS server and access point to hijack data from any device that connects to it.
• Exposing unencrypted data from “secure” subnets: Traffic that’s supposed to be sent to a client under the protection of WPA2/WPA3 can be retransmitted onto an open guest network, where it’s essentially broadcast for anyone to hear.

To pull off these attacks effectively, a hacker needs a device capable of simultaneous data transmission and reception with both the victim’s adapter and the access point. In a real-world scenario, this usually means a laptop with two Wi-Fi adapters running specifically configured Linux drivers. It’s worth noting that the attack isn’t exactly silent: it requires a flood of ARP packets, it can cause brief Wi-Fi glitches when it starts, and network speeds might tank to around 10Mbps. Despite these red flags, it’s still very much a practical threat in many environments.

Vulnerable devices

As part of the study, several enterprise and home access points and routers were put to the test. The list included products from Cisco, Netgear, Ubiquiti, Tenda, D-Link, TP-Link, LANCOM, and ASUS, as well as routers running popular community firmware like DD-WRT and OpenWrt. Every single device tested was vulnerable to at least some of the attacks described here. Even more concerning, the D-Link DIR-3040 and LANCOM LX-6500 were susceptible to every single variation of AirSnitch.

Interestingly, some routers were equipped with protective mechanisms that blocked the attacks, even though the underlying architectural flaws were still present. For example, the Tenda RX2 Pro automatically disconnects any client whose MAC address appears on two BSSIDs simultaneously, which effectively shuts down port stealing.

The researchers emphasize that any network administrator or IT security team serious about defense should test their own specific configurations. That’s the only way to pinpoint exactly which threats are relevant to your organization’s setup.

How to protect your corporate network from AirSnitch

The threat is most immediate for organizations running guest and corporate Wi-Fi networks on the same access points without additional VLAN segmentation. There are also significant risks for companies using RADIUS with outdated settings or weak shared secrets for wireless authentication.

The bottom line is that we need to stop viewing client isolation on an access point as a real security measure, and start seeing it as just a convenience feature. Real security needs to be handled differently:

• Segment the network using VLANs. Each SSID should have its own VLAN, with strict 802.1Q packet tagging maintained all the way from the access point to the firewall or router.
• Implement stricter packet inspection at the routing level — depending on the hardware capabilities. Features like Dynamic ARP Inspection, DHCP snooping, and limiting the number of MAC addresses per port help defend against IP/MAC spoofing.
• Enable individual GTK keys for each client, if your equipment supports it.
• Use more resilient RADIUS and 802.1X settings, including modern cipher suites and robust shared secrets.
• Log and analyze EAP/RADIUS authentication anomalies in your SIEM. This helps track many attack attempts beyond just AirSnitch. Other red flag events to watch for include the same MAC address appearing on different SSIDs, spikes in ARP requests, or clients rapidly jumping between BSSIDs or VLANs.
• Apply security at higher levels of the network topology. Many of these attacks lose their punch if the organization has universally implemented TLS and HSTS for all business application traffic, requires an active VPN for all Wi-Fi connections, or has fully embraced a Zero Trust architecture.

Kaspersky official blog – ​Read More

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

“Study hard what interests you the most in the most undisciplined, irreverent and original manner possible.” ― Richard Feynman  

“I had discovered that learning something, no matter how complex, wasn’t hard when I had a reason to want to know it.” ― Homer Hickam, Rocket Boys  

*looks around at – gestures – everything*  

*opens a new tab in the browser, takes in the newest news on AI, a new tab on supply chains, a new tab on vulnerability, and a new tab on active exploitation and zero-days*   

*closes tabs and throws laptop into the nearest bin, à la Ron Swanson*  

*opens other laptop, avoids the internet*  

*puts on headphones for deep work binaural audio*  

*cracks knuckles*  

I’m often asked about why I bring up board games and video games when interviewing perspective analysts or threat hunters, so I’m going to give the 8,000 foot view on my thoughts. With everything that is going on, now more than ever we need the most curious people on the planet on our side.   

What’s the very first and most important step to securing any environment? Knowing the environment, inside and out. When you play any gameyou must understand the rules: the standard opening moves of chess, or Go, or perhaps the common resource-gathering patterns in strategy games. Once you understand what “normal” play looks like, you can immediately spot when an opponent makes a move that is inefficient or unusual — an anomalous trigger that, if spotted, can lead to victory.   

When experienced players recognize patterns (a specific chess gambit, a defensive build in a strategy game, etc.), they don’t just react to the current move — they predict several moves into the future from both players, especially if they know their opponents’ tendencies. As players gain experience and play against other skilled players, they begin involving feints or decoys (false flags, if you will). A player might sacrifice a minor piece to distract you from their true objective. Learning to look past that “noise” to find the real motivation is the key to taking your experience and skill to the next level.   

Threat actors rarely follow a predictable script. They constantly evolve tactics, techniques, and procedures (TTPs). Developing the mental flexibility to handle those unexpected, non-standard behaviors is essential in identifying the unknowns.  

The transition from board games to threat hunting is rooted in the development of critical thinking and situational awareness. While board games provide a controlled environment to practice these skills, the core competency — that ability to identify the why behind a deviation — is exactly what will make you a successful threat hunter.  

“I prefer to speak in metaphor: That way, no logic can trap me, and no rule can bind me, and no fact can limit me or decide for me what’s possible.” ― Claire Oshetsky, Chouette 

The one big thing 

Cisco Talos has observed threat actors weaponizing legitimate SaaS notification pipelines, such as those in GitHub and Jira, to deliver phishing and spam emails. By leveragingthese platforms’ official infrastructure, attackers bypass traditional email authentication protocols like SPF, DKIM, and DMARC. This “Platform-as-a-Proxy” (PaaP) technique exploits the implicit trust organizations place in system-generated notifications to facilitate credential harvesting. These campaigns effectively mask malicious intent behind the reputation of trusted enterprise tools. 

Why do I care? 

Traditional email security gateways are often blind to these attacks because the emails are technically authenticated and originate from verified, trusted domains. This technique exploits “automation fatigue,” where users are conditioned to reflexively trust system-generated alerts from business-critical platforms. Consequently, attackers can bypass standard perimeter defenses, making it harder to distinguish between legitimate business communications and sophisticated phishing attempts. 

So now what? 

Transition to a Zero-Trust approach by implementing instance-level verification and cross-referencing notifications against internal SaaS directories. Security teams should ingest SaaS API logs into their SIEM to detect anomalous precursor activities, such as suspicious project creation or mass invitations. Additionally, introduce friction for high-risk interactions by requiring out-of-band verification and apply semantic intent analysis to identify notifications that deviate from a platform’s established functional baseline. 

Top security headlines of the week 

Tech giants launch AI-powered “Project Glasswing” 
Major technology companies have joined forces in an effort to use advanced artificial intelligence to identify and address security flaws in the world’s most critical software systems. (CyberScoop) 

Russian government hackers broke into thousands of home routers to steal passwords 
Fancy Bear, or APT 28, is known for its high-profile hacks and spying operations, including the breach of the U.S. Democratic National Committee in 2016 and the destructive hack that hit satellite provider Viasat in 2022. (TechCrunch) 

Storm-1175 deploys Medusa ransomware at “high velocity” 
Storm-1175 has rapidly exploited more than a dozen n-days, the most recent of which is CVE-2026-1731, a critical remote code execution flaw in BeyondTrust Remote Support and older versions of the vendor’s Privileged Remote Access. (Dark Reading) 

North Korean hackers pose as trading firm to steal $285M from Drift 
A group of individuals approached Drift staff at a “major crypto conference,” presenting as a professional quantitative trading firm. They went so far as to deposit $1M of their own money into a Drift Ecosystem Vault between December 2025 and January 2026. (HackRead) 

Telehealth giant Hims & Hers says its customer support system was hacked 
A spokesperson for Hims & Hers said the company was hit by a social engineering attack, and the stolen data “primarily included customer names and email addresses.” (TechCrunch) 

Can’t get enough Talos? 

New Lua-based malware observed in targeted attacks against Taiwanese organizations 
Cisco Talos uncovered a cluster of activity we track as UAT-10362 conducting spear-phishing campaigns against Taiwanese non-governmental organizations (NGOs) and suspected universities to deliver a newly identified malware family, “LucidRook.” 

Vulnerabilities old and new and something React2 
2025 was characterized by an unending beat-down on infrastructure that relied on older enmeshed dependencies (e.g., Log4j and PHPUnit), while React2Shell rocketed to the highest percentage of attacks for the entire year within the last three weeks of the year. 

From the field to the report and back again 
The same Year in Review report that Talos IR casework feeds into is the report that defenders should be feeding back into their own preparation cycles. Here’s how you can start. 

Talos Takes: 2025’s ransomware trends and zombie vulnerabilities 
In this episode, Amy and Pierre Cadieux unpack the ransomware and vulnerability trends that defined 2025. From the persistent ransomware threats targeting the manufacturing sector to the rise of stealthy “living off the land” tactics, we break down what these shifts mean for your defense strategy. 

Upcoming events where you can find Talos 

• OffensiveCon (May 15 – 16) Berlin, Germany 

Most prevalent malware files from Talos telemetry over the past week 

SHA256: 9f1f11a708d393e0a4109ae189bc64f1f3e312653dcf317a2bd406f18ffcc507  
MD5: 2915b3f8b703eb744fc54c81f4a9c67f  
Talos Rep: https://talosintelligence.com/talos_file_reputation?s=9f1f11a708d393e0a4109ae189bc64f1f3e312653dcf317a2bd406f18ffcc507 
Example Filename: VID001.exe  
Detection Name: Win.Worm.Coinminer::1201 

SHA256: 90b1456cdbe6bc2779ea0b4736ed9a998a71ae37390331b6ba87e389a49d3d59 
MD5: c2efb2dcacba6d3ccc175b6ce1b7ed0a  
Talos Rep: https://talosintelligence.com/talos_file_reputation?s=90b1456cdbe6bc2779ea0b4736ed9a998a71ae37390331b6ba87e389a49d3d59 
Example Filename: APQ9305.dll  
Detection Name: Auto.90B145.282358.in02 

SHA256: 38d053135ddceaef0abb8296f3b0bf6114b25e10e6fa1bb8050aeecec4ba8f55  
MD5: 41444d7018601b599beac0c60ed1bf83  
Talos Rep: https://talosintelligence.com/talos_file_reputation?s=38d053135ddceaef0abb8296f3b0bf6114b25e10e6fa1bb8050aeecec4ba8f55 
Example Filename: content.js  
Detection Name: W32.38D053135D-95.SBX.TG 

SHA256: a31f222fc283227f5e7988d1ad9c0aecd66d58bb7b4d8518ae23e110308dbf91  
MD5: 7bdbd180c081fa63ca94f9c22c457376  
Talos Rep: https://talosintelligence.com/talos_file_reputation?s=a31f222fc283227f5e7988d1ad9c0aecd66d58bb7b4d8518ae23e110308dbf91  
Example Filename: d4aa3e7010220ad1b458fac17039c274_62_Exe.exe 
Detection Name: Win.Dropper.Miner::95.sbx.tg** 

SHA256: 96fa6a7714670823c83099ea01d24d6d3ae8fef027f01a4ddac14f123b1c9974  
MD5: aac3165ece2959f39ff98334618d10d9  
Talos Rep: https://talosintelligence.com/talos_file_reputation?s=96fa6a7714670823c83099ea01d24d6d3ae8fef027f01a4ddac14f123b1c9974 
Example Filename: d4aa3e7010220ad1b458fac17039c274_63_Exe.exe  
Detection Name: W32.Injector:Gen.21ie.1201 

SHA256: 5e6060df7e8114cb7b412260870efd1dc05979454bd907d8750c669ae6fcbcfe  
MD5: a2cf85d22a54e26794cbc7be16840bb1  
Talos Rep: https://talosintelligence.com/talos_file_reputation?s=5e6060df7e8114cb7b412260870efd1dc05979454bd907d8750c669ae6fcbcfe  
Example Filename: a2cf85d22a54e26794cbc7be16840bb1.exe  
Detection Name: W32.5E6060DF7E-100.SBX.TG

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