diff --git a/windows/security/threat-protection/overview-of-threat-mitigations-in-windows-10.md b/windows/security/threat-protection/overview-of-threat-mitigations-in-windows-10.md
index 328c784d99..e5fa9cb4bc 100644
--- a/windows/security/threat-protection/overview-of-threat-mitigations-in-windows-10.md
+++ b/windows/security/threat-protection/overview-of-threat-mitigations-in-windows-10.md
@@ -64,7 +64,7 @@ Windows 10 mitigations that you can configure are listed in the following two ta
 | **Windows Defender Antivirus**,<br>which helps keep devices<br>free of viruses and other<br>malware | Windows 10 includes Windows Defender Antivirus, a robust inbox antimalware solution. Windows Defender Antivirus has been significantly improved since it was introduced in Windows 8.<br><br>**More information**: [Windows Defender Antivirus](#windows-defender-antivirus), later in this topic |
 | **Blocking of untrusted fonts**<br> helps prevent fonts<br>from being used in<br>elevation-of-privilege attacks | Block Untrusted Fonts is a setting that allows you to prevent users from loading fonts that are "untrusted" onto your network, which can mitigate elevation-of-privilege attacks associated with the parsing of font files. However, as of Windows 10, version 1703, this mitigation is less important, because font parsing is isolated in an [AppContainer sandbox](https://docs.microsoft.com/windows/win32/secauthz/appcontainer-isolation) (for a list describing this and other kernel pool protections, see [Kernel pool protections](#kernel-pool-protections), later in this topic).<br><br>**More information**: [Block untrusted fonts in an enterprise](/windows/threat-protection/block-untrusted-fonts-in-enterprise) |
 | **Memory protections**<br> help prevent malware<br>from using memory manipulation<br>techniques such as buffer<br>overruns | These mitigations, listed in [Table 2](#table-2), help to protect against memory-based attacks, where malware or other code manipulates memory to gain control of a system (for example, malware that attempts to use buffer overruns to inject malicious executable code into memory. Note:<br>A subset of apps will not be able to run if some of these mitigations are set to their most restrictive settings. Testing can help you maximize protection while still allowing these apps to run.<br><br>**More information**: [Table 2](#table-2), later in this topic |
-| **UEFI Secure Boot**<br> helps protect<br>the platform from<br>bootkits and rootkits | Unified Extensible Firmware Interface (UEFI) Secure Boot is a security standard for firmware built in to PCs by manufacturers beginning with Windows 8. It helps to protect the boot process and firmware against tampering, such as from a physically present attacker or from forms of malware that run early in the boot process or in kernel after startup.<br><br>**More information**: [UEFI and Secure Boot](/windows/device-security/bitlocker/bitlocker-countermeasures#uefi-and-secure-boot)</a> |
+| **UEFI Secure Boot**<br> helps protect<br>the platform from<br>boot kits and rootkits | Unified Extensible Firmware Interface (UEFI) Secure Boot is a security standard for firmware built in to PCs by manufacturers beginning with Windows 8. It helps to protect the boot process and firmware against tampering, such as from a physically present attacker or from forms of malware that run early in the boot process or in kernel after startup.<br><br>**More information**: [UEFI and Secure Boot](/windows/device-security/bitlocker/bitlocker-countermeasures#uefi-and-secure-boot)</a> |
 | **Early Launch Antimalware (ELAM)**<br> helps protect<br>the platform from<br>rootkits disguised as drivers | Early Launch Antimalware (ELAM) is designed to enable the antimalware solution to start before all non-Microsoft drivers and apps. If malware modifies a boot-related driver, ELAM will detect the change, and Windows will prevent the driver from starting, thus blocking driver-based rootkits.<br><br>**More information**: [Early Launch Antimalware](/windows/device-security/bitlocker/bitlocker-countermeasures#protection-during-startup) |
 | **Device Health Attestation**<br> helps prevent<br>compromised devices from<br>accessing an organization's<br>assets | Device Health Attestation (DHA) provides a way to confirm that devices attempting to connect to an organization's network are in a healthy state, not compromised with malware. When DHA has been configured, a device's actual boot data measurements can be checked against the expected "healthy" boot data. If the check indicates a device is unhealthy, the device can be prevented from accessing the network.<br><br>**More information**: [Control the health of Windows 10-based devices](/windows/device-security/protect-high-value-assets-by-controlling-the-health-of-windows-10-based-devices) and [Device Health Attestation](https://docs.microsoft.com/windows-server/security/device-health-attestation) |
 
@@ -225,7 +225,7 @@ Windows 10 has several important improvements to the security of the heap:
 
 - **Heap allocation randomization**, that is, the use of randomized locations and sizes for heap memory allocations, which makes it more difficult for an attacker to predict the location of critical memory to overwrite. Specifically, Windows 10 adds a random offset to the address of a newly allocated heap, which makes the allocation much less predictable.
 
-- **Heap guard pages** before and after blocks of memory, which work as tripwires. If an attacker attempts to write past a block of memory (a common technique known as a buffer overflow), the attacker will have to overwrite a guard page. Any attempt to modify a guard page is considered a memory corruption, and Windows 10 responds by instantly terminating the app.
+- **Heap guard pages** before and after blocks of memory, which work as trip wires. If an attacker attempts to write past a block of memory (a common technique known as a buffer overflow), the attacker will have to overwrite a guard page. Any attempt to modify a guard page is considered a memory corruption, and Windows 10 responds by instantly terminating the app.
 
 ### Kernel pool protections
 
@@ -275,7 +275,7 @@ Windows 10 includes an entirely new browser, Microsoft Edge. Microsoft Edge is m
 
 In addition to Microsoft Edge, Microsoft includes IE11 in Windows 10, primarily for backwards-compatibility with websites and with binary extensions that do not work with Microsoft Edge. It should not be configured as the primary browser but rather as an optional or automatic switchover. We recommend using Microsoft Edge as the primary web browser because it provides compatibility with the modern web and the best possible security.
 
-For sites that require IE11 compatibility, including those that require binary extensions and plug ins, enable Enterprise mode and use the Enterprise Mode Site List to define which sites have the dependency. With this configuration, when Microsoft Edge identifies a site that requires IE11, users will automatically be switched to IE11.
+For sites that require IE11 compatibility, including those that require binary extensions and plug-ins, enable Enterprise mode and use the Enterprise Mode Site List to define which sites have the dependency. With this configuration, when Microsoft Edge identifies a site that requires IE11, users will automatically be switched to IE11.
 
 ### Functions that software vendors can use to build mitigations into apps