RF Safe critiques the anti-radiation phone case market for relying on headline percentage-blocking claims that may reflect tests of shielding material rather than real-world phone behavior in a case on a live network. The article argues that poorly designed or misused shielding cases can interfere with a phone’s signal and prompt higher transmit power, potentially increasing exposure in some scenarios. It positions RF Safe’s QuantaCase/TruthCase as avoiding percentage marketing claims and emphasizes a systems-engineering approach to testing and use, while noting that health causation from typical consumer RF exposure remains debated by authorities.

RF Safe argues that “anti-radiation” phone case marketing based on universal “99% blocking” claims is misleading because real-world phone emissions vary with signal conditions, orientation, and how a case affects the antenna. The post positions RF Safe’s TruthCase/QuantaCase as more credible specifically because it refuses to advertise a single percentage reduction and instead emphasizes design constraints intended to avoid prompting a phone to increase transmit power. It cites a KPIX 5 (CBS San Francisco) test as an example of how flip cases can reduce exposure in some configurations but potentially increase it in others when used differently than intended.

RF Safe argues that many “anti-radiation” phone cases use misleading marketing (e.g., fabric-swatch tests, vague “FCC tested” claims) and that some designs may cause phones to increase transmit power if they interfere with antennas. The article provides a checklist of red flags (magnets/metal plates, detachable shields, unclear orientation instructions) and emphasizes behavioral steps to reduce RF exposure. It promotes RF Safe’s QuantaCase as a “directional shielding” design intended to reduce exposure on the body-facing side while avoiding signal blockage that could prompt higher power output.

An RF Safe commentary argues that persistent, pulsed “non-native” RF electromagnetic noise can disrupt biological “timing coherence,” leading to downstream “fidelity losses,” particularly in electrically active tissues. It also emphasizes that smartphones are adaptive RF systems that change transmit power and modulation, so accessories that detune antennas or distort near-field conditions may cause phones to transmit harder. The piece cites FTC warnings that partial-shield products can be ineffective and may increase emissions by interfering with signal quality, and it argues that material shielding claims do not directly translate to real-world exposure outcomes.

An RF Safe blog post written in a first-person “Grok” voice argues that many anti-radiation phone cases are ineffective or can increase exposure by causing phones to boost transmit power. It recommends the QuantaCase™ as the best option in late 2025, claiming it “delivers on physics” and avoids common design pitfalls seen in competing products. The post references WHO’s position that low-level exposure is not proven harmful in humans while also citing animal research (e.g., NTP) and proposed mechanisms (e.g., oxidative stress) to justify precautionary use.