UK-Filed Patent Introduces a New Standard for Securing Software in the Quantum Computing Era - APN News

As quantum technologies move closer to real-world deployment, cybersecurity analysts are increasingly highlighting a growing gap between emerging computational models and existing security frameworks. Many widely adopted approaches to secure software development were designed for deterministic, classical systems and do not account for the probabilistic behaviour and optimisation-driven execution paths introduced by quantum and hybrid quantum–classical environments. A recently filed UK patent has drawn attention within the cybersecurity community for proposing a structured response to this challenge. The patent introduces the Quantum Injection Attack Risk Management Framework (QIA-RMF), a methodology designed to identify, assess, and mitigate a newly defined class of threats referred to as Quantum Injection Attacks across the Secure Software Development Lifecycle (SSDLC). The framework was developed by Bisola Faith Kayode, a cybersecurity and emerging-technology specialist. Industry observers note that the framework’s significance lies in its formal treatment of quantum-influenced risks as a distinct threat category, rather than an extension of existing classical attack models. “Most current security frameworks focus on cryptographic resilience,” said one cybersecurity researcher familiar with post-quantum systems, “but they do not address the behavioural and governance risks introduced by quantum optimisation and hybrid execution environments. That gap is becoming increasingly visible.” QIA-RMF embeds quantum-aware risk controls into system design, secure coding, testing, deployment, and runtime monitoring. Unlike established models such as STRIDE, NIST SSDF, ISO 27034, or traditional DevSecOps approaches, the framework explicitly accounts for non-deterministic outputs, optimisation bias, and hybrid system behaviour. Analysts view this as an early attempt to formalise governance and risk management for software systems that incorporate or interact with quantum computation. As organisations experiment with quantum optimisation, quantum machine learning, and advanced hybrid architectures, there is growing consensus that cybersecurity strategies will need to evolve beyond classical assumptions. Commentators suggest that patent-led frameworks such as QIA-RMF reflect a broader shift toward proactive, structured approaches to managing quantum-era security risks, rather than retrofitting existing controls after deployment. By securing formal intellectual property protection and placing the framework into public technical discourse, the QIA-RMF contributes to ongoing discussions around post-quantum and hybrid-system security, offering organisations an early reference point for addressing cybersecurity challenges in the quantum computing era.