In a context where digital innovation drives competitiveness, “vibe coding” is generating growing enthusiasm. This practice involves automatically producing code via AI from simple textual descriptions, accelerating the product exploration phase.
Speed and simplicity are key, enabling idea validation without deep technical expertise. But while vibe coding proves ideal for building an MVP or proof of concept, its limitations emerge as soon as the prototype needs to enter a real environment. Structural flaws, technical debt, security vulnerabilities, and lack of scalability can quickly turn a demonstration into a major risk for the organization.
Accelerating the Exploration Phase: The Advantages of Vibe Coding
Vibe coding drastically reduces prototyping timeframes without engaging a dedicated development team. It provides a low-code/no-code entry point to test features and gain a functional preview in just a few days.
Ultra-Fast Prototyping
The core of vibe coding relies on AI models capable of translating a textual specification into operational software components. Using these tools eliminates the traditional configuration steps and setup of a development environment.
During the exploration phase, decision-makers can iterate on multiple concepts, test different interfaces, and adjust the functional scope without waiting for traditional development schedules. This flexibility fosters rapid experimentation.
The result is an interactive prototype usable for internal demos, workshops with business teams, or client presentations. The production outlook remains secondary, as the primary objective is to validate or invalidate an idea.
Accessibility for Non-Technical Profiles
Vibe coding lowers the technical barrier by addressing project managers, business leads, or marketers who may not master a programming language. They can describe their needs and obtain a functional prototype.
This promotes collaboration between IT and business teams, speeds up decision-making processes, and reduces the back-and-forth often required to translate needs into technical specifications. The tool becomes a mediator between strategic vision and implementation.
By standardizing instructions as prompts, it is even possible to capitalize on use-case scenarios and templates to further accelerate subsequent prototypes. Skill development becomes more vertical, focused on orchestration rather than pure coding.
Focus on Speed Over Robustness
By design, AI favors rapid generation of executable code without guaranteeing quality or scalability. The trained models are oriented toward “functionality at the moment” rather than a sustainable architecture.
This approach implicitly means foregoing coding conventions, modular structures, or comprehensive unit and integration tests. The generated code may contain duplications, monolithic modules, or poorly managed dependencies.
Thus, while speed is crucial for testing a hypothesis, the lack of structural rigor becomes apparent when additional features need to be added, data access must be secured, or sustained load must be supported.
Use Case: Finance
An SME in the financial services sector used vibe coding to prototype a client portfolio management platform. In three days, a functional prototype allowed visualization of key performance indicators.
However, when real data and external users were integrated, the generated architecture revealed inconsistencies: duplicated modules, lack of fine-grained access controls, and difficulties connecting to an existing authentication service.
This feedback demonstrates that vibe coding remains relevant for validating an idea or leading a workshop, but it cannot alone support the demands of a product in production.
The Rapid Obsolescence of Generated Architecture
The code automatically produced by AI does not adhere to sustainable architectural principles, leading to rapid obsolescence. The compromises made to accelerate creation undermine maintainability and scalability in the medium term.
Instant Technical Debt
Each AI code generation can introduce shortcuts: lack of clear separation between business and presentation layers, overly coupled modules, or inconsistent naming conventions. These choices speed up the initial delivery but come at a high cost during the first refactoring.
Technical debt manifests as an accumulation of fixes, patches, and workarounds. As features are added, the code becomes fragile, and each change triggers unforeseen side effects.
The result is a constraining cycle where the team must devote most of its time to stabilizing and troubleshooting the prototype, at the expense of functional evolution and business value.
Structural Inconsistencies and Deployment
AI does not conceive a global system vision and does not account for existing integration patterns. Generated modules may bypass internal APIs, reinvent the wheel, or ignore shared services.
When deploying to staging or production environments, these inconsistencies lead to duplicates, version conflicts, or missing configurations. The CI/CD pipeline fails to run without manual adjustments.
It then becomes necessary to rewrite portions of code to align the architecture, restore conventions, or integrate existing frameworks, partially negating the initial time savings.
Use Case: Manufacturing Industry
A manufacturing industry company used AI to generate a production performance dashboard. In a few days, a functional prototype displayed the main efficiency indicators.
However, when connecting to real-time control systems, the AI-generated architecture exhibited inconsistencies: duplicated modules, lack of data validation, and difficulty integrating existing sensors.
This experience illustrates that while vibe coding can help test a concept, it requires a rewrite to meet the technical demands of a real environment.
Use Case: Healthcare
A healthcare organization used AI to generate an internal application for tracking document validation requests. The prototype worked perfectly in tests with a few users.
Then, when opened to all staff members, the application did not support multi-role scenarios: workflow business rules were not applied, and it was impossible to add a reporting module without disrupting the existing system.
This example shows that an AI-generated prototype must be thoroughly reviewed before any production rollout, or functional and technical limits will quickly arise.
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Underestimated Security and Compliance Risks
Vibe coding rarely generates secure configurations and control mechanisms that meet regulatory requirements. The lack of automated testing and security audits exposes the product to critical vulnerabilities.
Default Vulnerabilities and Lack of Hardening
By default, the generated code often incorporates basic practices for authentication, encryption, or session management. AI models do not necessarily know the internal policies or ISO/NIST standards to apply.
Without manual auditing or post-generation hardening, you end up with unprotected entry points, outdated dependencies, or overly broad database permissions.
These vulnerabilities can be exploited during development testing or, worse, once the application is in production with sensitive data.
Lack of Test and Audit Coverage
Unit, integration, and security tests (SAST/DAST scans) are not part of the automated vibe coding workflow. Each generator simply produces executable code without ensuring quality or compliance.
Without a robust CI/CD pipeline and appropriate test data sets, critical regressions easily slip through. Minor changes can break the application without warning, and known vulnerabilities remain unaddressed.
It is therefore essential to systematically complement the process with a manual code review, a vulnerability audit, and the integration of automated tests before any production deployment.
Non-Compliance with Standards and Regulations
Regulated sectors (finance, healthcare, insurance) impose strict requirements for data storage, encryption, and traceability. AI does not always anticipate these constraints and produces generic code that does not comply with specific frameworks.
Integrating consent mechanisms, detailed logs, or retention policies requires additional layers of work and often a significant rewrite of the initial code.
Omitting these steps can lead to financial penalties, production deployment blocks, or lengthy and costly compliance procedures.
How to Integrate AI to Strengthen Rather Than Replace Software Engineering
AI is a productivity amplifier, not a substitute for human expertise in architecture and security. High-performing teams combine AI prompt creativity with strict governance and proven quality standards.
Complementarity Between Developers and AI
Rather than delegating all development to AI, engineers use it to generate code skeletons, snippets, or unit tests automatically. They focus on system vision, architectural choices, and business optimization.
This hybrid approach reduces the burden of repetitive tasks and frees up time for high-value activities: designing modular solutions, code review, and performance management.
Developers remain masters of technical decisions, guiding AI via structured prompts and predefined frameworks (templates, guidelines, and patterns).
Best Practices for Framing Vibe Coding
It is essential to document a clear process: generation phases, code reviews, unit and integration tests, security audits, and final packaging. Each step must be formalized and integrated into a CI/CD pipeline.
Governance and Modular Architecture
Adopting an architecture based on microservices or decoupled modules facilitates the integration of AI-generated components. Each service has its own lifecycle and can be tested and deployed independently.
Implementing an internal catalog of approved templates, security blueprints, and performance guidelines ensures consistency regardless of the generation source.
Finally, agile governance involving IT leadership, architects, and business stakeholders ensures regular reviews of AI deliverables, adjustment of priorities, and adherence to longevity and ROI objectives.
Leverage Vibe Coding While Securing Your Product
Vibe coding is a boon for accelerating exploration phases and prototyping solutions at low cost. However, its use must not replace a rigorous software engineering approach. From prototype to production, it is imperative to regain control over architecture, security, scalability, and code quality.
The most successful organizations use AI to boost their speed while maintaining clear governance, high technical standards, and human expertise at the core of the process. Our Edana experts can support you in integrating AI to deliver robust, scalable engineering, ensuring risk management and the longevity of your digital products.
