Medical Device Development Process Step 2 Product Design

Medical Device Development Process Step 2: Product Design

Medical Device Development Process Step 2 Product Design

Transforming a medical device from concept to commercial product involves extensive product design efforts. Structured product development processes guide an invention through incremental prototypes, comprehensive testing, and design refinements to arrive at an optimized commercial device.

In this installment of our medical device development processes, we explore DeviceLab’s stepwise approach to maturing medical device designs to meet user needs, clinical demands, and market requirements. Beginning with early research and development, we progress through proof-of-concept, alpha prototype, beta prototype, and pilot production phases. Each stage yields valuable user feedback and insights to improve subsequent iterations.

Thorough design verification and validation testing ensure the medical device meets product requirements and specifications. Human factors evaluations confirm usability and safety for the intended use environment. A streamlined design transfer provides manufacturing teams with comprehensive documentation to initiate production. When executed effectively, the product design process delivers innovative medical products with strong clinical and commercial value.

Early Research and Development (R&D)

The early R&D phase lays the groundwork for medical device product design efforts. Market research, user studies, and technical assessments nurture a concept into a clearer product direction. Early deliverables give tangible shape to possibilities while gathering powerful feedback to focus design priorities.

Clarifying Design Objectives

The R&D phase initiates with an examination of user needs and technology possibilities relevant to the medical device concept. Interviews and observations identify pain points in clinical environments. Technical capabilities are researched based on current IP and adjacent innovations. Competitive solutions establish benchmarks for product performance and features. These inputs shape well-defined design objectives and product requirements to channel downstream efforts.

Early Design Deliverables

With directional clarity, the concept takes physical form through early deliverables:

  • Mockups: Sketches, renderings, and 3D models visualize industrial design language, ergonomics, and user/patient interactions.
  • Apps: Software prototypes demonstrate workflow, interface design, and connected capabilities.
  • Models: 3D printed models provide hands-on design feedback around grip, balance, buttons, display visibility, and other human factors.

These tangible concept manifestations, though not functioning, enable invaluable user testing and design refinement before resource-intensive engineering phases.

Early R&D activity solidifies the product vision and explores possibilities through models.

Deliverables provide tools to crystallize user-centric designs before heavy investment in engineering and prototypes.

Proof of Concept

The proof of concept phase transforms an idea into reality by demonstrating key aspects of the medical device function as expected. Simple prototypes test hypotheses around critical questions, technologies, or user interactions. Data provides evidence of feasibility while uncovering areas needing refinement.

Validating Technical Feasibility

Proof of concept prototypes focuses on features where uncertainty exists. For example, can a novel imaging approach actually detect the anatomical signatures it promises? Does a new surgical tool access tight spaces in practice? Can a diagnostic device produce accurate biomarker outputs? Dedicated subsystem models answer these questions with real-world functionality tests.

Proof of Concept Deliverables

The proof of concept prototype incarnates the simplest model to test assumptions and achieve “good enough” performance to inform the next steps. An accompanying testing plan gathers quantitative and qualitative data from simulated use. Results affirm technical viability while shedding light on improvements for subsequent iterations. Feedback validates user workflows and human factors assumptions.

The proof of concept phase builds selective prototypes to confirm or deny key questions around critical functions, technologies, and user interactions. Data reveals maturity level and priority refinement areas to succeed in more advanced prototypes.

Alpha Prototype Design and Testing

With proof of concept confidence, the alpha prototype phase creates the first fully featured model and tests subsystems together. An integrated device tests workflows, explores human factors, and allows comprehensive performance evaluation. Insights feed the next iteration.

Detailed System Design

Armed with knowledge of how critical subsystems actually operate, engineers synthesize learnings into an integrated design. Components get selected based on tested compatibility. Electronics define system architecture and software frameworks. Mechanical assemblies undergo CAD optimization. Design deliverables capture details for prototype manufacturing.

Alpha Prototype Build

The alpha prototype graduates from simplified proof of concept models to represent the complete device function from a user perspective. Electronics integrate sensors, microprocessors, power systems, and peripherals to deliver capabilities. The software activates instrument control, processing algorithms, and user interfaces. Mechanical parts are fabricated or 3D printed from plastics or metals.

Comprehensive Testing

Fully integrated alpha prototypes undergo rigorous functional testing to baseline performance and reliability. Test protocols evaluate key specifications, safety factors, use lifecycles, electrical interfaces, data architecture, and other attributes as a system. Real-world use simulations uncover human factors and workflow optimization opportunities.

The alpha prototype phase yields the first complete system embodiment for comprehensive performance testing. Shortcomings identified baseline the next iteration’s improvement targets.

Beta Prototype Design and Testing

Informed by alpha prototype performance, the beta phase finalizes the medical device design, optimizes for production, and verifies the complete system. Rigorous testing and validation ensure the product meets all requirements before committing to tooling and manufacturing.

Design Optimization

The beta phase focuses on refinements to address shortcomings, improve reliability, evolve user factors, and fulfill unmet requirements based on alpha feedback. Electronics robustness improves through circuit and board optimization. The software integrates enhanced functionality and UI upgrades. Mechanical components get DFMA analysis for part consolidation and tolerance allocation. Materials selection balances patient contact, performance, and cost considerations.

Beta Prototype Build

Beta prototypes graduate from alpha testbeds to models with near-production materials, processes, and finish levels. Electronics utilize printed circuit boards with integrated circuits in place of breadboards. Software code achieves beta release maturity. Mechanisms adopt molded, cast, stamped, or machined parts instead of 3D prints. The resulting models approach the fit, feel, and function expected by end users.

Comprehensive Validation

Formal design verification and validation testing commence with the beta prototypes across functional performance, safety, reliability, usability, and cybersecurity attributes. Test procedures and pass/fail criteria validate all product requirements per the design plan. Hardware and software validation provide documentary evidence of fitness for purpose. The beta phase completes due diligence before design lock.

Beta prototypes undergo rigorous system validation to finalize the medical device before transitioning to production-ready design documentation, tooling, and manufacturing preparation.

Design Verification and Validation

Design verification and validation (V&V) ensures the medical device performs as intended in the real world prior to patient use. Comprehensive test protocols measure function, safety, efficacy, reliability, and regulatory compliance against pre-defined requirements and user needs. Issues discovered lead to design refinements before locking and transferring to production.

Verification Testing

Formal design verification executes test protocols assessing product performance versus all engineering requirements established during development. Electronics, software, mechanical, electrical safety, wireless coexistence, data security, and other attributes face quantitative pass/fail criteria. Results populate verification reports demonstrating the design outputs meet inputs.

Validation Testing

Design validation confirms the medical device satisfies user needs and intended uses through simulated use human factors studies, workflow evaluations, clinical simulations, and in-field testing. Studies assess areas like patient comfort, clinician usability, training requirements, and feature adoption. Validation affirms product readiness from the user’s perspective.

Safety and Compliance Testing

Additional validation testing essential for regulatory clearance and release includes biocompatibility, sterilization, and electromagnetic compatibility per relevant consensus standards. Cybersecurity testing ensures PHI and operational safeguards. Other applicable standards verify environmental resilience, wireless coexistence, electrical safety, and more.

Broad validation testing across technical performance, human use factors, safety, and regulatory compliance reduces patient and product risks substantially prior to market release. Issues uncovered lead to design improvements before locking.

Tooling Release and Production-Ready Design

After design validation, the product transitions from engineering prototypes to advanced manufacturing planning, tooling, and robust documentation to enable quality production. Manufacturing engineers collaborate closely to ensure a smooth handoff before volume ramps up.

Production Planning

Manufacturing preparation begins by finalizing mechanical drawings, electronics assembly diagrams, software version control, and vendor component specifications. Detailed work instructions codify assembly sequences, quality inspections, and test operations. Equipment requirements get defined for inventory management. Quality engineers create control plans addressing risk priorities, critical parameters, process flow, and measurement systems.

Tooling

With the design locked, custom molds, dies, jigs, fixtures, and other tooling required for efficient production gets designed and fabricated in parallel based on projected volumes. Injection molds, stamping dies, and casting patterns require significant lead time and vendor collaboration to complete tooling along with assembly automation.

Transfer to Manufacturing

A comprehensive design package transfers fully to manufacturing teams, enabling quality production to meet schedules. Design support during initial runs helps optimize assembly processes and performance. Validation testing may supplement initial lots to reconfirm critical specifications. With the handoff, the focus shifts from engineering prototypes to volume manufacturing.

Thorough design transfer provides manufacturing teams with a complete blueprint to take medical devices from benchtop to bedside through robust production capabilities, controls, and support.

The product design process transforms concepts into mature medical devices ready for high-volume manufacturing. Each phase focuses on iterations guided by user feedback and performance data to meet product requirements, safety standards, and quality benchmarks.

Partner with DeviceLab Today

At DeviceLab, we’re here to partner with you every step of the way. Our dedicated team will help you navigate the product design process, ensuring your device meets user needs and shines in the market. Let’s connect and start bringing your vision to life together! Reach out to us today!