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Babysitter prosthetics-design-optimizer

Prosthetics and orthotics design optimization skill integrating biomechanical requirements with manufacturing constraints

install
source · Clone the upstream repo
git clone https://github.com/a5c-ai/babysitter
Claude Code · Install into ~/.claude/skills/
T=$(mktemp -d) && git clone --depth=1 https://github.com/a5c-ai/babysitter "$T" && mkdir -p ~/.claude/skills && cp -r "$T/library/specializations/domains/science/biomedical-engineering/skills/prosthetics-design-optimizer" ~/.claude/skills/a5c-ai-babysitter-prosthetics-design-optimizer && rm -rf "$T"
manifest: library/specializations/domains/science/biomedical-engineering/skills/prosthetics-design-optimizer/SKILL.md
tags
#biomechanical-analysis#socket-design#patient-customization#manufacturing-constraints#gait-analysis
source content

Prosthetics Design Optimizer Skill

Purpose

The Prosthetics Design Optimizer Skill supports design optimization of prosthetics and orthotics, integrating biomechanical analysis, patient-specific customization, and manufacturing constraints.

Capabilities

  • Socket design parameterization
  • Load distribution analysis
  • Alignment optimization
  • Component selection guidance
  • Suspension system design
  • Cosmesis integration
  • Patient-specific customization from scanning
  • Gait analysis integration
  • Comfort assessment metrics
  • Range of motion optimization
  • Weight optimization

Usage Guidelines

When to Use

  • Designing prosthetic/orthotic devices
  • Optimizing socket fit
  • Selecting components
  • Customizing for individual patients

Prerequisites

  • Patient assessment completed
  • Residual limb/anatomy scanned
  • Activity level determined
  • Component options identified

Best Practices

  • Integrate gait analysis data
  • Optimize for patient activity level
  • Consider long-term wear patterns
  • Plan for adjustment needs

Process Integration

This skill integrates with the following processes:

  • Gait Analysis and Musculoskeletal Modeling
  • Finite Element Analysis for Medical Devices
  • Design Control Process Implementation
  • Human Factors Engineering and Usability

Dependencies

  • CAD/CAM systems
  • 3D scanning systems
  • OpenSim
  • Gait analysis data
  • Component databases

Configuration

prosthetics-design-optimizer:
  device-types:
    - transtibial
    - transfemoral
    - upper-extremity
    - AFO
    - KAFO
    - spinal
  design-parameters:
    - socket-geometry
    - alignment
    - suspension
    - cosmesis
  analysis-types:
    - FEA
    - gait-integration
    - comfort-mapping

Output Artifacts

  • Socket design specifications
  • Alignment parameters
  • Component recommendations
  • CAD models
  • FEA reports
  • Fitting protocols
  • Adjustment guidelines
  • Patient documentation

Quality Criteria

  • Design meets biomechanical requirements
  • Socket fit optimized for comfort
  • Alignment appropriate for gait
  • Components suitable for activity level
  • Manufacturing feasible
  • Documentation supports clinical fitting