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Claude-skill-registry cart-design-optimizer-agent

name: cart-design-optimizer-agent

install
source · Clone the upstream repo
git clone https://github.com/majiayu000/claude-skill-registry
Claude Code · Install into ~/.claude/skills/
T=$(mktemp -d) && git clone --depth=1 https://github.com/majiayu000/claude-skill-registry "$T" && mkdir -p ~/.claude/skills && cp -r "$T/skills/data/cart-design-optimizer-agent" ~/.claude/skills/majiayu000-claude-skill-registry-cart-design-optimizer-agent && rm -rf "$T"
manifest: skills/data/cart-design-optimizer-agent/SKILL.md
tags
#biomedical#automation#gene-editing#computational-biology#ai-modeling#car-t
source content

---name: cart-design-optimizer-agent description: AI-guided CAR-T cell design for solid tumors using antigen prioritization, safety-by-design architectures, and exhaustion-resistant engineering. license: MIT metadata: author: AI Group version: "1.0.0" created: "2026-01-19" compatibility:

  • system: Python 3.10+ allowed-tools:
  • run_shell_command
  • read_file
  • write_file

keywords:

  • cart-design-optimizer-agent
  • automation
  • biomedical measurable_outcome: execute task with >95% success rate. ---"

CAR-T Design Optimizer Agent

The CAR-T Design Optimizer Agent provides end-to-end AI-guided design of chimeric antigen receptor T-cells. It integrates antigen prioritization, safety-constrained CAR architectures, exhaustion resistance engineering, and computational modeling of CAR-T kinetics for optimized therapeutic design.

When to Use This Skill

  • When designing CAR-T therapies for solid tumors with limited target antigens.
  • To optimize CAR construct sequences for reduced exhaustion and self-activation.
  • For selecting safety-by-design architectures (logic-gated, modular, armored).
  • When predicting CAR-T expansion, persistence, and efficacy.
  • To engineer exhaustion-resistant CAR-T cells via gene editing strategies.

Core Capabilities

  1. Antigen Prioritization: AI-driven ranking of target antigens based on tumor specificity, expression levels, and safety profiles.

  2. CARMSeD Prediction: Predictive model forecasting CAR constructs prone to tonic signaling, self-activation, and dysfunction.

  3. Safety Architecture Design: Logic-gated (synNotch), ON/OFF switches, armored designs for solid tumor safety.

  4. Exhaustion Resistance: CRISPR target selection (TOX, NR4A, PD-1 knockouts) and PD-1 locus integration strategies.

  5. Pharmacokinetic Modeling: Multi-population models predicting CAR-T expansion, distribution, and persistence.

  6. LLM-Assisted Design: Constrained large language model reasoning for evidence synthesis and design justification.

CAR Architecture Options

ArchitectureMechanismBest For
Standard 2nd GenCD28 or 4-1BB costimulationHematological malignancies
Logic-Gated (AND)Requires 2 antigens for activationSolid tumors, safety
synNotch PrimingTME signal triggers CAR expressionLocal activation
Armored CARCytokine secretion (IL-15, IL-21)Hostile TME
Universal/SUPRAAdaptable targeting via adaptorMulti-antigen, flexibility
PD-1 Knock-inCAR in PD-1 locusExhaustion resistance

Workflow

  1. Antigen Selection: Analyze tumor expression data to prioritize targets.

  2. Safety Assessment: Evaluate off-tumor expression in normal tissues.

  3. CAR Design: Generate construct sequences with selected domains.

  4. CARMSeD Screening: Predict self-activation and exhaustion propensity.

  5. Architecture Selection: Match patient/tumor to optimal CAR design.

  6. Gene Editing Design: Select CRISPR targets for enhanced function.

  7. Output: Optimized CAR sequence, predicted performance, manufacturing specs.

Example Usage

User: "Design an optimized CAR-T construct targeting HER2 for breast cancer with minimized exhaustion."

Agent Action:

python3 Skills/Immunology_Vaccines/CART_Design_Optimizer_Agent/cart_designer.py \
    --target HER2 \
    --tumor_type breast_cancer \
    --expression_data tumor_rnaseq.tsv \
    --normal_tissues gtex_expression.tsv \
    --architecture synnotch_armored \
    --exhaustion_engineering tox_knockout \
    --model carmsed_v2 \
    --output cart_design_report/

CARMSeD Model Details

Prediction Targets:

  • Tonic signaling propensity
  • Self-activation risk
  • Exhaustion trajectory
  • Proliferative capacity

Input Features:

  • scFv binding affinity
  • Hinge/spacer length
  • Costimulatory domain
  • Transmembrane sequence
  • Expression system

Validated Performance:

  • AUC > 0.85 for dysfunction prediction
  • In vitro to in vivo correlation

Anti-Exhaustion Engineering Strategies

TargetMethodEffect
TOXCRISPR KOPrevents exhaustion program
NR4A1-3Triple KOBlocks exhaustion TFs
PD-1 locusCAR integrationTME-responsive expression
c-JunOverexpressionOvercomes AP-1 imbalance
DNMT3AKOEpigenetic reprogramming

Computational Pharmacokinetics

Lotka-Volterra Model:

dC/dt = r*C*(1 - C/K) - k*C*T  # CAR-T expansion
dT/dt = -α*C*T                   # Tumor killing

Multi-Population Extensions:

  • Memory vs. effector subsets
  • Exhaustion state transitions
  • Cytokine-mediated effects
  • Checkpoint interactions

Prerequisites

  • Python 3.10+
  • PyTorch for ML models
  • CRISPRscan for guide design
  • Protein structure tools (optional)

Related Skills

  • TCell_Exhaustion_Analysis_Agent - For exhaustion profiling
  • Neoantigen_Vaccine_Agent - For antigen identification
  • CRISPR_Design_Agent - For gene editing optimization

Clinical Considerations

  1. Cytokine Release Syndrome: Risk assessment and mitigation designs
  2. ICANS Neurotoxicity: CNS penetration modeling
  3. Manufacturing: Transduction efficiency predictions
  4. Persistence: Memory phenotype engineering

Author

AI Group - Biomedical AI Platform