implement-pharma-serialisation
О программе
Этот навык помогает разработчикам внедрять системы сериализации фармацевтической продукции, соответствующие глобальным регуляторным требованиям, таким как EU FMD и US DSCSA. Он охватывает генерацию уникальных идентификаторов, управление иерархиями агрегации и обработку обмена данными EPCIS. Используйте его при запуске сериализованного продукта, интеграции с системами верификации (EMVS/NMVS) или проектировании соответствующих транзакционных обменов.
Быстрая установка
Claude Code
Рекомендуетсяnpx skills add pjt222/agent-almanac -a claude-code/plugin add https://github.com/pjt222/agent-almanacgit clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/implement-pharma-serialisationСкопируйте и вставьте эту команду в Claude Code для установки этого навыка
Документация
Implement Pharmaceutical Serialisation
Set up pharmaceutical serialisation systems for regulatory compliance with global track-and-trace mandates.
When to Use
- Implementing serialisation for a new product launch in the EU or US market
- Integrating with the European Medicines Verification System (EMVS/NMVS)
- Designing DSCSA-compliant transaction information exchange
- Building or integrating an EPCIS event repository for supply chain visibility
- Extending serialisation to additional markets (China NMPA, Brazil ANVISA, etc.)
Inputs
- Required: Product information (GTIN, product code, dosage form, pack sizes)
- Required: Target market regulations (EU FMD, DSCSA, or both)
- Required: Packaging hierarchy (unit, bundle, case, pallet)
- Optional: Existing ERP/MES system details for integration
- Optional: Contract manufacturer serialisation capabilities
- Optional: Verification endpoint specifications
Procedure
Step 1: Understand the Regulatory Landscape
| Regulation | Region | Key Requirements | Deadline |
|---|---|---|---|
| EU FMD (2011/62/EU) | EU/EEA | Unique identifier + tamper-evident feature on each unit | Live since Feb 2019 |
| DSCSA | USA | Electronic, interoperable tracing at package level | Full enforcement Nov 2024+ |
| China NMPA | China | Unique drug traceability code per minimum saleable unit | Rolling |
| Brazil ANVISA (SNCM) | Brazil | Serialisation of pharmaceuticals with IUM | Rolling |
| Russia MDLP | Russia | Crypto-code per unit, mandatory scanning | Live |
Key data elements per regulation:
EU FMD unique identifier (per Delegated Regulation 2016/161):
- Product code (GTIN-14 from GS1)
- Serial number (up to 20 alphanumeric characters, randomised)
- Batch/lot number
- Expiry date
DSCSA transaction information:
- Product identifier (NDC/GTIN, serial number, lot, expiry)
- Transaction information (date, entities, shipment details)
- Transaction history and transaction statement
- Verification at package level
Got: Clear understanding of which regulations apply to each product-market combination. If fail: Engage regulatory affairs to confirm market requirements before proceeding.
Step 2: Design the Serialisation Data Model
-- Core serialisation data model
CREATE TABLE serial_numbers (
id BIGSERIAL PRIMARY KEY,
gtin VARCHAR(14) NOT NULL, -- GS1 GTIN-14
serial_number VARCHAR(20) NOT NULL, -- Unique per GTIN
batch_lot VARCHAR(20) NOT NULL,
expiry_date DATE NOT NULL,
status VARCHAR(20) DEFAULT 'ACTIVE', -- ACTIVE, DECOMMISSIONED, DISPENSED, etc.
created_at TIMESTAMPTZ DEFAULT NOW(),
UNIQUE(gtin, serial_number)
);
-- Aggregation hierarchy
CREATE TABLE aggregation (
id BIGSERIAL PRIMARY KEY,
parent_code VARCHAR(50) NOT NULL, -- SSCC or higher-level code
parent_level VARCHAR(10) NOT NULL, -- CASE, PALLET, BUNDLE
child_code VARCHAR(50) NOT NULL, -- GTIN+serial or child SSCC
child_level VARCHAR(10) NOT NULL, -- UNIT, BUNDLE, CASE
aggregation_event_id UUID NOT NULL,
created_at TIMESTAMPTZ DEFAULT NOW()
);
-- EPCIS events
CREATE TABLE epcis_events (
id UUID PRIMARY KEY DEFAULT gen_random_uuid(),
event_type VARCHAR(30) NOT NULL, -- ObjectEvent, AggregationEvent, TransactionEvent
action VARCHAR(10) NOT NULL, -- ADD, OBSERVE, DELETE
biz_step VARCHAR(100), -- urn:epcglobal:cbv:bizstep:commissioning
disposition VARCHAR(100), -- urn:epcglobal:cbv:disp:active
read_point VARCHAR(100), -- urn:epc:id:sgln:location
event_time TIMESTAMPTZ NOT NULL,
event_timezone VARCHAR(6) NOT NULL,
payload JSONB NOT NULL,
created_at TIMESTAMPTZ DEFAULT NOW()
);
Aggregation hierarchy:
Pallet (SSCC)
└── Case (SSCC)
└── Bundle (GTIN + serial) [optional level]
└── Unit (GTIN + serial)
Got: Data model supports full pack hierarchy with EPCIS event tracking. If fail: If existing ERP schema conflicts, design an integration layer rather than modifying ERP directly.
Step 3: Implement Serial Number Generation
import secrets
import string
def generate_serial_number(length: int = 20, charset: str = None) -> str:
"""Generate a random serial number compliant with GS1 standards.
EU FMD requires randomised serial numbers to prevent prediction.
Max 20 characters, alphanumeric (GS1 Application Identifier 21).
"""
if charset is None:
# GS1 AI(21) allows: digits, uppercase, lowercase, and some special chars
# Most implementations use alphanumeric only for interoperability
charset = string.ascii_uppercase + string.digits
return ''.join(secrets.choice(charset) for _ in range(length))
def generate_serial_batch(gtin: str, batch_lot: str, expiry: str, count: int) -> list:
"""Generate a batch of unique serial numbers for a production run."""
serials = set()
while len(serials) < count:
serials.add(generate_serial_number())
return [
{
"gtin": gtin,
"serial_number": sn,
"batch_lot": batch_lot,
"expiry_date": expiry,
"status": "COMMISSIONED"
}
for sn in serials
]
Got: Serial numbers are cryptographically random, unique per GTIN, and stored before printing. If fail: If a uniqueness collision occurs, regenerate the conflicting serial and log the event.
Step 4: Implement GS1 DataMatrix Encoding
The 2D DataMatrix barcode encodes the GS1 element string:
(01)GTIN(21)Serial(10)Batch(17)Expiry
Example:
(01)05012345678901(21)A1B2C3D4E5(10)LOT123(17)261231
Where:
- AI(01) = GTIN-14
- AI(21) = Serial number
- AI(10) = Batch/lot number
- AI(17) = Expiry date (YYMMDD)
The GS1 DataMatrix uses FNC1 as a separator (GS character, ASCII 29) between variable-length fields.
def encode_gs1_element_string(gtin: str, serial: str, batch: str, expiry: str) -> str:
"""Encode GS1 element string for DataMatrix printing.
FNC1 (GS character \\x1d) separates variable-length fields.
AI(01) and AI(17) are fixed length, so no separator needed after them.
AI(21) and AI(10) are variable length and need FNC1 terminator.
"""
GS = '\x1d' # GS1 FNC1 / Group Separator
return f"01{gtin}21{serial}{GS}10{batch}{GS}17{expiry}"
Got: Encoded strings verified by scanning test prints with a GS1-certified verifier (ISO 15415 grade C or above). If fail: If scan verification fails, check print quality, quiet zones, and encoding order.
Step 5: Integrate with National Verification Systems
EU FMD — EMVS/NMVS Integration
MAH → Upload serial data → EU Hub → Distribute to National Systems (NMVS)
├── Germany (securPharm)
├── France (CTS)
├── Italy (AIFA)
└── ... 31 markets
API operations:
- Upload (MAH → EU Hub): Batch upload of commissioned serial numbers
- Verify (Pharmacy → NMVS): Check serial status before dispensing
- Decommission (Pharmacy → NMVS): Mark as dispensed at point of sale
- Reactivate (MAH → NMVS): Reverse accidental decommission
DSCSA — Verification Router Service
Trading Partner A → VRS Request → Verification Router → MAH's VRS → Response
Implement a VRS responder endpoint:
# Simplified VRS endpoint (DSCSA verification)
from fastapi import FastAPI, HTTPException
app = FastAPI()
@app.get("/verify/{gtin}/{serial}/{lot}/{expiry}")
async def verify_product(gtin: str, serial: str, lot: str, expiry: str):
"""DSCSA product verification endpoint."""
record = await lookup_serial(gtin, serial)
if record is None:
return {"verified": False, "reason": "SERIAL_NOT_FOUND"}
if record.batch_lot != lot or str(record.expiry_date) != expiry:
return {"verified": False, "reason": "DATA_MISMATCH"}
if record.status != "ACTIVE":
return {"verified": False, "reason": f"STATUS_{record.status}"}
return {"verified": True, "status": record.status}
Got: Verification endpoints respond within 1 second with correct status. If fail: If national system upload fails, retry with exponential backoff and alert operations.
Step 6: Implement EPCIS Event Capture
Record supply chain events in EPCIS 2.0 format:
{
"@context": "https://ref.gs1.org/standards/epcis/2.0.0/epcis-context.jsonld",
"type": "ObjectEvent",
"eventTime": "2025-03-15T10:30:00.000+01:00",
"eventTimeZoneOffset": "+01:00",
"epcList": ["urn:epc:id:sgtin:5012345.067890.A1B2C3D4E5"],
"action": "ADD",
"bizStep": "urn:epcglobal:cbv:bizstep:commissioning",
"disposition": "urn:epcglobal:cbv:disp:active",
"readPoint": {"id": "urn:epc:id:sgln:5012345.00001.0"},
"bizLocation": {"id": "urn:epc:id:sgln:5012345.00001.0"}
}
Key business steps in the pharma supply chain:
commissioning— serial number assigned to physical unitpacking— aggregation into cases/palletsshipping— departure from a locationreceiving— arrival at a locationdispensing— supplied to patient (decommission trigger)
Got: Every status change generates an EPCIS event with correct timestamps and locations. If fail: Failed event capture must be queued and retried; never silently dropped.
Validation
- Serial numbers are randomised and unique per GTIN
- GS1 DataMatrix encoding verified by barcode scanner (ISO 15415 grade C+)
- Aggregation hierarchy correctly links units → bundles → cases → pallets
- National verification system integration tested (upload, verify, decommission)
- EPCIS events captured for all business steps
- Verification endpoint responds within 1 second
- Exception handling covers upload failures, scan failures, and network errors
Pitfalls
- Sequential serial numbers: EU FMD explicitly requires randomisation to prevent counterfeiting. Never use sequential numbering.
- Aggregation errors: Disaggregation (breaking a case) must update the hierarchy. Shipping a case with wrong child associations causes verification failures downstream.
- Timezone handling: EPCIS events must include timezone offset. Using local time without offset causes event ordering ambiguity across sites.
- Late uploads: Serial data must be uploaded to national systems before product enters the supply chain. Late upload = product flagged as suspicious at pharmacy.
- Ignoring exceptions: Legitimate products get flagged (false alerts) regularly. A process for investigating and resolving alerts is essential.
Related Skills
perform-csv-assessment— validate serialisation system as a computerised systemconduct-gxp-audit— audit serialisation processesimplement-audit-trail— audit trail for serialisation eventsserialize-data-formats— general data serialisation (different domain, complementary concepts)design-serialization-schema— schema design for data exchange formats
GitHub репозиторий
Frequently asked questions
What is the implement-pharma-serialisation skill?
implement-pharma-serialisation is a Claude Skill by pjt222. Skills package instructions and resources that Claude loads on demand, so Claude can perform implement-pharma-serialisation-related tasks without extra prompting.
How do I install implement-pharma-serialisation?
Use the install commands on this page: add implement-pharma-serialisation to Claude Code as a plugin, or clone its repository into your skills directory, then restart Claude so it picks up the skill.
What category does implement-pharma-serialisation belong to?
implement-pharma-serialisation is in the Meta category, tagged design and data.
Is implement-pharma-serialisation free to use?
Yes. implement-pharma-serialisation is listed on AIMCP and free to install. It runs inside Claude, so no separate service account is required to use the skill itself.
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