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Data SecurityPublicado June 18, 2026 · Actualizado May 25, 2026

Contextual Encryption for LLM and Vector Database Pipelines

An enterprise AI platform needed to enable LLM-powered features (chat, search, document analysis) while ensuring sensitive data — PII, financial records, healthcare information — remained encrypted throughout the pipeline, including when stored as vector embeddings in a vector database.

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Data Security
Domain
10
Technologies
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Key Results
Delivered
Status

El Desafío

Using LLMs and vector databases with sensitive data introduced novel security risks:

  • Embedding Inversion Attacks — Research showed that vector embeddings could be reverse-engineered to reconstruct original text, exposing PII stored in vector DBs
  • LLM Context Leakage — Sensitive data sent to LLMs could appear in responses to other users if not properly isolated
  • Compliance Requirements — GDPR, HIPAA, and SOC2 demanded encryption at rest and in transit, but vector databases stored mathematical representations, not traditional text fields
  • Search Functionality — Encrypting text before embedding destroyed semantic meaning, making similarity search useless
  • Key Management — Per-tenant encryption keys needed rotation without re-embedding entire datasets
  • Audit Trail — Every access to decrypted sensitive data needed logging for compliance

Nuestra Solución

We implemented a contextual encryption architecture that selectively encrypts sensitive fields before storage while preserving semantic searchability through a layered approach — encrypting PII in metadata while keeping sanitized, non-sensitive content available for embedding.

Architecture

  • Encryption Engine: AES-256-GCM with per-tenant encryption keys
  • Key Management: AWS KMS for key generation, rotation, and access control
  • PII Detection: NER-based (Named Entity Recognition) PII classifier
  • Vector Database: Milvus for similarity search on sanitized embeddings
  • LLM Layer: Sanitized context sent to LLM, sensitive fields re-injected post-generation
  • Audit System: Every decryption event logged with user, timestamp, and purpose
  • Database: PostgreSQL for encrypted metadata

Contextual Encryption Strategy

Data Classification

Before any data enters the pipeline, a PII classifier categorizes each field by sensitivity level:

  • Highly Sensitive (e.g., government IDs, financial account numbers, medical IDs) — Encrypted, never embedded, never sent to LLM
  • Sensitive PII (e.g., full names, email addresses, phone numbers) — Encrypted at rest, placeholder-replaced before embedding
  • Contextual (e.g., job titles, company names) — Encrypted at rest, available for embedding with consent
  • Non-Sensitive (e.g., product descriptions, public information) — Stored and embedded as-is

Encryption Layers

Layer 1: Field-Level Encryption at Rest

Sensitive fields are encrypted with AES-256-GCM before storage. Each tenant gets a dedicated data encryption key (DEK) managed through a key hierarchy via AWS KMS. Shadow fields store searchable hashes for exact-match lookups without requiring decryption.

Layer 2: Sanitization Before Embedding

PII is detected and replaced with type-preserving placeholders before text is sent to the embedding model. This preserves semantic meaning for similarity search while removing identifiable information. The original-to-placeholder mapping is stored encrypted alongside the vector record.

Layer 3: Context Injection After LLM Generation

The LLM receives sanitized context with placeholders for generating responses. After generation, the system re-injects actual values from encrypted storage into the response. This prevents sensitive data from entering LLM training data or being cached by the provider.

Vector Database Security

Collection Design

Vector collections store sanitized embeddings alongside encrypted original metadata. Tenant isolation is enforced via partition keys, with each tenant's metadata encrypted using their own key. The API layer validates tenant ownership before any decryption operation.

Key Management & Rotation

Key Hierarchy

A multi-level key hierarchy is used: a master key in AWS KMS wraps per-tenant key encryption keys, which in turn wrap per-tenant data encryption keys used for field-level encryption. This enables efficient key rotation without re-encrypting the entire key chain.

Key Rotation Process

  1. New DEK Generated — New data encryption key created under the existing key encryption key
  2. New Writes — All new data encrypted with the new key; the old key remains valid for reads
  3. Background Re-encryption — Batch job re-encrypts existing records with the new key
  4. Old DEK Retirement — Once all records migrated, old key marked inactive
  5. Audit Log — Rotation event logged with timestamps and affected record counts

Audit & Compliance

Decryption Audit Log

Every decryption event captures who requested it, what was decrypted, when, why (request context), and which key was used — providing a complete compliance trail.

GDPR Right to Erasure

The system supports full data deletion across both the relational database and vector database, with optional key rotation to cryptographically ensure no residual access. All deletion operations are logged in a GDPR audit trail.

Key Features

  1. Field-Level Encryption — AES-256-GCM on sensitive fields, not entire records
  2. PII Sanitization — Placeholders preserve semantic meaning for embeddings
  3. Post-LLM Re-injection — Sensitive data never sent to LLM providers
  4. Per-Tenant Keys — Isolated encryption keys with AWS KMS management
  5. Key Rotation — Zero-downtime rotation with background re-encryption
  6. Embedding Safety — Sanitized embeddings prevent inversion attacks on PII
  7. Audit Trail — Every decryption logged for compliance reporting
  8. GDPR Compliance — Automated erasure across encrypted stores and vector DB

Resultados

Compliance: Met GDPR, HIPAA, and SOC2 encryption and audit requirements
Security: PII never exposed in vector embeddings or LLM context
Search Quality: Sanitized embeddings maintained 95%+ semantic search relevance vs. unsanitized

Stack Tecnológico

AES-256-GCMAWS KMSMilvusPostgreSQLNER/PII DetectionOpenAI EmbeddingsNode.jsTypeScriptBullMQPython

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Preguntas Frecuentes

MicrocosmWorks developed a selective encryption pipeline that identifies and encrypts sensitive entities like names, account numbers, and health data within documents before they enter the vector database, while preserving the surrounding semantic context that the LLM needs for meaningful retrieval and generation. During query time, the system decrypts only the specific entities needed for the response, scoped to the requesting user's access level, so the LLM never sees raw sensitive data it is not authorized to surface.

MicrocosmWorks solved this by encrypting sensitive entities at the token level while computing embeddings on the original unencrypted text, then storing the encrypted text alongside the semantic vectors in the vector database. The search retrieves semantically relevant chunks using the high-quality embeddings, and the decryption layer reconstructs the original content only for authorized users, preserving full search quality while protecting data at rest.

MicrocosmWorks designed the contextual encryption approach to address specific requirements in HIPAA, SOC 2, GDPR, and CCPA by ensuring that personally identifiable information and protected health information are encrypted at rest in the vector store and only decrypted within memory during authorized query processing. The system generates tamper-proof audit logs of every decryption event, which satisfies the access monitoring and accountability requirements common across these compliance frameworks.

MicrocosmWorks built a migration utility that processes existing vector database collections incrementally, encrypting sensitive entities in stored document chunks while preserving their vector embeddings, so you do not need to re-compute embeddings for your entire corpus. The migration runs as a background process that can be paused and resumed, and the query pipeline seamlessly handles both encrypted and not-yet-migrated chunks during the transition period.

MicrocosmWorks optimized the encryption and decryption operations to add approximately 15-30ms of overhead per query, which is negligible compared to the 500ms-2s typical LLM generation time. The entity detection and encryption during ingestion adds about 100ms per document chunk, which is also minimal since ingestion is typically a batch process. The system uses hardware-accelerated AES operations and caches decryption keys in memory to minimize the cryptographic overhead.