LIFE SCIENCES — CRITICAL RESEARCH SECTOR

Nation-States Are Stealing
Your Biotech IP at Wire Speed

Genomic databases, clinical trial systems, and biotech R&D networks hold the world's most valuable intellectual property. P4S SOFTLESS FPGA enforces research data sovereignty at network level — absolute containment, zero exfiltration vectors.

Request Hardware PoC Talk to an Engineer →
P4S SOFTLESS™ PROTECTED
LIVE ATTACK SIMULATION
P4S SOFTLESS™ FPGA ACTIVE

Life Sciences OT Network
Live Attack + Encryption Race

Life Sciences OT — SCADA, PLC-4, HMI & OT GW secured at 1 Gbps IPSec each. P4S SF-106-8 detects DNS tunnelling and exfiltration attempts — genomic IP and clinical trial data protected at hardware level in under 3 microseconds.

AES-256-GCM-16 1 Gbps IPSec/port <3μs latency Zero software
P4S FPGA ACTIVE — MONITORING
0
Blocked
μs/Block
100%
Block Rate
FPGA · P4S SOFTLESS
AES-256 · 9×FW · 18 Gbps
SF-106-8
FPGA SHIELD
9
FPGA FW
1G
IPSec/port
ATTACK SOURCES
PROTECTED OT NETWORK · 1 Gbps EACH
— P4S SF-106-8 HARDWARE FIREWALL LOG — LIFE SCIENCES OT NETWORK —
SF-106-8 · 9 FPGA · 18 Gbps · 1 Gbps IPSec/port
AES-256-GCM-16 ENCRYPTION RACE — READY
64-byte OT packet · AES-256-GCM-16 IPSec · 1 Gbps port · Same payload
P4S FPGA
SF-106-2 CipherWall
<3μs
VS
SOFTWARE FW
Linux kernel + OpenSSL
~3000μs
P4S WINS — 1000× FASTER
FPGA: <3μs  ·  Software: ~3000μs  ·  1 Gbps IPSec/port
Feature P4S FPGA Software FW
IPSec Latency<3μs~3000μs
IPSec Speed/Port1 Gbps≤0.1 Gbps
Attack SurfaceZEROOS + Stack
Zero-Day Immune✔ Yes✘ No
OT Node Support✔ Native✘ Limited
— AES-256-GCM-16 IPSec RACE LOG — 1 Gbps port —
1000× FASTER · 1 Gbps/port · SILICON
<3μs
Encrypt Latency
1 Gbps
IPSec/Port
1000×
Faster Than SW
ZERO
Software Layer
Live Attack Scenario

When the Attack
Hits Your Network

The documented attack playbook used against life sciences infrastructure — and why a legacy software firewall fails at every stage.

T+0:00
Sequencing lab compromised
Nation-state actor compromises genomic sequencing lab via trojanized bioinformatics software update. Software firewall passes code-signed update — no anomaly.
T+0:06
Genomic database accessed
2.4M patient genomes and CRISPR target sequences accessed. Software firewall — authenticated session, normal access patterns. No alert.
T+0:12
IP exfiltrated via DNS tunnelling
2.4M genome records exfiltrated via DNS tunnelling — 100KB chunks in legitimate DNS queries. Software DPI cannot inspect at genomics data volumes.
T+0:00 — P4S
DNS exfiltration blocked at hardware
FPGA detects anomalous DNS query volume and payload size at hardware level. DNS tunnelling pattern blocked in <3μs.
Hardware vs Software

Why Software
Firewalls Fail

⚠ LEGACY SOFTWARE FIREWALL
DNS tunnelling exfiltration invisible to software firewalls without deep DNS inspection — impossible at genomics volumes
Bioinformatics pipeline tools require external network access — software firewall allowlists create exfiltration channels
NGS data transfers are terabyte-scale — software DLP cannot baseline or monitor at this volume
Clinical trial access patterns are complex — software behavioural analysis generates excessive false positives
✓ P4S SOFTLESS™ FPGA HARDWARE
FPGA detects DNS tunnelling via payload size and query frequency analysis — exfiltration blocked before first chunk exits
Per-port isolation — sequencing lab, clinical database, and collaboration network separated in silicon
AES-256-GCM-16 IPSec encrypts all inter-lab transfers — federated research secured without software dependency
TAP-106-8 provides complete genomics network capture for IP forensics — zero impact on sequencing pipeline performance
Theme C — The Breakthrough

P4S SOFTLESS™ Hardware
Solves All Three Problems in Silicon

P4S completely replaces software stacks with hardcoded FPGA logic. No Linux. No Windows. No memory stack. No OS exploit path. No 1 Gbps performance ceiling. No quantum-vulnerable cipher implementation.

Zero Software Flaws
No Linux or Windows OS means zero memory stack overflows, zero remote OS exploits, and zero CVE exposure. The attack surface is physically absent — not patched, not mitigated. Absent.
FPGA logic hardwired at manufacture
CORE TECHNOLOGY
Line-Rate at Any Load
FPGA logic processes 18 Gbps total (SF-106-8) at wire speed regardless of attack volume. At 1 Gbps DDoS load, CPU consumption is zero. Legitimate OT packets are never dropped. PLC-4 polling never times out.
<3μs
64B frame IPSec
1 Gbps
IPSec per port
18 Gbps
Total SF-106-8
Independent FW
Quantum-Resistant Encryption
AES-256-GCM-16 implemented in FPGA silicon — not in software. The only symmetric cipher that survives Grover's algorithm reduction. Your life sciences OT traffic stays encrypted even as quantum capabilities advance.
AES-256-GCM-16 · IPSec · FIPS 140-3
SF-106 Series Architecture — Life Sciences Deployment
SF-106-2
CipherWall
2-port · 4 Gbps
1 Gbps IPSec/port
1W · POE · 32 rules
+
RECOMMENDED
SF-106-8
Network Controller
9 ports · 18 Gbps
1 Gbps IPSec/port
9× FPGA · 64 rules
+
TAP-106-8
Network Probe
Passive TAP
2 independent channels
Zero packet loss
<3μs
ENCRYPT LATENCY
ZERO
SOFTWARE LAYER
100%
BANDWIDTH
1000×
FASTER THAN SW
1 Gbps
IPSec/PORT
Protected OT Assets — All at 1 Gbps IPSec per Port
SCADA1 Gbps
🔧PLC-41 Gbps
💻HMI1 Gbps
🌐OT GW1 Gbps
System Deployment

The P4S Stack for
Life Sciences

Device 01
SF-106-2 CipherWall
2-port hardware cipher firewall. AES-256-GCM-16 in <3μs. 4 Gbps. 1W POE. 32 rules/port.
View Specs →
RECOMMENDED
Device 02
SF-106-8 Controller
9 independent FPGA firewalls. 18 Gbps. 64 rules/port. Redundant PSU. DIN-Rail. Built for life sciences OT.
View Specs →
Device 03
TAP-106-8 Probe
Passive hardware TAP. 2 independent channels. Zero packet loss. Zero added latency. Full visibility.
View Specs →
Core Technology
P4S SOFTLESS™ FPGA
No OS. No drivers. No software attack surface.
<3μs
ENCRYPT
ZERO
SOFTWARE
100%
BANDWIDTH
1000×
FASTER
Request a Proof-of-Concept
On-Site Hardware PoC
for Life Sciences

Deploy P4S SOFTLESS on your live life sciences network — zero disruption, real threat data within 48 hours.

Book Free On-Site PoC Contact Our Team →