REMSPEC replaces wet plaster and fiberglass with measured, 3D-printed splints — generated from a handful of measurements, printed on-site, and fitted to the patient in minutes. Lightweight, ventilated, and clean.
No scanners, no casting mess, no waiting room full of plaster dust. A clinician enters simple measurements; the REMSPEC engine does the rest.
Limb length and two circumferences — plus the clinical intent: what to immobilize, for how long, and the weight-bearing level.
Wrap angle, wall thickness, clearance, and ventilation are computed from the clinical inputs. Every splint is verified watertight and printable before it reaches the printer.
Printed on-site in minutes on standard hardware. The result is a ventilated, lightweight splint shaped for the patient — not a shelf size forced to fit.
Plaster and fiberglass work — at the cost of weight, mess, skin problems, and zero adjustability. A printed splint changes the trade.
| Plaster / fiberglass | REMSPEC printed splint | |
|---|---|---|
| Weight | Heavy | Light — ventilated lattice |
| Application | Wet, messy, 20+ min | Clean, minutes |
| Skin | Itch, odor, maceration | Ventilated, washable |
| Fit | One-shot, hard to adjust | Measured to the patient |
| Waterproof | No | Yes |
REMSPEC runs on the TrueSet engine: clinical intent goes in — region, motions to restrict, duration, load — and a watertight, printable splint geometry comes out, with structure derived from the prescription, not a template catalog.
"Lock these motions for three weeks, partial weight-bearing" becomes wrap angle, wall thickness, and vent density — automatically.
Every generated splint is validated — watertight geometry, consistent walls, realistic print mass — before it's released to the printer.
The full pipeline runs on-site on standard hardware. No patient data leaves the building.