Madrob Resorbable Hydroxyapatite

It is a synthetic bone substitute made of hydroxyapatite, chemically similar to the mineral component of bone and teeth. It is bioactive, meaning it supports bone development, healing, and osseointegration when used as a bone implant material in periodontal, oral, cranio-maxillofacial, and orthopedic surgery.

IMPLASTIC HA is synthetic nano-crystalline hydroxyapatite, designed with interconnected micro and macropores that balances mechanical function while temporarily supporting biological exchange and bone tissue regeneration. It is a bone matrix equivalent to human biological apatite, which naturally occurs in the body and mineralizes bone tissue.

Size

Clear

TECHNICAL DATA SHEET

Madrob Resorbable Hydroxyapatite

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Properties

Bone regeneration matrix with interconnected channels, similar to that of bone with an average pore size of 200-300 microns.

- Osteoconductive
- Nanocrystalline
- Mineralization initiator
- Controlled resorption in 6 months
- Biocompatible
- Osteointegrable
- Resorbable

Indications

Filling of non-structural bone perforations, synthetic bone extender:

Filling of post-extraction sockets
Filling of extraction sites in third molars
Alveolar ridge augmentation
Filling of cystic cavities
Filling of benign lesions
Maxillary sinus lift
Filling of periodontal bone defects
Filling of surgically created bone spaces

Presentation

Syringe x 1 cc

Syringe x 0.5 cc

Granules 300 – 600 microns

600-900 microns, 900-1200 microns

Sterile

Bibliography

Jarcho, M. Calcium Phosphate ceramics as hard tissue prosthetic. Clin Orthop 157:259-278, 1981.
Van W. JR. Phosphorus and its compounds, Interscience Publish Inc. New York 2:14-29.
Rodriguez, MD. Synthesis of Hydroxyapatite. Engineering and Research, Universidad Nacional de Colombia, Facultad de Ingeniería, Bogotá D.C. Dec. (41):63, 1998.
Campos LA, Rodriguez MD. Dentistry. Reconstruction of alveolar ridges and stimulation of bone mineralization through the use of resorbable and non-resorbable hydroxyapatite. Year 11 (5): 19-22, 19967.
Campos LA, Rodriguez MD. Study on bioresorption and biocompatibility of ceramic hydroxyapatite produced in Colombia. Dental Tribune, Bogotá DC 1995.
Bonel G, Heughebeaert J.C., Heughebeaert M., et al. Apatitic Calcium orthophosphates and related compounds for biomaterials preparation. Annals of the New York Academy of Sciences. 523: 115-129. 1988.
Driessens FCM. Physiology of hard tissues in comparison with the solubility of synthetic calcium phosphates. Annals of the New York Academy of Sciences. 523: 131-155.