| L / Ø | Ø3.0 (Slim) | Ø3.5 | Ø3.75 | Ø4.2 | Ø5.0 | Ø6.0 |
| 6mm | ——– | ——– | ——– | M4206 | M5006 | M6006 |
| 8mm | ——– | M3508 | M3708 | M4208 | M5008 | M6008 |
| 10mm | S3010 | M3510 | M3710 | M4210 | M5010 | M6010 |
| 11.5mm | S3011 | M3511 | M3711 | M4211 | M5011 | M6011 |
| 13mm | S3013 | M3513 | M3713 | M4213 | M5013 | M6013 |
| 16mm | S3016 | M3516 | M3716 | M4216 | M5016 | ——– |
MOR Spiral Dental Implant
GDT MOR Implant is an internal hex spiral implant designed to support high primary stability in a broad range of clinical indications. It combines a tapered body with a spiral thread design and self-drilling, self-tapping capability to improve bone engagement and condensation during insertion. Made from Titanium Grade 5 with SLA surface treatment, MOR supports predictable osseointegration and is suitable for routine placement as well as protocols that include immediate placement or augmentation when clinically appropriate.
Table of Contents
Implant Features
MOR Implant uses an Internal Hexagon connection with one universal platform for all diameters, simplifying restorative planning by keeping the restorative interface consistent. Platform switching is engineered to help minimize crestal bone loss while promoting bone and soft tissue growth, supporting stable peri-implant tissues and improved natural aesthetics over time.
MOR implant body combines a tapered profile with a spiral design to support stability at placement and predictable handling across different clinical situations. This geometry provides optimal soft tissue support, enhances primary stability, and improves bone condensation during placement, creating a stable foundation for restorative workflows.
MOR Implant features aggressive apical threads are designed for decisive engagement where initial fixation is critical. This thread geometry supports stability in immediate extraction sockets, in poor bone quality, and in protocols planned for immediate loading when clinically appropriate.
MOR features an SLA surface treatment. This two step process increases surface roughness on multiple levels: large grit sandblasting creates macro roughness, followed by acid etching that adds micro roughness. By increasing bone to implant contact (BIC) through a surface structure that supports cell attachment, the SLA topography helps osteoblasts adhere and proliferate. This supports faster and more predictable osseointegration, improving implant stability and contributing to long term clinical performance.
Sizes & Drilling Protocol
2 Connection Options Available
• Internal Hex 2.42mm
• Slim Internal Hex 2.0mm
* The suggested drilling protocol is a recommendation only and does not replace the clinician’s judgment
Package Content
Surgical Kits
Streamline implant procedures with organized surgical kits built for consistency and control. Featuring essential drills, drivers, and tools in an autoclavable case, each kit is labeled for efficient instrument return and designed to support precise, predictable placement across a wide range of indications.
Digital Solutions
Support a complete digital workflow with key restorative components designed for reliable digital impression capture and virtual model creation. Combined with our CAD/CAM libraries, these solutions help improve accuracy, restoration outcomes, and simplify case planning.
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Testimonials
Dr. Elias Achey
Michigan, USA
Dr. Jared Van Ittersum
Michigan, USA
Dr. Julissa Mendez
New Jersey, USA
Dr. Emin Orujov
Baku, Azerbaijan
Dr. Daniel Shtern
New Jersey, USA
Dr. Jorge Pacheco
Espinho, Portugal
Dr. Mirela Gjoni
Tirane, Albania
Dr. Jonathan Rabanipour
New York, USA
Dr. Georgi Mendez
New Jersey, USA
Mrs. Evelyn Juarez
Guatemala
FAQs
What clinical indications is the GDT MOR Implant suitable for?
The GDT MOR Implant is designed for a broad range of dental implant indications, including routine placement, immediate extraction sockets, and cases involving poor bone quality. Its tapered body with spiral design, aggressive apical threads, and self tapping system support high primary stability, making it suitable for immediate placement and for immediate loading protocols when clinically appropriate.
How does the GDT MOR Implant achieve high primary stability in dental implant placement?
High primary stability is supported by the implant macro design working as a system: a tapered body, spiral thread design, aggressive apical threads, and a self-drilling, self-tapping thread design that improves bone engagement and condensation during insertion. This combination supports controlled placement and reliable initial fixation across different bone densities.
What is the purpose of the SLA surface treatment on the GDT MOR dental implant?
The SLA surface treatment increases surface roughness at both macro and micro levels, supporting greater bone to implant contact (BIC). This surface structure supports cell attachment and osteoblast activity, promoting faster and more predictable osseointegration and contributing to long term dental implant stability.
Why does the GDT MOR Implant use a round apex design?
The round apex supports controlled insertion and improved stability, particularly when a dental implant is placed near sensitive anatomy. The design helps protect the sinus from perforation and minimizes the risk of anatomical structure damage during placement.
Still Have Questions?
