Procedures / Shoulder

Reverse Shoulder Arthroplasty

Tailor Surgery provides patient-specific 3D surgical planning and tools to ensure optimal placement of the metaglene component, enhancing outcomes and reducing surgical time.

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Precision

Less than 1 mm deviation and 2° accuracy in metaglene component positioning.

Anatomical 3D Planning

Restores the optimal glenoid plane for each patient. Supervised by shoulder and elbow surgery specialists.

Reduces intraoperative surprises & surgical time

Surgical time reduced by up to 20%, with fewer intraoperative complications thanks to comprehensive planning.

REVERSE SHOULDER ARTHROPLASTY
Our 3 Personalized Solutions

CORE SOLUTION

✓ 3D Surgical Planning

Would you like a second opinion? Contact us.

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ADVANCED SOLUTION

✓ 3D Surgical Planning
✓ Personalized Surgical Guide for Standard Implants

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EXCELLENCE SOLUTION

✓ 3D Surgical Planning
✓ Personalized Surgical Guide
✓ Customized Implant

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LEVEL 1

CORE SOLUTION

Receive a detailed digital surgical plan simulating the perfect position of your implant.

Pre-drilling measurement

Get precise measurements of the recommended reaming depth on the glenoid surface.

Multi-angle analysis

Obtain a comprehensive assessment of the glenoid surface anatomy, including:

Anteversion or retroversion angle
Inclination.

Standard implant and screw adjustment

Receive recommendations on implant size, and screw length and direction.

Get your Core Solution in 48 Hours

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LEVEL 2

ADVANCED SOLUTION

Take it a step further with our patient-specific metaglene positioning guide.

Central pin alignment

Ensure proper metaglene placement with our Custom Surgical Guide..

Get your Advanced Solution in 4-5 days

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LEVEL 3

EXCELLENCE SOLUTION

Elevate your surgery with a fully customized metaglene system tailored to your patient.

Maximum implant fixation

Drill all peripheral screw holes in the optimal direction and ensure accurate metaglene placement using our Custom Surgical Guide.

Patient-specific implant

Don’t adapt the patient to the implant—use a custom-made metaglene component, perfectly matched to the patient's glenoid surface. Compatible with your usual prosthesis (contact us for compatibility).

Request your Excellence Solution now

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Clinical Indication

Reverse Shoulder Arthroplasty is indicated for the treatment of shoulder osteoarthritis and proximal humeral fractures.

Compatibilities

This product is compatible with the following prosthesis systems:

✓  Humelock Reversed - FX Solutions
✓  Comprehensive Reverse Shoulder System
✓  Zimmer Biomet

TC Protocol

Get the image protocol for the shoulder arthroplasty procedure here:

ESP ENG

SCIENTIFIC EVIDENCE:

Marcoin, A., Nerot, C., Lestra, T., Blasco, L., Ferrier, A., Siboni, R. and Ohl, X., 2020. The precision of patient-specific instrumentation guides for the positioning of the glenoid component in total reverse shoulder arthroplasty: an in vivo scanographic study. International Orthopaedics, 44(9), pp.1761-1766.
Villatte, G., Muller, A., Pereira, B., Mulliez, A., Reilly, P. and Emery, R., 2018. Use of Patient-Specific Instrumentation (PSI) for glenoid component positioning in shoulder arthroplasty. A systematic review and meta-analysis. PLOS ONE, 13(8), p.e0201759.
Walch, G., Vezeridis, P., Boileau, P., Deransart, P. and Chaoui, J., 2015. Three-dimensional planning and use of patient-specific guides improve glenoid component position: an in vitro study. Journal of Shoulder and Elbow Surgery, 24(2), pp.302-309.
Boileau, P., Cheval, D., Gauci, M., Holzer, N., Chaoui, J. and Walch, G., 2018. Automated Three-Dimensional Measurement of Glenoid Version and Inclination in Arthritic Shoulders. Journal of Bone and Joint Surgery, 100(1), pp.57-65.
Srivas, P., Kapat, K., Dadhich, P., Pal, P., Dutta, J., Datta, P. and Dhara, S., 2017. Osseointegration assessment of extrusion printed Ti6Al4V scaffold towards accelerated skeletal defect healing via tissue in-growth. Bioprinting, 6, pp.8-17.
Xiong, Y., Wang, W., Gao, R., Zhang, H., Dong, L., Qin, J., Wang, B., Jia, W. and Li, X., 2020. Fatigue behavior and osseointegration of porous Ti-6Al-4V scaffolds with dense core for dental application. Materials & Design, 195, p.108994.