J005
XCmedico
1 Pcs(72 Hours Delivery)
Titanium Alloy
CE/ISO:9001/ISO13485.Etc
Custom-Made 15 Days Delivery(Excluding Shipping Time)
FedEx. DHL.TNT.EMS.Etc
Availability: | |
---|---|
Quantity: | |
BB Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3311-04090 | 9 | 135 | 33.8 | 135 | Ti6Al4V | Ti+HA | |
3311-04100 | 10 | 140 | 34.5 | ||||
3311-04110 | 11 | 145 | 35.2 | ||||
3311-04120 | 12 | 150 | 36 | ||||
3311-04130 | 13 | 155 | 36.8 | ||||
3311-04140 | 14 | 155 | 37.6 | ||||
3311-04150 | 15 | 155 | 38.4 | ||||
3311-04160 | 16 | 160 | 39.2 | ||||
3311-04170 | 17 | 160 | 40.2 | ||||
3311-04180 | 18 | 165 | 41.2 | ||||
145 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3330-01070 | 7 | 130 | 30.4 | 135 | Ti6Al4V | shot blasting | |
3330-01080 | 8 | 135 | 31.7 | ||||
3330-01090 | 9 | 140 | 33 | ||||
3330-01100 | 10 | 145 | 34.3 | ||||
3330-01110 | 11 | 150 | 35.6 | ||||
3330-01120 | 12 | 155 | 36.9 | ||||
3330-01130 | 13 | 160 | 38.2 | ||||
3330-01140 | 14 | 165 | 39.5 | ||||
140 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
20 | 9 | 140 | 37.5 | 130 | Ti6Al4V | Ti | |
3310-02100 | 10 | 145 | 38 | ||||
3310-02110 | 11 | 150 | 38.5 | ||||
3310-02120 | 12 | 155 | 39 | ||||
3310-02130 | 13 | 160 | 40 | ||||
3310-02140 | 14 | 165 | 41 | ||||
3310-02150 | 15 | 170 | 42 | ||||
BE Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3323-04080 | 8 | 115 | 38.4 | 135 | Ti6Al4V | Ti+HA | |
3323-04090 | 9 | 130 | 38.9 | ||||
3323-04100 | 10 | 140 | 39.8 | ||||
3323-04110 | 11 | 145 | 40.7 | ||||
3323-04120 | 12 | 150 | 41.3 | ||||
3323-04130 | 13 | 155 | 42.2 | ||||
3323-04140 | 14 | 160 | 43.1 | ||||
3323-04150 | 15 | 165 | 44 | ||||
3323-04160 | 16 | 170 | 44.8 | ||||
3323-04170 | 17 | 180 | 45.6 | ||||
3323-04180 | 17+ | 190 | 46.3 | ||||
BE2 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
/ | 6 | 110 | 32 | 127&133 two version | Ti6Al4V | Ti+HA | |
7 | 115 | 33 | |||||
8 | 120 | 34 | |||||
9 | 125 | 35 | |||||
10 | 130 | 36 | |||||
11 | 135 | 37 | |||||
12 | 140 | 38 | |||||
13 | 145 | 39 | |||||
14 | 150 | 40 | |||||
15 | 155 | 41 | |||||
16 | 160 | 42 | |||||
17 | 165 | 43 | |||||
18 | 170 | 44 | |||||
155 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | Pic. |
3332-02070 | 7 | 120 | 32.3 | 132 | Ti6Al4V | ![]() | ![]() |
3332-02080 | 8 | 125 | 33.3 | ||||
3332-02090 | 9 | 130 | 34.3 | ||||
3332-02100 | 10 | 135 | 35.4 | ||||
3332-02110 | 11 | 140 | 36.4 | ||||
3332-02120 | 12 | 145 | 37.6 | ||||
3332-02130 | 13 | 150 | 38.8 | ||||
3332-02140 | 14 | 155 | 39.9 | ||||
3332-02150 | 15 | 160 | 41.1 | ||||
3332-02160 | 16 | 165 | 42.3 | ||||
3332-02170 | 16+ | 170 | 43.5 | ||||
3332-02180 | 16++ | 175 | 44.7 |
130 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3320-02060 | 6 | 100 | 32 | 125 | Ti6Al4V | Ti | |
3320-02070 | 7 | 100 | 33 | ||||
3320-02080 | 8 | 110 | 34 | ||||
3320-02090 | 9 | 110 | 35 | ||||
3320-02100 | 10 | 120 | 36 | ||||
3320-02110 | 11 | 120 | 37.5 | ||||
3320-02120 | 12 | 130 | 39 | ||||
130 Long Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3315-01100 | 10 | 185&205& 220&250 | 40 | 135 | Ti6Al4V | Ti | |
3315-01110 | 11 | 40 | |||||
3315-01120 | 12 | 41 | |||||
3315-01130 | 13 | 41 | |||||
3315-01140 | 14 | 42 | |||||
3315-01150 | 15 | 42 | |||||
3315-01160 | 16 | 42 | |||||
BE1 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angl | Mat. | Coating | Pic. |
3331-02060 | 6 | 112 | 40.4 | 132 | Ti6Al4V | Ti | ![]() ![]() |
3331-02070 | 7 | 114 | 40.9 | ||||
3331-02080 | 8 | 116 | 41.4 | ||||
3331-02090 | 9 | 120 | 41.9 | ||||
3331-02100 | 10 | 122 | 42.4 | ||||
3331-02110 | 11 | 124 | 43.9 | ||||
3331-02120 | 12 | 126 | 46.9 | ||||
3331-02130 | 13 | 128 | 47.9 | ||||
3331-02140 | 13+ | 130 | 48.4 | ||||
160 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | ![]() | Pic. |
3325-02090 | 9 | 150 | 39 | 130 | Ti6Al4V | Ti | ![]() |
3325-02100 | 10 | 39.5 | |||||
3325-02110 | 11 | 40 | |||||
3325-02120 | 12 | 40.5 | |||||
3325-02130 | 13 | 41 | |||||
3325-01240 | 14 | 41.5 | |||||
3325-02150 | 15 | 41.5 | |||||
3325-02160 | 16 | 42 | |||||
3325-02180 | 18 | ||||||
3325-02200 | 20 | 42.5 | |||||
160 Stem(200mm Long, for Revision or Trochanteric Fracture THA) | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | Pic. |
3326-02091 | 9L | 200 | 39 | 130 | Ti6Al4V | ![]() | ![]() |
3326-02092 | 9R | ||||||
3326-02101 | 10L | 39.5 | |||||
3326-02102 | 10R | ||||||
3326-02111 | 11L | 40 | |||||
3326-02112 | 11R | ||||||
3326-02121 | 12L | 40.5 | |||||
3326-02122 | 12R | ||||||
3326-02131 | 13L | 41 | |||||
3326-02132 | 13R | ||||||
3326-02141 | 14L | 41.5 | |||||
3326-02142 | 14R | ||||||
3326-02161 | 16L | 42 | |||||
3326-02162 | 16R | ||||||
3326-02181 | 18L | 42.5 | |||||
3326-02182 | 18R | ||||||
3326-02201 | 20L | 43 | |||||
3326-02202 | 20R | ||||||
160 Stem(250mm Long, for Revision or Trochanteric Fracture THA) | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | ![]() | ![]() |
3327-02101 | 10L | 250 | 39.5 | 130 | Ti6Al4V | Ti | |
3327-02102 | 10R | ||||||
3327-02121 | 12L | 40.5 | |||||
3327-02122 | 12R | ||||||
3327-02141 | 14L | 41.5 | |||||
3327-02142 | 14R | ||||||
3327-02161 | 16L | 42 | |||||
3327-02162 | 16R | ||||||
3327-02181 | 18L | 42.5 | |||||
3327-02182 | 18R | ||||||
3327-02201 | 20L | 43 | |||||
3327-02202 | 20R |
CNC Preliminary Processing The computer numerical control technology is used to precisely process orthopedic products. This process has the characteristics of high precision, high efficiency, and repeatability. It can quickly produce customized medical devices that conform to the human anatomical structure and provide patients with personalized treatment plans. | Product Polishing The purpose of orthopedic products polishing is to improve the contact between the implant and human tissue, reduce stress concentration, and improve the long-term stability of the implant. | Quality Inspection The mechanical properties test of orthopedic products is designed to simulate the stress conditions of human bones, evaluate the load-bearing capacity and durability of implants in the human body, and ensure their safety and reliability. |
Product Package Orthopedic products are packaged in a sterile room to ensure that the product is encapsulated in a clean, sterile environment to prevent microbial contamination and ensure surgical safety. |
The storage of orthopedic products requires strict in-and-out management and quality control to ensure product traceability and prevent expiration or wrong shipment. |
The sample room is used to store, display and manage various orthopedic products samples for product technology exchanges and training. |
1. Ask Xc Medico Team For Cementless Revision Hip Product Catalog.
2. Choose Your Interested Cementless Revision Hip Product.
3. Ask For A Sample To Test Cementless Revision Hip.
4.Make An Order Of XC Medico's Cementless Revision Hip.
5.Become A Dealer Of XC Medico's Cementless Revision Hip.
1.Better Purchase Prices Of Cementless Revision Hip.
2.100% The Highest Quality Cementless Revision Hip.
3. Less Ordering Efforts.
4. Price Stability For The Period Of Agreement.
5. Sufficient Cementless Revision Hip.
6. Quick And Easy Assessment Of XC Medico's Cementless Revision Hip.
7. A Globally Recognized Brand - XC Medico.
8. Fast Access Time To XC Medico Sales Team.
9. Additional Quality Test By XC Medico Team.
10. Track Your XC Medico Order From Start To Finish.
The cementless revision hip implant represents a vital advancement in the field of orthopedic surgery, particularly in addressing complications related to failed or worn-out hip replacements. These implants are designed to improve mobility, reduce pain, and restore functionality without the use of bone cement. This guide provides an in-depth overview of cementless revision hips, exploring their features, advantages, applications, and future market potential, catering to orthopedic professionals and medical enthusiasts alike.
Cementless revision hip refers to a type of hip implant designed for use in revision surgeries, where a previously placed hip implant has failed, loosened, or caused complications. Unlike traditional implants that rely on bone cement for fixation, cementless implants achieve stability through biological fixation. This is facilitated by their porous surface, which promotes bone growth directly into the implant, creating a long-lasting and stable bond.
These implants are particularly suited for patients with good bone quality and those undergoing procedures where bone conservation is crucial. Cementless designs are increasingly favored for their ability to integrate with the natural bone structure and reduce the risk of complications associated with cemented implants.
The porous coating, often made of titanium or hydroxyapatite, encourages osseointegration, allowing natural bone to grow into the implant.
Many implants feature a tapered stem design to achieve a secure fit in the femoral canal, improving initial stability.
Modular designs allow for greater customization, enabling surgeons to tailor the implant to the patient’s unique anatomy and bone structure.
High-strength materials like titanium alloys are commonly used for their excellent biocompatibility, lightweight nature, and corrosion resistance.
Anatomical designs mimic the natural contours of the femur and acetabulum, enhancing implant stability and patient comfort.
Cementless systems often include options for extended-length stems and acetabular augments for severe bone loss cases.
Biological fixation ensures that the implant remains securely attached to the bone over time, reducing the likelihood of loosening or failure.
By eliminating the use of bone cement, which can serve as a potential site for bacterial growth, the risk of post-operative infection is minimized.
Cementless designs allow for bone conservation, which is particularly beneficial in younger patients who may require further revisions in the future.
The natural bone growth into the implant enhances load distribution and minimizes stress shielding, leading to better long-term outcomes.
Surgeons can customize the implant to address specific challenges, such as bone loss or deformities, improving surgical outcomes.
Patients often experience quicker recovery times and improved post-operative mobility due to the secure, natural fixation provided by these implants.
When a previously placed hip implant loses its attachment to the bone without infection, a cementless implant offers a stable replacement.
In cases of fractures around the original implant, the cementless design can accommodate and stabilize these complex conditions.
Bone loss caused by wear debris from previous implants can be mitigated with the use of cementless implants that promote bone regeneration.
For patients with recurrent dislocations or unstable hip joints, cementless revision implants restore proper alignment and stability.
After infection-related implant removal and eradication of infection, cementless designs provide a reliable option for re-implantation.
In some cases, the natural bone may take longer to grow into the implant, leading to temporary instability.
Patients with poor bone quality, such as those with severe osteoporosis, may not achieve adequate fixation, increasing the risk of implant failure.
Cementless revision procedures can be more technically demanding, requiring experienced surgeons and specialized equipment.
Improper implantation techniques may lead to fractures of the femur or acetabulum.
Over time, the components of the implant may wear, necessitating further revisions.
Cementless implants are often more expensive than cemented options, which may limit accessibility for some patients.
As the global population ages, the demand for hip revision surgeries is expected to increase, boosting the need for reliable implants.
Innovations in biocompatible materials, such as bioactive coatings and 3D-printed implants, are enhancing the performance of cementless systems.
The growing preference for biological fixation among surgeons ensures sustained adoption of cementless implants.
Expanding healthcare infrastructure in regions such as Asia-Pacific and Latin America presents untapped opportunities for market growth.
The integration of robotic-assisted surgery and AI-driven planning tools is improving the precision of cementless implant procedures.
The cementless revision hip is a cornerstone of modern orthopedic surgery, offering an effective, durable, and biocompatible solution for hip revision cases. Its innovative design promotes natural bone integration, reducing the risks associated with traditional cemented implants. While surgical challenges and patient-specific factors must be carefully considered, the advantages of cementless systems make them a preferred choice for many orthopedic surgeons.
As technology continues to advance and the global demand for revision surgeries grows, the cementless revision hip is set to play an increasingly vital role in enhancing patient outcomes and redefining standards in hip replacement surgery.
Warm reminder: This article is for reference only and cannot replace the doctor's professional advice. If you have any questions, please consult your attending physician.
BB Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3311-04090 | 9 | 135 | 33.8 | 135 | Ti6Al4V | Ti+HA | |
3311-04100 | 10 | 140 | 34.5 | ||||
3311-04110 | 11 | 145 | 35.2 | ||||
3311-04120 | 12 | 150 | 36 | ||||
3311-04130 | 13 | 155 | 36.8 | ||||
3311-04140 | 14 | 155 | 37.6 | ||||
3311-04150 | 15 | 155 | 38.4 | ||||
3311-04160 | 16 | 160 | 39.2 | ||||
3311-04170 | 17 | 160 | 40.2 | ||||
3311-04180 | 18 | 165 | 41.2 | ||||
145 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3330-01070 | 7 | 130 | 30.4 | 135 | Ti6Al4V | shot blasting | |
3330-01080 | 8 | 135 | 31.7 | ||||
3330-01090 | 9 | 140 | 33 | ||||
3330-01100 | 10 | 145 | 34.3 | ||||
3330-01110 | 11 | 150 | 35.6 | ||||
3330-01120 | 12 | 155 | 36.9 | ||||
3330-01130 | 13 | 160 | 38.2 | ||||
3330-01140 | 14 | 165 | 39.5 | ||||
140 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
20 | 9 | 140 | 37.5 | 130 | Ti6Al4V | Ti | |
3310-02100 | 10 | 145 | 38 | ||||
3310-02110 | 11 | 150 | 38.5 | ||||
3310-02120 | 12 | 155 | 39 | ||||
3310-02130 | 13 | 160 | 40 | ||||
3310-02140 | 14 | 165 | 41 | ||||
3310-02150 | 15 | 170 | 42 | ||||
BE Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3323-04080 | 8 | 115 | 38.4 | 135 | Ti6Al4V | Ti+HA | |
3323-04090 | 9 | 130 | 38.9 | ||||
3323-04100 | 10 | 140 | 39.8 | ||||
3323-04110 | 11 | 145 | 40.7 | ||||
3323-04120 | 12 | 150 | 41.3 | ||||
3323-04130 | 13 | 155 | 42.2 | ||||
3323-04140 | 14 | 160 | 43.1 | ||||
3323-04150 | 15 | 165 | 44 | ||||
3323-04160 | 16 | 170 | 44.8 | ||||
3323-04170 | 17 | 180 | 45.6 | ||||
3323-04180 | 17+ | 190 | 46.3 | ||||
BE2 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
/ | 6 | 110 | 32 | 127&133 two version | Ti6Al4V | Ti+HA | |
7 | 115 | 33 | |||||
8 | 120 | 34 | |||||
9 | 125 | 35 | |||||
10 | 130 | 36 | |||||
11 | 135 | 37 | |||||
12 | 140 | 38 | |||||
13 | 145 | 39 | |||||
14 | 150 | 40 | |||||
15 | 155 | 41 | |||||
16 | 160 | 42 | |||||
17 | 165 | 43 | |||||
18 | 170 | 44 | |||||
155 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | Pic. |
3332-02070 | 7 | 120 | 32.3 | 132 | Ti6Al4V | ![]() | ![]() |
3332-02080 | 8 | 125 | 33.3 | ||||
3332-02090 | 9 | 130 | 34.3 | ||||
3332-02100 | 10 | 135 | 35.4 | ||||
3332-02110 | 11 | 140 | 36.4 | ||||
3332-02120 | 12 | 145 | 37.6 | ||||
3332-02130 | 13 | 150 | 38.8 | ||||
3332-02140 | 14 | 155 | 39.9 | ||||
3332-02150 | 15 | 160 | 41.1 | ||||
3332-02160 | 16 | 165 | 42.3 | ||||
3332-02170 | 16+ | 170 | 43.5 | ||||
3332-02180 | 16++ | 175 | 44.7 |
130 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3320-02060 | 6 | 100 | 32 | 125 | Ti6Al4V | Ti | |
3320-02070 | 7 | 100 | 33 | ||||
3320-02080 | 8 | 110 | 34 | ||||
3320-02090 | 9 | 110 | 35 | ||||
3320-02100 | 10 | 120 | 36 | ||||
3320-02110 | 11 | 120 | 37.5 | ||||
3320-02120 | 12 | 130 | 39 | ||||
130 Long Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3315-01100 | 10 | 185&205& 220&250 | 40 | 135 | Ti6Al4V | Ti | |
3315-01110 | 11 | 40 | |||||
3315-01120 | 12 | 41 | |||||
3315-01130 | 13 | 41 | |||||
3315-01140 | 14 | 42 | |||||
3315-01150 | 15 | 42 | |||||
3315-01160 | 16 | 42 | |||||
BE1 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angl | Mat. | Coating | Pic. |
3331-02060 | 6 | 112 | 40.4 | 132 | Ti6Al4V | Ti | ![]() ![]() |
3331-02070 | 7 | 114 | 40.9 | ||||
3331-02080 | 8 | 116 | 41.4 | ||||
3331-02090 | 9 | 120 | 41.9 | ||||
3331-02100 | 10 | 122 | 42.4 | ||||
3331-02110 | 11 | 124 | 43.9 | ||||
3331-02120 | 12 | 126 | 46.9 | ||||
3331-02130 | 13 | 128 | 47.9 | ||||
3331-02140 | 13+ | 130 | 48.4 | ||||
160 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | ![]() | Pic. |
3325-02090 | 9 | 150 | 39 | 130 | Ti6Al4V | Ti | ![]() |
3325-02100 | 10 | 39.5 | |||||
3325-02110 | 11 | 40 | |||||
3325-02120 | 12 | 40.5 | |||||
3325-02130 | 13 | 41 | |||||
3325-01240 | 14 | 41.5 | |||||
3325-02150 | 15 | 41.5 | |||||
3325-02160 | 16 | 42 | |||||
3325-02180 | 18 | ||||||
3325-02200 | 20 | 42.5 | |||||
160 Stem(200mm Long, for Revision or Trochanteric Fracture THA) | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | Pic. |
3326-02091 | 9L | 200 | 39 | 130 | Ti6Al4V | ![]() | ![]() |
3326-02092 | 9R | ||||||
3326-02101 | 10L | 39.5 | |||||
3326-02102 | 10R | ||||||
3326-02111 | 11L | 40 | |||||
3326-02112 | 11R | ||||||
3326-02121 | 12L | 40.5 | |||||
3326-02122 | 12R | ||||||
3326-02131 | 13L | 41 | |||||
3326-02132 | 13R | ||||||
3326-02141 | 14L | 41.5 | |||||
3326-02142 | 14R | ||||||
3326-02161 | 16L | 42 | |||||
3326-02162 | 16R | ||||||
3326-02181 | 18L | 42.5 | |||||
3326-02182 | 18R | ||||||
3326-02201 | 20L | 43 | |||||
3326-02202 | 20R | ||||||
160 Stem(250mm Long, for Revision or Trochanteric Fracture THA) | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | ![]() | ![]() |
3327-02101 | 10L | 250 | 39.5 | 130 | Ti6Al4V | Ti | |
3327-02102 | 10R | ||||||
3327-02121 | 12L | 40.5 | |||||
3327-02122 | 12R | ||||||
3327-02141 | 14L | 41.5 | |||||
3327-02142 | 14R | ||||||
3327-02161 | 16L | 42 | |||||
3327-02162 | 16R | ||||||
3327-02181 | 18L | 42.5 | |||||
3327-02182 | 18R | ||||||
3327-02201 | 20L | 43 | |||||
3327-02202 | 20R |
CNC Preliminary Processing The computer numerical control technology is used to precisely process orthopedic products. This process has the characteristics of high precision, high efficiency, and repeatability. It can quickly produce customized medical devices that conform to the human anatomical structure and provide patients with personalized treatment plans. | Product Polishing The purpose of orthopedic products polishing is to improve the contact between the implant and human tissue, reduce stress concentration, and improve the long-term stability of the implant. | Quality Inspection The mechanical properties test of orthopedic products is designed to simulate the stress conditions of human bones, evaluate the load-bearing capacity and durability of implants in the human body, and ensure their safety and reliability. |
Product Package Orthopedic products are packaged in a sterile room to ensure that the product is encapsulated in a clean, sterile environment to prevent microbial contamination and ensure surgical safety. |
The storage of orthopedic products requires strict in-and-out management and quality control to ensure product traceability and prevent expiration or wrong shipment. |
The sample room is used to store, display and manage various orthopedic products samples for product technology exchanges and training. |
1. Ask Xc Medico Team For Cementless Revision Hip Product Catalog.
2. Choose Your Interested Cementless Revision Hip Product.
3. Ask For A Sample To Test Cementless Revision Hip.
4.Make An Order Of XC Medico's Cementless Revision Hip.
5.Become A Dealer Of XC Medico's Cementless Revision Hip.
1.Better Purchase Prices Of Cementless Revision Hip.
2.100% The Highest Quality Cementless Revision Hip.
3. Less Ordering Efforts.
4. Price Stability For The Period Of Agreement.
5. Sufficient Cementless Revision Hip.
6. Quick And Easy Assessment Of XC Medico's Cementless Revision Hip.
7. A Globally Recognized Brand - XC Medico.
8. Fast Access Time To XC Medico Sales Team.
9. Additional Quality Test By XC Medico Team.
10. Track Your XC Medico Order From Start To Finish.
The cementless revision hip implant represents a vital advancement in the field of orthopedic surgery, particularly in addressing complications related to failed or worn-out hip replacements. These implants are designed to improve mobility, reduce pain, and restore functionality without the use of bone cement. This guide provides an in-depth overview of cementless revision hips, exploring their features, advantages, applications, and future market potential, catering to orthopedic professionals and medical enthusiasts alike.
Cementless revision hip refers to a type of hip implant designed for use in revision surgeries, where a previously placed hip implant has failed, loosened, or caused complications. Unlike traditional implants that rely on bone cement for fixation, cementless implants achieve stability through biological fixation. This is facilitated by their porous surface, which promotes bone growth directly into the implant, creating a long-lasting and stable bond.
These implants are particularly suited for patients with good bone quality and those undergoing procedures where bone conservation is crucial. Cementless designs are increasingly favored for their ability to integrate with the natural bone structure and reduce the risk of complications associated with cemented implants.
The porous coating, often made of titanium or hydroxyapatite, encourages osseointegration, allowing natural bone to grow into the implant.
Many implants feature a tapered stem design to achieve a secure fit in the femoral canal, improving initial stability.
Modular designs allow for greater customization, enabling surgeons to tailor the implant to the patient’s unique anatomy and bone structure.
High-strength materials like titanium alloys are commonly used for their excellent biocompatibility, lightweight nature, and corrosion resistance.
Anatomical designs mimic the natural contours of the femur and acetabulum, enhancing implant stability and patient comfort.
Cementless systems often include options for extended-length stems and acetabular augments for severe bone loss cases.
Biological fixation ensures that the implant remains securely attached to the bone over time, reducing the likelihood of loosening or failure.
By eliminating the use of bone cement, which can serve as a potential site for bacterial growth, the risk of post-operative infection is minimized.
Cementless designs allow for bone conservation, which is particularly beneficial in younger patients who may require further revisions in the future.
The natural bone growth into the implant enhances load distribution and minimizes stress shielding, leading to better long-term outcomes.
Surgeons can customize the implant to address specific challenges, such as bone loss or deformities, improving surgical outcomes.
Patients often experience quicker recovery times and improved post-operative mobility due to the secure, natural fixation provided by these implants.
When a previously placed hip implant loses its attachment to the bone without infection, a cementless implant offers a stable replacement.
In cases of fractures around the original implant, the cementless design can accommodate and stabilize these complex conditions.
Bone loss caused by wear debris from previous implants can be mitigated with the use of cementless implants that promote bone regeneration.
For patients with recurrent dislocations or unstable hip joints, cementless revision implants restore proper alignment and stability.
After infection-related implant removal and eradication of infection, cementless designs provide a reliable option for re-implantation.
In some cases, the natural bone may take longer to grow into the implant, leading to temporary instability.
Patients with poor bone quality, such as those with severe osteoporosis, may not achieve adequate fixation, increasing the risk of implant failure.
Cementless revision procedures can be more technically demanding, requiring experienced surgeons and specialized equipment.
Improper implantation techniques may lead to fractures of the femur or acetabulum.
Over time, the components of the implant may wear, necessitating further revisions.
Cementless implants are often more expensive than cemented options, which may limit accessibility for some patients.
As the global population ages, the demand for hip revision surgeries is expected to increase, boosting the need for reliable implants.
Innovations in biocompatible materials, such as bioactive coatings and 3D-printed implants, are enhancing the performance of cementless systems.
The growing preference for biological fixation among surgeons ensures sustained adoption of cementless implants.
Expanding healthcare infrastructure in regions such as Asia-Pacific and Latin America presents untapped opportunities for market growth.
The integration of robotic-assisted surgery and AI-driven planning tools is improving the precision of cementless implant procedures.
The cementless revision hip is a cornerstone of modern orthopedic surgery, offering an effective, durable, and biocompatible solution for hip revision cases. Its innovative design promotes natural bone integration, reducing the risks associated with traditional cemented implants. While surgical challenges and patient-specific factors must be carefully considered, the advantages of cementless systems make them a preferred choice for many orthopedic surgeons.
As technology continues to advance and the global demand for revision surgeries grows, the cementless revision hip is set to play an increasingly vital role in enhancing patient outcomes and redefining standards in hip replacement surgery.
Warm reminder: This article is for reference only and cannot replace the doctor's professional advice. If you have any questions, please consult your attending physician.
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