J006
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: | |
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Quantity: | |
BC Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3510-02090 | 9 | 135 | 33.8 | 135 | CoCrMo | Blast | |
3510-02100 | 10 | 135 | 34.5 | ||||
3510-02110 | 11 | 135 | 35.3 | ||||
3510-02120 | 12 | 140 | 36 | ||||
3510-02130 | 13 | 145 | 36.8 | ||||
3510-02140 | 14 | 150 | 37.5 | ||||
3510-02150 | 15 | 150 | 38.3 | ||||
![]() | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() |
3511-01090 | 9 | 130 | 33.8 | 135 | CoCrMo | Polished | |
3511-01100 | 10 | 130 | 34.5 | ||||
3511-01110 | 11 | 135 | 35.3 | ||||
3511-01120 | 12 | 140 | 36 | ||||
3511-01130 | 13 | 145 | 36.8 | ||||
3511-01140 | 14 | 150 | 37.5 | ||||
3511-01150 | 15 | 155 | 38.3 | ||||
BC2 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3512-02090 | 9 | 180 | 33 | 135 | CoCrMo | Blast | |
3512-02100 | 10 | 190 | 33 | ||||
3512-02110 | 11 | 200 | 33 | ||||
3512-02120 | 12 | 210 | 34 | ||||
3512-02130 | 13 | 220 | 34 | ||||
3512-02140 | 14 | 230 | 35 | ||||
3512-02150 | 15 | 240 | 35 | ||||
BC3 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3516-03070 | 7 | 125 | 30.4 | 135 | CoCrMo | Blast | |
3516-03080 | 8 | 130 | 31.7 | ||||
3516-03090 | 9 | 135 | 33 | ||||
3516-03100 | 10 | 140 | 34.3 | ||||
3516-03110 | 11 | 145 | 35.6 | ||||
3516-03120 | 12 | 150 | 36.9 | ||||
3516-03130 | 13 | 155 | 38.2 | ||||
3516-03140 | 14 | 160 | 39.5 | ||||
BC4 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3513-03080 | 8 | 115 | 38.4 | 135 | CoCrMo | Polished | |
3513-03090 | 9 | 130 | 38.9 | ||||
3513-03100 | 10 | 140 | 39.8 | ||||
3513-03110 | 11 | 145 | 40.7 | ||||
3513-03120 | 12 | 150 | 41.3 | ||||
3513-03130 | 13 | 155 | 42.2 | ||||
3513-03140 | 14 | 160 | 43.1 | ||||
3513-03150 | 15 | 165 | 44 | ||||
3513-03160 | 16 | 170 | 44.8 | ||||
3513-03170 | 17 | 180 | 45.6 |
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 Cemented Revision Hip Product Catalog.
2. Choose Your Interested Cemented Revision Hip Product.
3. Ask For A Sample To Test Cemented Revision Hip.
4.Make An Order Of XC Medico's Cemented Revision Hip.
5.Become A Dealer Of XC Medico's Cemented Revision Hip.
1.Better Purchase Prices Of Cemented Revision Hip.
2.100% The Highest Quality Cemented Revision Hip.
3. Less Ordering Efforts.
4. Price Stability For The Period Of Agreement.
5. Sufficient Cemented Revision Hip.
6. Quick And Easy Assessment Of XC Medico's Cemented 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.
Cemented revision hip implants are a critical solution in addressing complications or failures of primary hip replacements. These implants use bone cement to secure the prosthesis, ensuring stability and functionality even in patients with compromised bone quality. This article provides an in-depth exploration of cemented revision hips, detailing their features, advantages, treatment applications, and future prospects, offering valuable insights for orthopedic professionals, patients, and medical researchers.
A cemented revision hip implant is a type of prosthesis used in revision hip arthroplasty to replace or repair a failed or problematic primary hip replacement. Unlike cementless designs, cemented implants rely on polymethylmethacrylate (PMMA) bone cement to bond the implant to the bone, providing immediate stability. This approach is particularly beneficial for patients with poor bone quality, such as those with osteoporosis or severe bone loss.
Cemented revision hips are designed to restore hip function, alleviate pain, and provide durable support. They are often utilized in cases where biological fixation through osseointegration (as seen in cementless implants) is not feasible.
The use of PMMA cement fills voids between the bone and implant, providing immediate and strong fixation.
Many cemented systems include modular heads, stems, and acetabular components, allowing surgeons to customize the implant to suit patient anatomy.
Polished stem designs reduce friction and wear, minimizing the risk of loosening or failure over time.
Constructed from cobalt-chromium alloys or titanium, cemented implants are highly resistant to corrosion and wear.
The stems often feature tapered designs for easier insertion and improved load distribution within the femoral canal.
PMMA bone cement is radiopaque, allowing surgeons to visualize the implant and cement layer during and after surgery using X-rays.
Some components include roughened or grit-blasted surfaces to improve cement adherence and reduce micro-motion.
Bone cement ensures that the implant achieves instant stability, eliminating the need for bone growth to secure the implant. This is especially beneficial for patients with poor bone quality.
Cemented designs can accommodate a wide range of patients, including those with significant bone loss, fractures, or conditions that impair biological fixation, such as osteoporosis.
The strong bond created by PMMA cement minimizes micromotion at the implant-bone interface, reducing the risk of loosening or wear-related complications.
For patients undergoing revision surgery due to implant failure or infection, cemented implants provide a reliable and predictable solution, even in compromised bone conditions.
The radiopaque nature of bone cement allows for easy post-operative monitoring of the implant’s position and the cement layer, enabling early detection of complications.
One of the most common reasons for revision surgery, cemented implants address the loosening of primary implants by providing immediate and stable fixation.
Fractures around a previous implant, particularly in older patients, are often stabilized effectively using cemented components.
Bone resorption caused by wear debris can be counteracted with cemented implants that compensate for bone loss.
In cases where infection has compromised the primary implant, a cemented revision hip can be used alongside antibiotic-loaded cement for infection control.
For patients with severe bone loss, cemented implants provide robust support that might not be achievable with cementless options.
Bone cement can lead to rare complications such as cement embolism, where particles of cement enter the bloodstream and cause blockages.
The exothermic reaction of PMMA during setting can generate heat, potentially damaging surrounding bone tissue.
While cement provides immediate stability, long-term loosening may occur, particularly if the cement bond weakens.
A rare but serious complication, BCIS involves hypotension, hypoxia, or cardiac issues during or after cement application.
Revision of cemented implants can be more complex due to the need to remove hardened cement without damaging the remaining bone.
As with any surgical procedure, there is a risk of post-operative infection, which may necessitate additional surgeries or treatments.
As the global population ages, the incidence of hip replacements and subsequent revisions will rise, driving demand for cemented implants.
Innovations in PMMA formulations, such as antibiotic-loaded and bioactive cements, are improving the performance and safety of cemented implants.
Surgeons often favor cemented implants for patients with poor bone quality or significant bone loss, ensuring continued demand.
Growth in healthcare infrastructure in Asia-Pacific, Latin America, and the Middle East is expected to drive adoption of cemented implants in these regions.
Ongoing R&D is focused on improving implant designs, cement formulations, and surgical techniques to enhance outcomes and reduce complications.
The cemented revision hip implant remains a cornerstone of modern orthopedic surgery, particularly for patients with compromised bone quality or complex revision needs. With features such as immediate stability, high versatility, and adaptability to a range of fracture types, these implants provide reliable outcomes for both patients and surgeons. While there are inherent risks, advancements in implant materials, cement formulations, and surgical techniques continue to minimize complications and improve results.
As the demand for hip revision surgeries grows globally, the cemented revision hip is poised to remain a critical tool in orthopedic care, offering stability, functionality, and improved quality of life for patients undergoing complex hip procedures.
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.
BC Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3510-02090 | 9 | 135 | 33.8 | 135 | CoCrMo | Blast | |
3510-02100 | 10 | 135 | 34.5 | ||||
3510-02110 | 11 | 135 | 35.3 | ||||
3510-02120 | 12 | 140 | 36 | ||||
3510-02130 | 13 | 145 | 36.8 | ||||
3510-02140 | 14 | 150 | 37.5 | ||||
3510-02150 | 15 | 150 | 38.3 | ||||
![]() | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() |
3511-01090 | 9 | 130 | 33.8 | 135 | CoCrMo | Polished | |
3511-01100 | 10 | 130 | 34.5 | ||||
3511-01110 | 11 | 135 | 35.3 | ||||
3511-01120 | 12 | 140 | 36 | ||||
3511-01130 | 13 | 145 | 36.8 | ||||
3511-01140 | 14 | 150 | 37.5 | ||||
3511-01150 | 15 | 155 | 38.3 | ||||
BC2 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3512-02090 | 9 | 180 | 33 | 135 | CoCrMo | Blast | |
3512-02100 | 10 | 190 | 33 | ||||
3512-02110 | 11 | 200 | 33 | ||||
3512-02120 | 12 | 210 | 34 | ||||
3512-02130 | 13 | 220 | 34 | ||||
3512-02140 | 14 | 230 | 35 | ||||
3512-02150 | 15 | 240 | 35 | ||||
BC3 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3516-03070 | 7 | 125 | 30.4 | 135 | CoCrMo | Blast | |
3516-03080 | 8 | 130 | 31.7 | ||||
3516-03090 | 9 | 135 | 33 | ||||
3516-03100 | 10 | 140 | 34.3 | ||||
3516-03110 | 11 | 145 | 35.6 | ||||
3516-03120 | 12 | 150 | 36.9 | ||||
3516-03130 | 13 | 155 | 38.2 | ||||
3516-03140 | 14 | 160 | 39.5 | ||||
BC4 Stem | |||||||
Code | Size | Stem Length | Offset | Neck Angle | Mat. | Coating | ![]() ![]() |
3513-03080 | 8 | 115 | 38.4 | 135 | CoCrMo | Polished | |
3513-03090 | 9 | 130 | 38.9 | ||||
3513-03100 | 10 | 140 | 39.8 | ||||
3513-03110 | 11 | 145 | 40.7 | ||||
3513-03120 | 12 | 150 | 41.3 | ||||
3513-03130 | 13 | 155 | 42.2 | ||||
3513-03140 | 14 | 160 | 43.1 | ||||
3513-03150 | 15 | 165 | 44 | ||||
3513-03160 | 16 | 170 | 44.8 | ||||
3513-03170 | 17 | 180 | 45.6 |
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 Cemented Revision Hip Product Catalog.
2. Choose Your Interested Cemented Revision Hip Product.
3. Ask For A Sample To Test Cemented Revision Hip.
4.Make An Order Of XC Medico's Cemented Revision Hip.
5.Become A Dealer Of XC Medico's Cemented Revision Hip.
1.Better Purchase Prices Of Cemented Revision Hip.
2.100% The Highest Quality Cemented Revision Hip.
3. Less Ordering Efforts.
4. Price Stability For The Period Of Agreement.
5. Sufficient Cemented Revision Hip.
6. Quick And Easy Assessment Of XC Medico's Cemented 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.
Cemented revision hip implants are a critical solution in addressing complications or failures of primary hip replacements. These implants use bone cement to secure the prosthesis, ensuring stability and functionality even in patients with compromised bone quality. This article provides an in-depth exploration of cemented revision hips, detailing their features, advantages, treatment applications, and future prospects, offering valuable insights for orthopedic professionals, patients, and medical researchers.
A cemented revision hip implant is a type of prosthesis used in revision hip arthroplasty to replace or repair a failed or problematic primary hip replacement. Unlike cementless designs, cemented implants rely on polymethylmethacrylate (PMMA) bone cement to bond the implant to the bone, providing immediate stability. This approach is particularly beneficial for patients with poor bone quality, such as those with osteoporosis or severe bone loss.
Cemented revision hips are designed to restore hip function, alleviate pain, and provide durable support. They are often utilized in cases where biological fixation through osseointegration (as seen in cementless implants) is not feasible.
The use of PMMA cement fills voids between the bone and implant, providing immediate and strong fixation.
Many cemented systems include modular heads, stems, and acetabular components, allowing surgeons to customize the implant to suit patient anatomy.
Polished stem designs reduce friction and wear, minimizing the risk of loosening or failure over time.
Constructed from cobalt-chromium alloys or titanium, cemented implants are highly resistant to corrosion and wear.
The stems often feature tapered designs for easier insertion and improved load distribution within the femoral canal.
PMMA bone cement is radiopaque, allowing surgeons to visualize the implant and cement layer during and after surgery using X-rays.
Some components include roughened or grit-blasted surfaces to improve cement adherence and reduce micro-motion.
Bone cement ensures that the implant achieves instant stability, eliminating the need for bone growth to secure the implant. This is especially beneficial for patients with poor bone quality.
Cemented designs can accommodate a wide range of patients, including those with significant bone loss, fractures, or conditions that impair biological fixation, such as osteoporosis.
The strong bond created by PMMA cement minimizes micromotion at the implant-bone interface, reducing the risk of loosening or wear-related complications.
For patients undergoing revision surgery due to implant failure or infection, cemented implants provide a reliable and predictable solution, even in compromised bone conditions.
The radiopaque nature of bone cement allows for easy post-operative monitoring of the implant’s position and the cement layer, enabling early detection of complications.
One of the most common reasons for revision surgery, cemented implants address the loosening of primary implants by providing immediate and stable fixation.
Fractures around a previous implant, particularly in older patients, are often stabilized effectively using cemented components.
Bone resorption caused by wear debris can be counteracted with cemented implants that compensate for bone loss.
In cases where infection has compromised the primary implant, a cemented revision hip can be used alongside antibiotic-loaded cement for infection control.
For patients with severe bone loss, cemented implants provide robust support that might not be achievable with cementless options.
Bone cement can lead to rare complications such as cement embolism, where particles of cement enter the bloodstream and cause blockages.
The exothermic reaction of PMMA during setting can generate heat, potentially damaging surrounding bone tissue.
While cement provides immediate stability, long-term loosening may occur, particularly if the cement bond weakens.
A rare but serious complication, BCIS involves hypotension, hypoxia, or cardiac issues during or after cement application.
Revision of cemented implants can be more complex due to the need to remove hardened cement without damaging the remaining bone.
As with any surgical procedure, there is a risk of post-operative infection, which may necessitate additional surgeries or treatments.
As the global population ages, the incidence of hip replacements and subsequent revisions will rise, driving demand for cemented implants.
Innovations in PMMA formulations, such as antibiotic-loaded and bioactive cements, are improving the performance and safety of cemented implants.
Surgeons often favor cemented implants for patients with poor bone quality or significant bone loss, ensuring continued demand.
Growth in healthcare infrastructure in Asia-Pacific, Latin America, and the Middle East is expected to drive adoption of cemented implants in these regions.
Ongoing R&D is focused on improving implant designs, cement formulations, and surgical techniques to enhance outcomes and reduce complications.
The cemented revision hip implant remains a cornerstone of modern orthopedic surgery, particularly for patients with compromised bone quality or complex revision needs. With features such as immediate stability, high versatility, and adaptability to a range of fracture types, these implants provide reliable outcomes for both patients and surgeons. While there are inherent risks, advancements in implant materials, cement formulations, and surgical techniques continue to minimize complications and improve results.
As the demand for hip revision surgeries grows globally, the cemented revision hip is poised to remain a critical tool in orthopedic care, offering stability, functionality, and improved quality of life for patients undergoing complex hip procedures.
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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