A surgeon places a bone graft into position during a limb salvage.
Bone generally has the ability to regenerate completely but requires a very small fracture space or some sort of scaffold to do so. Bone grafts may be autologous (bone harvested from the patient’s own body, often from the iliac crest), allograft (cadaveric bone usually obtained from a bone bank), or synthetic (often made of hydroxyapatite or other naturally occurring and biocompatible substances) with similar mechanical properties to bone. Most bone grafts are expected to be reabsorbed and replaced as the natural bone heals over a few months’ time.
The principles involved in successful bone grafts include osteoconduction (guiding the reparative growth of the natural bone), osteoinduction (encouraging undifferentiated cells to become active osteoblasts), and osteogenesis (living bone cells in the graft material contribute to bone remodeling). Osteogenesis only occurs with autograft tissue and allograft cellular bone matrices, such as Trinity ELITE (MTF/Orthofix), BIO4/Stryker) and Osteocel Plus (AlloSource/NuVasive).
- 1 Biological mechanism
- 2 Uses
- 3 Procedure
- 4 Risks
- 5 Recovery and aftercare
- 6 Costs
- 7 See also
- 8 References
- 9 Further reading
Bone grafting is possible because bone tissue, unlike most other tissues, has the ability to regenerate completely if provided the space into which to grow. As native bone grows, it will generally replace the graft material completely, resulting in a fully integrated region of new bone. The biologic mechanisms that provide a rationale for bone grafting are osteoconduction, osteoinduction and osteogenesis.
Osteoconduction occurs when the bone graft material serves as a scaffold for new bone growth that is perpetuated by the native bone. Osteoblasts from the margin of the defect that is being grafted utilize the bone graft material as a framework upon which to spread and generate new bone. In the very least, a bone graft material should be osteoconductive.
Osteoinduction involves the stimulation of osteoprogenitor cells to differentiate into osteoblasts that then begin new bone formation. The most widely studied type of osteoinductive cell mediators are bone morphogenetic proteins (BMPs). A bone graft material that is osteoconductive and osteoinductive will not only serve as a scaffold for currently existing osteoblasts but will also trigger the formation of new osteoblasts, theoretically promoting faster integration of the graft.
Osteopromotion involves the enhancement of osteoinduction without the possession of osteoinductive properties. For example, enamel matrix derivative has been shown to enhance the osteoinductive effect of demineralized freeze dried bone allograft (DFDBA), but will not stimulate de novo bone growth alone.
Osteogenesis occurs when vital osteoblasts originating from the bone graft material contribute to new bone growth along with bone growth generated via the other two mechanisms.
Autologous (or autogenous) bone grafting involves utilizing bone obtained from the same individual receiving the graft. Bone can be harvested from non-essential bones, such as from the iliac crest, or more commonly in oral and maxillofacial surgery, from the mandibular symphysis (chin area) or anterior mandibular ramus (the coronoid process); this is particularly true for block grafts, in which a small block of bone is placed whole in the area being grafted. When a block graft will be performed, autogenous bone is the most preferred because there is less risk of the graft rejection because the graft originated from the patient's own body. As indicated in the chart above, such a graft would be osteoinductive and osteogenic, as well as osteoconductive. A negative aspect of autologous grafts is that an additional surgical site is required, in effect adding another potential location for post-operative pain and complications.
All bone requires a blood supply in the transplanted site. Depending on where the transplant site is and the size of the graft, an additional blood supply may be required. For these types of grafts, extraction of the part of the periosteum and accompanying blood vessels along with donor bone is required. This kind of graft is known as a vital bone graft.
An autograft may also be performed without a solid bony structure, for example using bone reamed from the anterior superior iliac spine. In this case there is an osteoinductive and osteogenic action, however there is no osteoconductive action, as there is no solid bony structure.
Chin offers a large amount of cortico-cancellous autograft and easy access among all the intraoral sites. It can be easily harvested in the office settings under local anaesthesia on an outpatient basis. Proximity of the donor and recipient sites reduce operative time and cost. Convenient surgical access, low morbidity, elimination of hospital stay, minimal donor site discomfort and avoidance of cutaneous scars are the added advantages.
Dentin bone, made from extracted teeth, Dentin comprises more than 85% of tooth structure, the enamel consists of HA mineral and comprises 10% of tooth structure. Dentin is unlike bone in its chemical composition, by volume 50% is HA mineral and 50% organic matrix, mostly fibrous type I collagen. Dentin, like bone, may release growth and differentiating factors while being resorbed by osteoclasts. In order to make the dentin graft usable and bacteria-free some companies have developed clinical procedures which include grinding, sorting and cleaning of the teeth for immediate or future use. In Korea, the Korea Tooth Bank performed bio-recycling of 38 000 patients' own teeth from January 2009 until October 2012.
Allograft bone, like autogenous bone, is derived from humans; the difference is that allograft is harvested from an individual other than the one receiving the graft. Allograft bone can be taken from cadavers that have donated their bone so that it can be used for living people who are in need of it; it is typically sourced from a bone bank. Bone banks also supply allograft bone sourced from living human bone donors (usually hospital inpatients) who are undergoing elective total hip arthroplasty (total hip replacement surgery). During total hip replacement, the orthopaedic surgeon removes the patient's femoral head, as a necessary part of the process of inserting the artificial hip prosthesis. The femoral head is a roughly spherical area of bone, located at the proximal end of the femur, with a diameter of 45 mm to 56 mm in adult humans. The patient's femoral head is most frequently discarded to hospital waste at the end of the surgical procedure. However, if a patient satisfies a number of stringent regulatory, medical and social history criteria, and provides informed consent, their femoral head may be deposited in the hospital's bone bank.
There are three types of bone allograft available:
- Fresh or fresh-frozen bone
- Freeze-dried bone allograft (FDBA)
- Demineralized freeze-dried bone allograft (DFDBA)
Artificial bone can be created from ceramics such as calcium phosphates (e.g. hydroxyapatite and tricalcium phosphate), Bioglass and calcium sulphate; all of which are biologically active to different degrees depending on solubility in the physiological environment. These materials can be doped with growth factors, ions such as strontium or mixed with bone marrow aspirate to increase biological activity. Some authors believe this method is inferior to autogenous bone grafting however infection and rejection of the graft is much less of a risk, and the mechanical properties such as Young's modulus are comparable to bone. The presence of elements such as strontium can result in higher bone mineral density and enhanced osteoblast proliferation in vivo.
Xenograft bone substitute has its origin from a species other than human, such as bovine bone (or recently porcine bone) which can be freeze dried or demineralized and deproteinized. Xenografts are usually only distributed as a calcified matrix. Madrepore and or millepore type of corals are harvested and treated to become 'coral derived granules' (CDG) and other types of coralline xenografts. Coral based xenografts are mainly calcium carbonate (and an important proportion of fluorides, useful in the context of grafting to promote bone development) while natural human bone is made of hydroxyapatite along with calcium phosphate and carbonate: the coral material is thus either transformed industrially into hydroxyapatite through a hydrothermal process, yielding a non-resorbable xenograft, or simply the process is omitted and the coralline material remains in its calcium carbonate state for better resorption of the graft by the natural bone. The coral xenograft is then saturated with growth enhancing gels and solutions.
Alloplastic grafts may be made from hydroxylapatite, a naturally occurring mineral that is also the main mineral component of bone. They may be made from bioactive glass. Hydroxylapatite is a Synthetic Bone Graft, which is the most used now among other synthetic due to its osteoconduction, hardness and acceptability by bone. Some synthetic bone graft are made of calcium carbonate, which start to decrease in usage because it is completely resorbable in short time which make the bone easy to break again. Tricalcium phosphate which now used in combination with hydroxylapatite thus give both effect osteoconduction and resorbability. Polymers such as some microporous grades of PMMA and various other acrylates (such as polyhydroxylethylmethacrylate aka PHEMA), coated with calcium hydroxide for adhesion, are also used as alloplastic grafts for their inhibition of infection and their mechanical resilience and biocompatibility. Calcifying marine algae such as Corallina officinalis have a fluorohydroxyapatitic composition whose structure is similar to human bone and offers gradual resorption, thus it is treated and standardized as "FHA (Fluoro-hydroxy-apatitic) biomaterial" alloplastic bone grafts.
Growth Factor enhanced grafts are produced using recombinant DNA technology. They consist of either Human Growth Factors or Morphogens (Bone Morphogenic Proteins in conjunction with a carrier medium, such as collagen).
The most common use of bone grafting is in the application of dental implants to restore the edentulous area of a missing tooth. Dental implants require bones underneath them for support and proper integration into the mouth. As mentioned earlier bone grafts come in various forms such as autologous (from the same person), Allograft, Xenograft (mainly bovine bone), and Alloplastic materials. Bone grafts can be used prior to implant placement or simultaneously.  People who have been edentulous (without teeth) for a prolonged period may not have enough bone left in the necessary locations. In this case, bone can be taken from the chin, from the pilot holes for the implants, or even from the iliac crest of the pelvis and inserted into the mouth underneath the new implant.
In general, bone graft is either used en block (such as from the chin or the ascending ramus area of the lower jaw) or particulated, in order to be able to adapt it better to a defect.
Dental bone grafting is a specialized oral surgical procedure that has been developed to reestablish lost jawbone. This loss can be a result of dental infection of abscess, periodontal disease, or trauma. There are various reasons for replacing lost bone tissue and encouraging natural bone growth, and each technique tackles jawbone defects differently. Reasons that bone grafting might be needed include sinus augmentation, socket preservation, ridge augmentation, or regeneration.
Another common bone graft, which is more substantial than those used for dental implants, is of the fibular shaft. After the segment of the fibular shaft has been removed normal activities such as running and jumping are permitted on the leg with the bone deficit. The grafted, vascularized fibulas have been used to restore skeletal integrity to long bones of limbs in which congenital bone defects exist and to replace segments of bone after trauma or malignant tumor invasion. The periosteum and nutrient artery are generally removed with the piece of bone so that the graft will remain alive and grow when transplanted into the new host site. Once the transplanted bone is secured into its new location it generally restores blood supply to the bone in which it has been attached.
Besides the main use of bone grafting – dental implants – this procedure is used to fuse joints to prevent movement, repair broken bones that have bone loss, and repair broken bone that has not yet healed.
Depending on where the bone graft is needed, a different doctor may be requested to do the surgery. Doctors that do bone graft procedures are commonly orthopedic surgeons, otolaryngology head and neck surgeon, neurosurgeons, craniofacial surgeons, oral and maxillofacial surgeons, podiatric surgeons and periodontists, dental surgeons, oral surgeons and implantologists.
As with any procedure, there are risks involved; these include reactions to medicine, problems breathing, bleeding, and infection. Infection is reported to occur in less than 1% of cases and is curable with antibiotics. Overall, patients with a preexisting illness are at a higher risk of getting an infection as opposed to those who are overall healthy.
Risks for grafts from the iliac crest
- acquired bowel herniation (this becomes a risk for larger donor sites (>4 cm)). About 20 cases have been reported in the literature from 1945 till 1989 and only a few hundred cases have been reported worldwide
- meralgia paresthetica (injury to the lateral femoral cutaneous nerve also called Bernhardt-Roth's syndrome)
- pelvic instability
- fracture (extremely rare and usually with other factors)
- injury to the clunial nerves (this will cause posterior pelvic pain which is worsened by sitting)
- injury to the ilioinguinal nerve
- minor hematoma (a common occurrence)
- deep hematoma requiring surgical intervention
- ureteral injury
- pseudoaneurysm of iliac artery (rare)
- tumor transplantation
- cosmetic defects (chiefly caused by not preserving the superior pelvic brim)
- chronic pain
Recovery and aftercare
The time it takes for an individual to recover depends on the severity of the injury being treated and lasts anywhere from two weeks to two months, with a possibility of vigorous exercise being barred for up to six months.
Bone graft procedures consist of more than just the surgery itself. The complete 3-month total cost of a complex posterolateral lumbar spine fusion bone graft supplemented with graft extenders ranges from a mean of approximately $33,860 to $37,227. This price includes all visits in and out of the hospital for 3 months. Besides the cost of the bone graft itself (ranging from $250 to $900) other expenses for the procedure include: outpatient rehabilitation fees ($5,000 to $7,000), screws and rods ($7,500), room and board ($5,000), operating room ($3,500), sterile supplies ($1,100), physical therapy ($1,000), surgeon's fees (average $3,500), anesthesiologist fees (approximately $350 to $400 per hour), medication charges ($1,000), and additional fees for services such as medical supplies, diagnostic procedures, equipment use fees, etc.
- Klokkevold, PR, Jovanovic, SA (2002). "Advanced Implant Surgery and Bone Grafting Techniques". In Newman, Takei, Carranza. Carranza's Clinical Periodontology (9th ed.). Philadelphia: W.B. Saunders. pp. 907–8.
- Boyan BD, Weesner TC, Lohmann CH et al. (August 2000). "Porcine fetal enamel matrix derivative enhances bone formation induced by demineralized freeze dried bone allograft in vivo". J. Periodontol. 71 (8): 1278–86. doi:10.1902/jop.2000.71.8.1278. PMID 10972643.
- "Bone Grafts: No Longer Just a Chip Off the Ol' Hip".
- "Bone Graft Alternatives" (PDF). Retrieved 18 January 2009.
- "Human Dentin as Novel Biomaterial for Bone Regeneration" (PDF).
- Bone Allografts
- Hench, Larry L (1991). "Bioceramics: From Concept to Clinic" (PDF). Journal of the American Ceramic Society 74 (7): 1487. doi:10.1111/j.1151-2916.1991.tb07132.x.
- 'Bone augmentation procedures in localized defects in the alveolar ridge: clinical results with different bone grafts and bone-substitute materials' volume 24 supplement, Jensen Terheyden, 2009
- 'Bone Grafts and Bone Graft Substitutes in Periodontal Therapy' p.92 Chapter 2.3.3 'coralline calcium carbonate', Dumitrescu et al, 2011, Springer ,ISBN 978-3-642-18224-2
- Dumitrescu & al, 2011, p.94-95 ISBN 978-3-642-18224-2
- Dumitrescu et al, 2011, p.101-102 ISBN 978-3-642-18224-2
- Le BT, Borzabadi-Farahani A. (2014). "Simultaneous implant placement and bone grafting with particulate mineralized allograft in sites with buccal wall defects, a three-year follow-up and review of literature.". J Craniomaxillofac Surg. 42 (5): 552–9. PMID 24630053.
- "Bone Graft - Surgery Procedures & Risks - NY Times Health Information". The New York Times.
- "Bone Grafting - Definition, Purpose, Demographics, Description, Diagnosis/preparation, Aftercare, Risks, Normal results, Morbidity and mortality rates, Alternatives".
- John Gray Seiler III, MD, Joseph Johnson, MD, Georgia Hand and Microsurgery Clinic, Atlanta, Ga. (2000). "Iliac Crest Autogenous Bone Grafting: Donor Site Complications". J South Orthop Assoc 9 (2): 91–97. PMID 10901646.
- Banwart JC, Asher MA, Hassanein RS. (May 1995). "Iliac crest bone graft harvest donor site morbidity. A statistical evaluation". Spine 20 (9): 1055–60. doi:10.1097/00007632-199505000-00012. PMID 7631235.
- Arrington ED, Smith WJ, Chambers HG, Bucknell AL, Davino NA. (August 1996). "Complications of iliac crest bone graft harvesting". Clin Orthop Relat Res. 329 (329): 300–9. doi:10.1097/00003086-199608000-00037. PMID 8769465.
- M. M. Hamad; S. A. Majeed (November 1989). "Incisional hernia through iliac crest defects". Archives of Orthopaedic and Trauma Surgery 108 (6): 383–385. doi:10.1007/BF00932452. PMID 2695010.
- Anisuddin Bhatti, Waqar Ahmed. (June 1999). "Herniation through ILiac Crest Bone Graft donor site". J Surg Pak 4 (2): 37–9.
- "Pelvic fracture: The iliac crest bone grafting complication".
- Matthew J Oakley,Wade R Smith, Steven J Morgan, Navid M Ziran, and Bruce H Ziran (2007). "Repetitive posterior iliac crest autograft harvest resulting in an unstable pelvic fracture and infected non-union: case report and review of the literature". Patient Saf Surg. 1 (6): 6–13. doi:10.1186/1754-9493-1-6. PMC 241775. PMID 18271999.
- Andy Shau-Bin Chou, MD; Chein-Fu Hung, MD; Jeng-Hwei Tseng, MD; Kuang-Tse Pan, MD; Pao-Sheng Yen, MD; (July 2002). "Pseudoaneurysm of the Deep Circumflex Iliac Artery: A Rare Complication at an Anterior Iliac Bone Graft Donor Site Treated by Coil Embolization" (PDF). Chang Gung Med J 25 (7).[dead link]
- Marx RE, Morales MJ (March 1988). "Morbidity from bone harvest in major jaw reconstruction: a randomized trial comparing the lateral anterior and posterior approaches to the ilium". J. Oral Maxillofac. Surg. 46 (3): 196–203. doi:10.1016/0278-2391(88)90083-3. PMID 3280759.
- Ahlmann E, Patzakis M, Roidis N, Shepherd L, Holtom P (May 2002). "Comparison of anterior and posterior iliac crest bone grafts in terms of harvest-site morbidity and functional outcomes". J Bone Joint Surg Am 84–A (5): 716–20. PMID 12004011.
- Glassman SD, Carreon LY, Campbell MJ, Johnson JR, Puno RM, Djurasovic M, Dimar JR (2008). "The perioperative cost of Infuse bone graft in posterolateral lumbar spine fusion". Spine J 8 (3): 443–8. doi:10.1016/j.spinee.2007.03.004. PMID 17526436.
- "Bone grafting".
- Desai, AJ; Thomas, R; Tarun Kumar, AB; Mehta, DS (2013). "Current concepts and guidelines in chin graft harvesting: A literature review". International Journal of Oral Health Sciences 3 (1): 16–25. doi:10.4103/2231-6027.122094.