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Intramembranous ossification

Intramembranous ossification is the direct formation of bone tissue from mesenchymal connective tissue without an intermediate cartilage model, primarily responsible for the development of the flat bones of the skull, face, and clavicles.^[1] This process begins during embryonic development and continues through early postnatal growth, contributing to the rapid expansion of cranial structures to accommodate the growing brain.^[2] The process initiates with clusters of mesenchymal cells, derived from neural crest or mesoderm, proliferating and condensing into ossification centers within fibrous membranes.^[3] These cells differentiate into osteoblasts under the influence of signaling molecules such as bone morphogenetic proteins (BMP2, BMP4, and BMP7) and the transcription factor CBFA1 (also known as RUNX2), which promote osteoblast differentiation.^[2] Osteoblasts then secrete an organic matrix called osteoid, composed primarily of collagen and proteoglycans, which subsequently mineralizes through the deposition of calcium phosphate salts, forming hydroxyapatite crystals.^[2] As mineralization progresses, osteoblasts become embedded within the matrix and mature into osteocytes, while surrounding cells form the periosteum and initial trabecular (spongy) bone structure.^[1] The development proceeds in distinct stages: first, the formation of ossification centers where mesenchymal clusters differentiate; second, the secretion and calcification of osteoid into spicules that interconnect to form trabeculae; third, the establishment of the periosteum and vascular invasion leading to red bone marrow formation; and finally, the superficial remodeling into compact (cortical) bone through appositional growth.^[3] Unlike endochondral ossification, which replaces a hyaline cartilage template and is typical for long bones and the base of the skull, intramembranous ossification lacks this cartilaginous precursor, allowing for faster bone formation but potentially greater susceptibility to certain developmental disorders.^[1] Clinically, disruptions in intramembranous ossification are implicated in conditions such as cleidocranial dysplasia, caused by mutations in the RUNX2 gene, leading to delayed closure of cranial sutures, absent or hypoplastic clavicles, and dental abnormalities.^[1] This process also plays a role in fracture healing and periosteal bone widening throughout life, highlighting its ongoing physiological importance beyond embryogenesis.^[1]

Overview and Fundamentals

Definition and Process Summary

Intramembranous ossification is the process by which bone tissue forms directly from mesenchymal connective tissue without the intermediate formation of a cartilage model.^[1] This mode of ossification primarily occurs during embryonic development to produce the flat bones of the skull, such as the frontal and parietal bones, as well as the clavicle.^[2] Unlike endochondral ossification, which involves a cartilaginous precursor, intramembranous ossification relies on the direct differentiation of mesenchymal cells into bone-producing cells.^[3] The process begins with the proliferation and condensation of mesenchymal cells into compact nodules at sites destined to become bone, establishing ossification centers.^[2] These cells then differentiate into osteoblasts, which secrete an organic matrix known as osteoid, composed primarily of collagen and proteoglycans.^[1] The osteoid subsequently mineralizes through the deposition of calcium salts, forming a calcified matrix that traps some osteoblasts, converting them into osteocytes embedded within the bone tissue.^[3] As mineralization progresses, the initial woven bone structure emerges, with bony spicules radiating outward and surrounding mesenchymal cells organizing into the periosteum, which contributes to further bone deposition.^[2] This trabecular (woven) bone then remodels over time, with superficial layers developing into compact cortical bone, while vascularization leads to the formation of red marrow within the trabeculae.^[1] The entire sequence enables the rapid formation of membranous bones essential for protecting vital structures like the brain during early development.^[3]

Comparison to Endochondral Ossification

Intramembranous ossification differs fundamentally from endochondral ossification in its direct formation of bone from mesenchymal connective tissue without an intervening hyaline cartilage template, whereas endochondral ossification replaces a pre-existing cartilage model through hypertrophy, vascular invasion, and subsequent mineralization. This direct process in intramembranous ossification occurs within the mesenchyme, leading to the initial production of woven bone in flat structures such as the cranial vault and clavicle, in contrast to endochondral ossification, which develops long bones like the femur and humerus through a slower, staged replacement that supports longitudinal growth via epiphyseal plates.^[1]^[4]^[3] The intramembranous pathway is notably faster, bypassing the cartilage formation and resorption phases of endochondral ossification, which allows for quicker skeletal stabilization but limits adaptability for complex, weight-bearing shapes. This rapidity provides a key advantage in intramembranous ossification by enabling swift development of protective bony elements, such as those shielding the brain during rapid embryonic growth.^[1]^[4] From an evolutionary perspective, intramembranous ossification is considered a primitive mechanism, originating in early vertebrates as dermal bone mineralization around soft tissues for protective shields and odontode-like structures, and retained for specific exoskeletal elements like the cranium, while endochondral ossification evolved later to support endoskeletal expansion in more derived taxa.^[5]^[6]

Cellular and Molecular Mechanisms

Mesenchymal Cell Differentiation

Intramembranous ossification initiates with the aggregation of mesenchymal stem cells (MSCs) into dense condensates within the mesenchymal tissue, a process driven by signaling molecules such as bone morphogenetic proteins (BMPs) and fibroblast growth factors (FGFs). BMPs, particularly BMP2 and BMP4, promote mesenchymal cell proliferation and condensation by activating Smad-dependent pathways that enhance cell adhesion and migration, leading to the formation of these clusters that serve as precursors for bone formation.^[7]^[8] Similarly, FGF signaling, mediated through receptors like FGFR1 and FGFR2, supports condensation by regulating cell proliferation and survival within the mesenchyme, ensuring the spatial organization necessary for subsequent osteogenic commitment.^[9] These condensates form primarily in the cranial vault, facial bones, and clavicles, where intramembranous ossification predominates.^[10] Within these condensates, MSCs undergo a stepwise differentiation pathway toward bone-forming cells, progressing from undifferentiated MSCs to osteoprogenitor cells, then to pre-osteoblasts, and finally to mature osteoblasts. This lineage commitment is orchestrated by key transcription factors, with Runx2 acting as the master regulator that initiates the osteogenic program by binding to promoter regions of genes involved in osteoblast specification, thereby driving MSCs toward the pre-osteoblast stage.^[11]^[12] Downstream of Runx2, Osterix (also known as Sp7) is essential for the maturation of pre-osteoblasts into fully functional osteoblasts, as it regulates the expression of genes required for alkaline phosphatase activity and collagen synthesis without which osteoblast differentiation arrests.^[13]^[14] This sequential activation ensures that only committed progenitors proceed to produce bone matrix, distinguishing intramembranous ossification from other skeletal developmental modes.^[15] Vascular invasion plays a critical supportive role in this differentiation process, as endothelial cells infiltrating the condensates release vascular endothelial growth factor (VEGF), which not only promotes angiogenesis but also directly enhances osteoblast differentiation through paracrine signaling. VEGF binds to receptors on MSCs and osteoprogenitors, activating pathways like PI3K/Akt that upregulate Runx2 expression and facilitate the transition to mature osteoblasts.^[16]^[17] This endothelial-osteoblast crosstalk is vital in intramembranous sites, where blood vessel ingrowth coincides with the onset of osteogenic differentiation, ensuring nutrient supply and synchronization of bone formation.^[18]

Osteoblast Activity and Matrix Secretion

Following differentiation from mesenchymal precursor cells, osteoblasts play a central role in intramembranous ossification by synthesizing and secreting the organic components of the bone extracellular matrix. These cells actively produce type I collagen, which constitutes approximately 90% of the organic matrix and provides tensile strength to the developing bone.^[19] In addition, osteoblasts secrete non-collagenous proteins such as osteocalcin, which binds calcium and regulates mineralization initiation, and bone sialoprotein, which promotes cell attachment and matrix organization.^[19]^[20] These proteins, along with proteoglycans and glycoproteins forming the ground substance, are assembled into an unmineralized matrix known as osteoid, which serves as the scaffold for subsequent bone hardening.^[1] The activity of osteoblasts in matrix secretion is tightly regulated by hormonal signals that influence gene expression and cellular function. Parathyroid hormone (PTH) acts as a positive regulator, stimulating osteoblast proliferation, differentiation, and the expression of genes encoding type I collagen and alkaline phosphatase, thereby enhancing matrix production.^[21] Vitamin D, particularly its active form 1,25-dihydroxyvitamin D3, synergizes with PTH to upregulate osteoblast-specific genes, including those for osteocalcin and bone sialoprotein, while also promoting the transition of osteoblasts toward matrix-secreting phenotypes.^[22]^[23] These regulatory mechanisms ensure coordinated deposition of osteoid during intramembranous bone formation. As the secreted osteoid undergoes calcification, some osteoblasts become embedded within the mineralizing matrix and differentiate into osteocytes, which maintain connectivity through dendritic processes to sense mechanical stress and coordinate further bone activity.^[24] This entrapment typically occurs in 10-20% of osteoblasts, with the majority remaining on the bone surface to continue matrix elaboration or undergoing apoptosis.^[25]

Stages of Bone Formation

Formation of Woven Bone

Woven bone represents the earliest stage of mineralized tissue in intramembranous ossification, distinguished by its disorganized structure that enables rapid skeletal framework establishment. It features randomly oriented collagen fibers arranged in a loose, interlacing pattern, contrasting with the parallel alignment seen in mature bone. This matrix exhibits high cellularity, with numerous osteocytes embedded haphazardly within the tissue, reflecting the swift proliferation and differentiation of mesenchymal precursors into osteoblasts. Additionally, mineralization occurs irregularly, resulting in a coarse, woven texture that serves primarily as a temporary scaffold to support subsequent bone maturation and mechanical loading during development.^[26]^[27] The process of woven bone formation commences with osteoblasts secreting osteoid, an unmineralized organic matrix composed mainly of type I collagen and proteoglycans. This is followed by the rapid deposition of mineral salts, predominantly hydroxyapatite (Ca₁₀(PO₄)₆(OH)₂), onto the osteoid surface, which crystallizes and hardens the matrix to form the initial bone spicules. This mineralization is enzymatically driven by alkaline phosphatase, an ectoenzyme expressed on osteoblast membranes that hydrolyzes phosphate esters to elevate local inorganic phosphate levels, thereby promoting hydroxyapatite nucleation and growth. The overall rapidity of this deposition—occurring without an intervening cartilage template—allows woven bone to provide immediate structural integrity in regions requiring quick ossification.^[1]^[26] In human embryogenesis, woven bone formation via intramembranous ossification initiates between the sixth and eighth weeks, with early evidence appearing in the mandible around week six and extending to cranial vault bones by weeks seven to eight. This timeline aligns with the peak activity of osteogenic centers in the developing skull, where the process outpaces the slower, more organized deposition characteristic of lamellar bone, enabling efficient enclosure of vital structures like the brain.^[1]^[28]

Development of Primary Ossification Centers

The development of primary ossification centers marks the initial phase of intramembranous ossification, where localized foci emerge within mesenchymal condensations of flat bone anlagen, such as those forming the cranial vault and clavicle. These centers originate from clusters of undifferentiated mesenchymal cells that aggregate in highly vascularized regions of the embryonic connective tissue, differentiating directly into osteoblasts under the influence of local signaling cues.^[1]^[29] Invading blood vessels form loops within these condensations, providing oxygen, nutrients, and osteogenic factors like vascular endothelial growth factor (VEGF), which promotes osteoblast differentiation in an autocrine manner.^[30] The osteoblasts surround these vascular structures and begin secreting unmineralized osteoid matrix, which rapidly calcifies through deposition of calcium and phosphate ions, establishing the foundational bone spicules at each center.^[1]^[31] Expansion of the primary ossification centers proceeds via appositional growth, in which peripheral mesenchymal cells along the developing periosteum differentiate into new osteoblasts that deposit successive layers of bone matrix parallel to the existing surface.^[1] This outward radial growth allows individual centers to enlarge progressively, driven by continued osteoblast proliferation and matrix secretion, while the central vascular loops facilitate nutrient supply to sustain the process.^[29] As multiple centers arise simultaneously within a single bone anlage—often numbering several in elements like the frontal or parietal bones—they expand until adjacent centers merge, interconnecting via bridging osteoid deposits to form cohesive, plate-like bone structures.^[30] This merging consolidates the irregular woven bone framework into a more unified flat bone template, with the initial matrix exhibiting the disorganized collagen fibers typical of woven bone.^[1] Several factors regulate the initiation, positioning, and expansion of these centers during embryonic development. Genetic control is mediated primarily by transcription factors such as Runx2 (also known as CBFA1) and Osterix, which orchestrate mesenchymal cell commitment to the osteoblast lineage and ensure precise spatiotemporal patterning of the centers; for instance, Runx2 mutations disrupt center formation, as seen in models of cleidocranial dysplasia.^[29]^[1] Supporting signaling pathways, including Wnt/β-catenin and bone morphogenetic protein (BMP), further modulate osteoblast activity and vascular invasion to refine center location and growth rates.^[30] Mechanical stresses, such as tensile forces from expanding neural tissues or early muscle contractions, influence center positioning and directional expansion, optimizing bone shape for load-bearing in the developing embryo.^[30] These integrated cues ensure the centers develop as focal, expandable sites that collectively outline the final architecture of intramembranous bones.^[31]

Transition to Lamellar Bone

The transition from woven bone to lamellar bone in intramembranous ossification occurs through a remodeling process where osteoclasts resorb the disorganized woven bone matrix, creating spaces that osteoblasts subsequently fill by depositing organized layers of collagen in lamellar sheets.^[32] This remodeling is essential for maturing the initial bone framework formed during embryonic and early postnatal development.^[1] Lamellar bone features parallel orientation of collagen fibers arranged in concentric lamellae, which contrasts with the random fiber arrangement in woven bone and results in enhanced mechanical strength and lower cellularity due to smaller, more flattened osteocytes embedded in the matrix.^[32] These structural adaptations allow lamellar bone to better withstand physiological stresses while maintaining efficient mineral deposition.^[32] This transition primarily takes place in the postnatal period, with the replacement of woven bone by lamellar bone beginning around birth in the calvaria and gradually during the postnatal period as the skull matures.^[33] The process is influenced by mechanical loading, which stimulates osteoblast activity and promotes the organized deposition of lamellar layers in response to functional demands on the bone.

Structural Development

Formation of Bone Spicules

In intramembranous ossification, bone spicules emerge as the initial structural elements following the establishment of primary ossification centers, where clusters of mesenchymal cells differentiate into osteoblasts. These spicules develop as thin, needle-like projections of woven bone that radiate outward from the ossification centers, driven by the secretory activity of osteoblasts lining the periphery of the developing matrix. Osteoblasts deposit layers of osteoid—an unmineralized organic matrix primarily composed of type I collagen and proteoglycans—along these projections, which then undergo calcification as hydroxyapatite crystals bind to the matrix, forming the spiky extensions characteristic of early bone formation.^[2]^[34] The branching pattern of bone spicules arises through coordinated osteoblast proliferation and matrix secretion, where active osteoblasts at the tips of the projections continue to extend and ramify the structure, creating an interconnected network that serves as a scaffold for subsequent bone development. This process ensures the spicules act as templates for additional matrix deposition, allowing for the progressive buildup of bone tissue without a cartilaginous intermediate. As osteoblasts become entrapped within the hardening matrix, they differentiate into osteocytes, which remain embedded and maintain the vitality of the forming bone through a network of canaliculi.^[2]^[34] Microscopically, bone spicules consist of irregularly mineralized woven bone, with the osteoid matrix exhibiting a disorganized collagen fiber arrangement that contrasts with the more ordered structure of mature lamellar bone. The embedded osteocytes, housed in lacunae, facilitate nutrient exchange and signaling within the spicule, while the irregular mineralization pattern—marked by variable deposition of calcium phosphates—provides initial mechanical strength to these primitive projections. This woven architecture underscores the spicules' role in rapidly establishing a foundational framework for flat bones, such as those in the cranium.^[2]^[34]

Creation of Trabecular Bone

In intramembranous ossification, the initial bone spicules serve as precursors that interconnect through a process of anastomosis, where their ends branch and fuse to form an interconnected network.^[1] This interconnection is facilitated by clusters of osteoblasts that continue to deposit layers of osteoid, an unmineralized organic matrix primarily composed of type I collagen, around the vascular cores of the spicules.^[32] Successive deposition of osteoid followed by mineralization, where calcium phosphate crystals (hydroxyapatite) bind to the matrix, causes the spicules to thicken and mature into trabeculae.^[3] As osteoblasts become embedded within the hardening matrix, they differentiate into osteocytes, which maintain the structure and facilitate further nutrient exchange.^[1] The resulting trabeculae organize into a three-dimensional lattice characteristic of trabecular (cancellous or spongy) bone, which provides lightweight mechanical support while maximizing strength-to-weight ratio.^[32] This porous architecture houses vascular sinuses and spaces that eventually fill with bone marrow, enabling hematopoiesis and fat storage.^[3] The interconnected trabecular network distributes loads efficiently across the bone, resisting compressive forces without the density of compact bone.^[1] Developmentally, trabecular bone in intramembranous ossification progresses from embryonic woven trabeculae, which are irregularly oriented and rapidly formed, to more organized postnatal lamellar trabeculae through ongoing remodeling.^[32] This transition involves the replacement of woven matrix with layered lamellar bone, enhancing durability and alignment.^[3] The architecture is further refined under the influence of Wolff's law, whereby trabeculae adapt their orientation and density in response to mechanical stresses, thickening along lines of force to optimize load-bearing capacity.^[35]

Assembly of Osteons

The assembly of osteons, also known as Haversian systems, represents a key phase in the maturation of compact bone during intramembranous ossification, where cylindrical units organize the dense cortical layer of flat bones.^[32] These structures form through a remodeling process that replaces initial woven bone with more organized lamellar bone, enhancing mechanical strength.^[36] In this process, osteoclasts initiate formation by excavating vascular tunnels within the existing bone matrix, creating a cutting cone that advances through the tissue at a rate of approximately 20–40 μm per day.^[32]^[36] Following resorption, osteoblasts are recruited to the trailing edge of the cutting cone, where they deposit successive layers of mineralized matrix to refill the tunnel, forming 4–20 concentric lamellae around a central Haversian canal that houses blood vessels, nerves, and lymphatics.^[32]^[36] Each osteon typically measures 150–250 μm in diameter and spans several millimeters in length, with the lamellae oriented parallel to the canal walls.^[32] As osteoblasts become embedded in the matrix, they differentiate into osteocytes housed within lacunae, small cavities spaced throughout the lamellae.^[36] Osteocytes within lacunae extend processes through canaliculi, a network of thin channels (about 0.25–0.5 μm in diameter) that interconnect adjacent cells and facilitate nutrient diffusion and mechanosensory signaling.^[32]^[36] These processes are linked by gap junctions, allowing direct intercellular communication via ion and small molecule exchange, which coordinates osteocyte responses to mechanical loads.^[36] In the final integration, osteons align parallel to predominant stress lines in the bone, optimizing load distribution and replacing disorganized woven bone in regions akin to the diaphysis of flat bones, such as the calvaria.^[32]^[36] This orientation is influenced by Wolff's law, where remodeling adapts to functional demands, ensuring the compact bone's durability.^[32] The complete assembly of an individual osteon takes about 3–4 months, contributing to the overall transition to mature lamellar bone.^[36]

Anatomical Examples and Applications

Sites in the Human Skeleton

Intramembranous ossification primarily occurs in the flat bones of the cranium, including the parietal, frontal, and occipital bones, which form the calvaria or skull vault.^[37] These bones develop directly from mesenchymal condensations without a cartilaginous intermediate, allowing rapid expansion to accommodate the growing brain during fetal and postnatal development.^[38] Similarly, the flat bones of the face, such as the maxilla, zygomatic, nasal, and lacrimal bones, as well as the mandible, arise through this process, contributing to the structural framework of the viscerocranium.^[39] The clavicle, or collarbone, is another key site, forming mostly via intramembranous ossification to provide early support for the upper limb.^[4] The clavicle represents a unique case among these sites, as it undergoes a hybrid ossification pattern: the central diaphysis develops intramembranously from paraxial mesoderm-derived mesenchyme, while the medial (sternal) end involves endochondral ossification from a secondary cartilaginous model and the lateral (acromial) end develops intramembranously.^[40] This dual mechanism distinguishes it from typical long bones and enables its early ossification, beginning around the fifth to sixth week of embryonic development, making it the first bone to ossify in the human fetus.^[41] Cranial sutures, the fibrous joints between calvarial bones such as the coronal, sagittal, and lambdoid sutures, serve as persistent growth zones where intramembranous ossification continues postnatally, facilitating skull expansion until early adulthood. Embryologically, these sites derive from distinct mesenchymal populations: the cranial vault bones, including the frontal and parietal, primarily originate from cranial neural crest cells, while portions of the occipital bone and the clavicle arise from paraxial mesoderm.^[42] Facial bones, such as the maxilla and mandible, are predominantly neural crest-derived, reflecting their role in craniofacial patterning influenced by migratory neural crest populations during gastrulation.^[43] This dual embryonic origin underlies regional differences in bone growth dynamics and regenerative potential within the intramembranous process.^[30]

Clinical Relevance and Disorders

Intramembranous ossification is implicated in several clinical disorders, particularly those affecting craniofacial development. Craniosynostosis involves the premature fusion of cranial sutures, where abnormal acceleration of intramembranous ossification leads to restricted skull growth and potential neurological complications.^[44] This condition arises from genetic mutations disrupting the balance between osteoblast differentiation and suture patency, often requiring surgical intervention to allow brain expansion.^[45] Cleidocranial dysplasia (CCD), caused by heterozygous mutations in the RUNX2 gene, results in defective intramembranous ossification primarily affecting the clavicles and cranial vault, leading to hypoplastic or absent clavicles, delayed fontanelle closure, and supernumerary teeth.^[46] RUNX2 is a critical transcription factor for osteoblast maturation, and its haploinsufficiency impairs the direct mesenchymal-to-bone conversion essential for these flat bones.^[47] Patients often exhibit short stature and skeletal anomalies treatable through orthopedic and dental management. Fibrous dysplasia (FD), particularly in its craniofacial form, stems from activating mutations in the GNAS gene, causing dysregulated Gαs signaling that disrupts normal intramembranous ossification and leads to persistent woven bone within fibrous stroma.^[44] This results in expansile lesions that deform the skull and facial bones, increasing fracture risk and requiring bisphosphonate therapy or surgical contouring to alleviate symptoms.^[48] In clinical applications, principles of intramembranous ossification guide bone grafting techniques in reconstructive surgery, where mesenchymal stem cells (MSCs) are induced to form new bone directly without a cartilaginous intermediate, as seen in craniofacial defect repairs using autografts or tissue-engineered scaffolds.^[49] This approach is particularly effective for non-load-bearing sites like the mandible or calvaria, promoting rapid integration and vascularization.^[50] Fracture healing in flat bones, such as those of the skull, predominantly occurs via intramembranous ossification, involving direct osteoblast-mediated callus formation and Haversian remodeling without endochondral intermediates.^[51] This process supports efficient repair in membranous bones but can be compromised in disorders like FD, necessitating targeted interventions to enhance osteogenesis. Recent advancements as of 2025 include stem cell therapies leveraging cranio-maxillofacial skeletal stem cells (CMSSCs) to promote MSC differentiation toward intramembranous ossification for correcting craniofacial defects, demonstrating improved bone regeneration in preclinical models.^[52] Studies on bone morphogenetic protein (BMP) enhancers, such as BMP-2 combined with vascular endothelial growth factor in mineralized collagen scaffolds, have shown enhanced osteogenesis and angiogenesis in these therapies, offering promise for treating congenital anomalies like craniosynostosis.^[53]

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Although the skull bones are classically described as forming by intramembranous ossification, transient cartilage intermediates are well known to occur.
[46]
Genetic Analysis of Runx2 Function During Intramembranous ...
Jan 15, 2016 · Runx2 is an essential transcriptional regulator of osteoblast differentiation and its haploinsufficiency leads to cleidocranial dysplasia.
[47]
A Runx2 threshold for the cleidocranial dysplasia phenotype - PMC
Because all CCD patients exhibit craniofacial defects, it has been proposed that intramembranous bone formation may require a high level of functional RUNX2.
[48]
Fibrous dysplasia/McCune-Albright syndrome: state-of-the-art ...
Aug 8, 2025 · FD lesions are characterized by the growth of a fibro-osseous tissue that replaces the normal bone/bone marrow organ. This causes deformity, ...
[49]
Onlay Bone Grafts in Head and Neck Reconstruction - PMC
Bone is embryologically derived from mesenchymal tissue through endochondral or intramembranous ossification. Endochondral bone goes through a cartilaginous ...
[50]
A Developmental Engineering-Based Approach to Bone Repair
Mar 30, 2020 · Intramembranous bone growth is achieved through bone formation within a periosteum or by bone formation at suture lines (Opperman, 2000).
[51]
Fracture Healing Overview - StatPearls - NCBI Bookshelf
Apr 8, 2023 · Fracture healing is complex, and it involves the following stages: hematoma formation, granulation tissue formation, callus formation, and bone remodeling.
[52]
Identification of human cranio-maxillofacial skeletal stem cells for ...
Jan 1, 2025 · Thus, this study identifies CMSSCs that orchestrate the intramembranous ossification of cranio-maxillofacial bones, providing a deeper ...
[53]
Enhancement of BMP-2 and VEGF carried by mineralized collagen ...
Jun 13, 2020 · Craniofacial bones require intramembranous ossification to generate tissue-engineered bone grafts via angiogenesis and osteogenesis. Here ...