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Septum transversum

The septum transversum is an embryonic structure that forms during the early stages of human development, serving as the barrier between the thoracic and abdominal cavities and contributing significantly to the formation of the diaphragm's central as well as mesenchymal components of the liver. Originating from the rostral-most in the lateral plate during the fourth week of , the septum transversum initially appears as a thick mass of positioned caudal to the developing heart and cranial to the , just ventral to the . As cranio-caudal folding of the progresses around weeks 4-5, it migrates from its initial cervical location at the level of somites C3-C5 caudally to the lower thoracic region, eventually positioning its ventral edge at T7 and dorsal edge at T12 by week 8. In diaphragm development, the septum transversum acts as a foundational scaffold, integrating with pleuroperitoneal folds, dorsal mesentery, and myogenic progenitors from cervical somites to separate the pericardial and peritoneal cavities and close the pericardioperitoneal canals, a process largely complete by week 7-8. This migration is accompanied by the elongation of the from C3-C5 origins, ensuring innervation of the resulting diaphragmatic muscle. Disruptions in its formation or fusion can lead to congenital , highlighting its essential role in partitioning body cavities. Beyond the diaphragm, the septum transversum mesenchyme plays a key inductive role in hepatogenesis by signaling to adjacent foregut endoderm to initiate liver bud formation around week 4. Its mesothelial and submesothelial cells, marked by expression of genes like Wt1 and desmin, give rise to hepatic stellate cells (approximately 15-24% by embryonic days equivalent to weeks 6-7 in humans) and perivascular mesenchymal cells such as portal fibroblasts and smooth muscle cells in the developing liver, contributing to sinusoidal architecture and vascular support without differentiating into endothelial or hematopoietic lineages.

Embryonic Origins and Development

Formation

The septum transversum emerges during the third week of as a critical mesodermal structure. It arises specifically on day 22 as a thick mass of cranial positioned between the developing heart and the , marking the initial differentiation of ventral midline at the cranial edge of the trilaminar disc. This formation occurs through the specification of into its splanchnic layer, which envelops the emerging and contributes to the partitioning of the coelomic cavity. At Carnegie stage 10, corresponding to approximately 22-23 days post-fertilization, the septum transversum solidifies as a distinct entity derived solely from splanchnic , located ventral to the . This positioning places it immediately caudal to the pericardial region and dorsal to the prospective hepatic area, facilitating its role in early without any direct input from endodermal or ectodermal layers. The structure's mesodermal origin ensures its framework, which will later support vascular and epithelial integrations. The and patterning of the septum transversum rely on mesodermal signaling pathways that establish its ventral identity. Key molecules include bone morphogenetic proteins (, BMP-4, and BMP-7), secreted from the septum transversum itself and adjacent cardiac , which promote the of this mesodermal mass and its interactions with neighboring tissues. These BMP signals act combinatorially to specify the septum's role as the primordial ventral , providing a scaffold for subsequent derivatives while excluding alternative fates such as pancreatic specification in adjacent .

Migration and Positioning

The septum transversum initially forms as a mesodermal mass in the cranial region of the embryo, positioned rostral to the developing heart and at the level of the third, fourth, and fifth cervical somites during the third week of gestation. As embryonic development progresses, it undergoes a caudal migration primarily driven by the craniocaudal folding of the body, which begins around week 4 and continues through week 8. This folding process, initiated by rapid growth of the central nervous system and ventral bending of the embryo's edges, repositions the septum transversum from its original cervical location into the thoracic region, creating an apparent descent relative to the vertebral column. The migration is facilitated by mechanical forces arising from differential growth rates along the embryo's body axis, including the elongation of the neck and the descent of the heart, which pull the septum transversum inferiorly. During this period, the growing liver primordium invades the septum transversum, expanding its size and contributing to its ventral anchoring, while the expanding lung buds interact with its dorsal aspects, further influencing its positional adjustment. These interactions ensure the septum transversum aligns properly as a partitioning structure between emerging body cavities, without active cellular migration but through passive relocation via overall body morphogenesis. By the end of week 8, the septum transversum has reached the thoracoabdominal junction, lying caudal to the developing heart and at approximately the level of the lower thoracic vertebrae, setting the stage for its integration into the diaphragm. This positioning is critical for separating the pericardial and peritoneal cavities, achieved through the completion of embryonic folding and the fusion with adjacent structures like the pleuroperitoneal folds. Disruptions in this process, such as altered growth differentials, can lead to incomplete descent and associated congenital anomalies.

Anatomical Features

Composition

The septum transversum is primarily composed of mesenchymal cells originating from the mesoderm of the during early embryonic development. These mesenchymal cells form a thick, supportive sheet that serves as a foundational structure in the cranial region of the . Within this , key cellular components include fibroblasts and undifferentiated mesenchymal cells, which contribute to the overall framework. The structure also harbors myogenic precursor cells, identifiable by markers such as desmin, that represent early progenitors destined to differentiate into muscle fibers in subsequent developmental stages; however, no mature muscle tissue is present at this embryonic phase. Vascular elements, derived from the adjacent splanchnic vascular , integrate into the mesenchyme to form primitive networks, while the septum transversum notably lacks any epithelial layers. Biochemically, the septum transversum exhibits a high expression of proteins, including , which is deposited between mesenchymal layers to provide essential structural support and facilitate interactions with neighboring tissues. This ECM-rich composition underscores its role as a scaffold for further .

Location and Relations

The septum transversum forms as a thick mass of cranial mesenchyme on approximately day 22 of embryonic development, initially positioned caudal to the developing heart and ventral to the foregut endoderm, into which the hepatic diverticulum (liver primordium) evaginates. It lies between the pericardial cavity cranially and the yolk sac (via the vitelline duct) caudally, serving as an early barrier between the thoracic and abdominal regions. Ventrally, it is bordered by the extraembryonic coelom, while its ventral orientation places it adjacent to the foregut endoderm, into which the hepatic diverticulum begins to protrude around the fourth week. After the fourth week, the septum transversum maintains its superior relation to the developing heart within the and develops an inferior border with the expanding , which grows into the surrounding to form initial . This positioning facilitates interactions with adjacent endodermal derivatives, reinforcing its role in early separation. Laterally, the septum transversum relates to the paraxial of the somites, particularly the somites, which contribute myoblasts that migrate into the structure to form diaphragmatic musculature.

Innervation

Nerve Supply

The septum transversum receives its primary innervation from the ventral rami of the spinal nerves , , and during early embryogenesis. These nerves originate from somites at the level, specifically somites , which contribute myogenic precursors to the structure. These neural fibers serve as the early precursor to the phrenic nerve, extending through the surrounding mesenchyme to reach the septum transversum around weeks 5–6 of development. The phrenic nerve precursors descend alongside the septum transversum as it migrates caudally, maintaining this somatic connection. Among these fibers, sensory components from the phrenic precursors provide visceral afferents to the septum transversum's central regions, while motor fibers innervate the myogenic cells, enabling contractile function. This innervation is exclusively somatic at this embryonic stage, with no contributions from sympathetic or parasympathetic systems.

Functional Role in Innervation

The precursors of the , originating from the cervical spinal cord segments C3-C5, establish motor innervation to the septum transversum early in embryonic development, ensuring subsequent diaphragmatic contraction essential for after the structure's derivation into the . Detailed timelines below are primarily from models (embryonic days, E), corresponding approximately to gestational weeks 6-8. These neural precursors extend axons to the pleuroperitoneal folds by embryonic day 10.5 in mice, forming neuromuscular junctions that enable coordinated muscle activation in the costal and crural regions of the developing . This motor control is critical for the diaphragm's role in thoracic expansion during . Sensory innervation from the afferents provides feedback mechanisms in the septum transversum-derived structures, detecting stretch in the developing and signals from the adjacent . This sensory role supports reflexive adjustments in patterns and protective responses to diaphragmatic strain. During the caudal migration of the septum transversum, axons are guided by molecular cues such as (NCAM), preserving the C3-C5 segmental supply despite the structure's descent from cervical to thoracoabdominal levels. Pioneer axons reach the pleuroperitoneal folds by embryonic day 10.5 in mice, branching via receptor protein tyrosine phosphatases to target specific muscle progenitors while avoiding ectopic paths. This guidance ensures precise innervation patterning, maintaining functional connectivity as the positions at the thoracic-lumbar boundary. β-Catenin within the developing muscle regulates secondary branching and arborization of the , coordinating with somite-derived progenitors to form functional myofibers. These interactions are essential for the structural integrity and contractile capability of the derived .

Derivatives

Diaphragmatic Derivatives

The cranial portion of the septum transversum primarily contributes to the formation of the central of the , a fibrous that serves as the primary attachment site for the radiating muscle fibers of the . This develops as the septum transversum migrates caudally during weeks 4 to 6 of embryonic development, establishing an initial partition between the developing thoracic and abdominal cavities. By providing this central fibrous structure, the septum transversum enables the structural integrity and functional doming of the essential for . The septum transversum also plays a key role in the muscularization of the by receiving myoblasts that migrate from the somites (levels to ) during weeks 5 to 6. These myoblasts integrate into the of the septum transversum, proliferate, and fuse to form the fibers of the , completing this process by approximately week 8 of . This migration and differentiation are guided by the , ensuring proper innervation and contractile function of the resulting muscular sheet. Furthermore, the septum transversum integrates with the pleuroperitoneal membranes during weeks 6 to 8 to close the pericardioperitoneal canals, thereby preventing herniation of abdominal contents into the . The pleuroperitoneal membranes extend from the lateral body walls to fuse dorsally with the septum transversum and the dorsal esophageal mesentery, forming a complete diaphragmatic barrier that separates the pleural and peritoneal spaces. This closure is critical for the proper compartmentalization of the coelomic cavity and the establishment of isolated thoracic and abdominal regions. Notably, the septum transversum does not contribute to the peripheral tendinous parts of the , such as the costal and crural attachments, which instead derive from the of the body wall and thoracic-lumbar somites. These peripheral components develop through lateral ingrowths from the body wall, attaching to the , , and independently of the central septum transversum-derived tendon.

Mesenteric and Hepatic Derivatives

The caudal portion of the septum transversum contributes to the formation of the ventral mesentery, a mesenchymal structure that suspends the primitive and supports early in the . This ventral mesentery differentiates into key peritoneal derivatives, including the , which connects the lesser curvature of the to the liver, and the , which anchors the liver to the anterior . These structures arise as the septum transversum's integrates with expanding foregut derivatives, providing structural support and vascular continuity during embryonic growth. During liver development, the septum transversum integrates with the hepatic , an outpouching of the that invades the mesenchymal septum around the fourth week of gestation. This integration envelops the nascent liver , forming the visceral that covers the liver's anterior and superior surfaces. The resulting peritoneal layer, derived from the septum's splanchnic mesoderm, facilitates the liver's expansion into the while maintaining its attachment to surrounding structures. The septum transversum mesenchyme plays a critical inductive role in hepatic specification by secreting bone morphogenetic proteins (BMPs), which, in concert with fibroblast growth factors (FGFs) from adjacent cardiac , promote the differentiation of hepatic into the liver . Specifically, BMP signaling from the septum transversum activates liver-specific in the foregut , suppressing alternative pancreatic fates and ensuring hepatoblast formation by the 14-somite stage. This permissive environment, established through mesenchymal-endodermal interactions, positions the hepatic for subsequent proliferation and vascularization. Mesenchymal cells from the septum transversum undergo condensation to establish the fibrous layer of Glisson's capsule, the connective tissue sheath that encases the liver and extends into its portal triads. This condensation process, occurring as hepatoblasts invade the septum, forms a supportive framework that delineates the liver's external boundary and internal lobular architecture. The resulting capsule, thicker at the porta hepatis, integrates with the visceral peritoneum to provide mechanical protection and facilitate intrahepatic septation.

Clinical Relevance

Congenital Anomalies

Congenital anomalies of the septum transversum primarily manifest as structural defects in the due to disruptions in its embryonic formation, where the septum transversum serves as a foundational component fused with pleuroperitoneal membranes and migrating myoblasts. These defects can lead to impaired separation of thoracic and abdominal cavities, resulting in hernias or weakened diaphragmatic tissue. Eventration of the arises from incomplete migration of myoblasts from somites to the septum transversum during weeks 4-7 of , causing the diaphragmatic muscle to be abnormally thin, elevated, or replaced by fibroelastic tissue. This congenital form often affects the left hemidiaphragm and may be total or partial, leading to paradoxical motion during respiration without an actual tear in the membrane. Morgagni hernia, a rare anterior diaphragmatic defect comprising 2-3% of congenital diaphragmatic hernias, results from failure of the pleuroperitoneal membranes to fuse properly with the septum transversum and costal margins around the 6th-8th week of development. This creates a of Morgagni through which abdominal contents, such as omentum or colon, may protrude into the , typically on the right side. Congenital diaphragmatic hernias linked to septum transversum anomalies, including Bochdalek and Morgagni types, occur in approximately 1 in 2,500 to 4,000 live births worldwide, with higher rates in certain populations due to genetic or environmental factors. Many of these anomalies are at birth and discovered incidentally, but prenatal or postnatal can detect them by revealing abnormal continuity between thoracic and abdominal compartments, such as bowel loops or liver herniation displacing lung tissue.

Developmental Disorders

Septum transversum maldevelopment is associated with syndromic disorders such as (CdLS), a genetic condition caused by mutations in genes like NIPBL that disrupt cohesin-mediated signaling in mesodermal tissues, affecting formation and leading to congenital (CDH) in 5-20% of cases. In CdLS, these mesodermal defects impair the signaling pathways necessary for proper septum transversum , contributing to high mortality rates from CDH-related , with only 33% of affected patients undergoing repair and overall survival around 24%. The syndrome's impact on mesodermal development highlights how genetic disruptions in early embryogenesis can cascade into functional diaphragmatic insufficiency. Failed hepatic induction by the septum transversum , mediated through and FGF signaling pathways, can result in impaired liver , such as delayed hepatogenesis or reduced liver size. from the septum transversum is essential for inducing liver-specific genes like while suppressing pancreatic fate. Additionally, asymmetric expression of Pitx2c in the left septum transversum supports left-right axis determination, and its dysregulation is associated with heterotaxy syndromes involving liver malposition. Therapeutic interventions for disorders arising from septum transversum maldevelopment, particularly CDH, primarily involve surgical repair after initial stabilization with (ECMO) in severe cases, with modern high-volume centers reporting survival rates exceeding 80% as of 2023. As of 2025, multi-center data report inpatient survival rates around 76-80% for CDH, with variations by severity and center. Outcomes have improved due to advances in prenatal , delayed repair strategies, and multidisciplinary care, achieving 83% survival in cohorts from 2019-2023 despite increasing disease severity. For phrenic nerve-related issues in neonates, plication of the paralyzed may be required, enhancing respiratory function in up to 70% of cases.

References

  1. [1]
    Development of the diaphragm, a skeletal muscle essential for ...
    The septum transversum is the first structure present in the developing diaphragm and serves as the initial barrier between the thoracic and abdominal cavities ...
  2. [2]
    Body Cavities
    It arises from tissue from four sources: The septum transversum, which forms the central tendon of the diaphragm. The diaphragm develops initially at the level ...
  3. [3]
    Lung and Diaphragm - Duke University Medical School - Embryology
    with cranio-caudal folding, a block of connective called the septum transversum forms in between the heart and future liver; the septum transversum grows in ...
  4. [4]
    Septum Transversum-Derived Mesothelium Gives Rise to Hepatic ...
    The septum transversum mesenchyme (STM) signals to induce hepatogenesis from the foregut endoderm. Hepatic stellate cells (HSCs) are sinusoidal pericytes ...
  5. [5]
    Anatomy, Thorax, Pericardium - StatPearls - NCBI Bookshelf - NIH
    The septum transversum is a thick mass of cranial mesenchyme that is formed on day 22. During craniocaudal folding, it assumes a position caudal to the ...Missing: formation | Show results with:formation<|separator|>
  6. [6]
    Gastrointestinal Tract - Liver Development - UNSW Embryology
    Week 4. Carnegie stage 11. hepatic diverticulum development (ductal plate) ; Carnegie stage 12. cell differentiation. septum transversum forming liver stroma.
  7. [7]
    Atlas of Human Embryos Chapter 4
    The septum transversum lies ventral to the cranial intestinal portal where the hepatic diverticulum forms. Mesoderm is located on each side of the midline and ...
  8. [8]
    Septum Transversum - an overview | ScienceDirect Topics
    The septum transversum, or tendon center, is the source of the central tendon of the diaphragm and grows dorsally to the ventrolateral wall of the body, forming ...Missing: splanchnic | Show results with:splanchnic
  9. [9]
    Distinct mesodermal signals, including BMPs from the septum ... - NIH
    We find that BMP signaling from the septum transversum mesenchyme is necessary to induce liver genes in the endoderm and to exclude a pancreatic fate.
  10. [10]
    The body cavities and the diaphragm - Clinical Gate
    Jun 13, 2015 · The septum transversum, composed of mesoderm, gives rise to the central tendon of the diaphragm. The body wall. As the pleural cavities enlarge ...
  11. [11]
    [PDF] Embryonic Cephalocaudal and Lateral Flexion/Folding
    The septum transversum forms cranial to the cardiogenic area in the germ disc, A, and is translocated to the future lower thoracic region through the folding of ...
  12. [12]
    Longitudinal Section - College of Medicine - University of Cincinnati
    Cranial folding also moves the heart and the septum transversum from the cranial end of the embryo into the area of the future thorax. This cranial folding also ...
  13. [13]
    Embryology and Anatomy of the Diaphragm - Thoracic Key
    Jun 25, 2016 · 51-1). The septum transversum, formed during the third week of gestation, separates the pericardial region from the rest of the body cavity.
  14. [14]
    Embryology of the Abdominal Wall and Associated Malformations ...
    Septum Transversum​​ The transverse septum originates behind the base of the pericardial cavity and the roof of the vitelline duct, bordered ventrally by the ...
  15. [15]
    https://doi.org/10.1002/hep.24119
  16. [16]
    https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9300894/
  17. [17]
    Developmental origin and morphogenesis of the diaphragm, an ...
    The PPFs expand dorsally and ventrally across the septum transversum, a thin membrane on the cranial surface of the liver, and give rise to the diaphragm's ...<|control11|><|separator|>
  18. [18]
    https://www.ncbi.nlm.nih.gov/books/NBK513325/
  19. [19]
    Anatomy, Thorax, Phrenic Nerves - StatPearls - NCBI Bookshelf
    Jul 24, 2023 · The phrenic nerve descends along with the septum transversum, carrying innervation from the ventral rami from C3 through C5. Go to: Blood ...Missing: precursor | Show results with:precursor
  20. [20]
    FEBS Press
    ### Summary of Innervation Role from Septum Transversum in Diaphragm Function
  21. [21]
    https://www.sciencedirect.com/science/article/pii/S0363018820301092
  22. [22]
    https://www.sciencedirect.com/science/article/pii/B9781455727940000152
  23. [23]
    https://www.sciencedirect.com/science/article/pii/B9780323930222000095
  24. [24]
    https://www.kenhub.com/en/library/anatomy/development-of-digestive-system
  25. [25]
    Development and embryology of the digestive system | Kenhub
    The ventral mesentery is derived from the septum transversum (a mass of splanchnic mesoderm ... foregut and the septum transversum. Bare area of the liver ...
  26. [26]
    Gut Development - Duke Embryology
    the ventral mesentery of the liver becomes the falciform ligament; the mesentery between the stomach and liver becomes the lesser omentum. the rest of the GI ...
  27. [27]
    Anatomy, Abdomen and Pelvis: Falciform Ligament - StatPearls - NCBI
    Jun 15, 2025 · Embryology · The falciform ligament derives from the ventral mesentery attached to the ventral border of the foregut. · The intraembryonic ...
  28. [28]
    Atlas of Human Embryos Chapter 6
    As the liver expands into the ventral mesentery, it is covered by a thin layer called the serosa. That part of the liver adjacent to the septum transversum has ...
  29. [29]
    Liver and Biliary System - PMC - PubMed Central
    Primitive epithelial cells of the hepatic diverticulum extend into the adjacent mesenchymal stroma of the septum transversum, a sheet of cells that incompletely ...
  30. [30]
    Mechanisms controlling early development of the liver - ScienceDirect
    Initial stages of hepatogenesis require FGFs secreted from the pre-cardiac mesoderm and BMPs from the septum transversum mesenchyme (yellow) By 14 somites a ...
  31. [31]
    Liver development - StemBook - NCBI Bookshelf - NIH
    Oct 31, 2008 · At e9.5, the hepatic endoderm cells, known as hepatoblasts delaminate from the epithelium and invade the adjacent septum transversum mesenchyme ...
  32. [32]
    Book - Developmental Anatomy 1924-7 - UNSW Embryology
    Oct 24, 2016 · The septum transversum of 2 mm. embryos occupies a transverse position in the middle cervical region (Fig. 119, 2). It then migrates caudally, ...
  33. [33]
    Structure, Function, and Responses to Injury | Abdominal Key
    Sep 29, 2019 · Condensation of the Glisson capsule occurs at the porta hepatis, and the fibrous tissue then extends into the liver, supporting and ...
  34. [34]
    Liver - SpringerLink
    May 15, 2024 · The liver is enclosed in a thin connective tissue membrane (Glisson's capsule). It is thicker at the hilum (porta hepatis), where the portal ...
  35. [35]
    Congenital Diaphragmatic Hernia - StatPearls - NCBI Bookshelf - NIH
    With the advances in prenatal imaging, about two-thirds of the cases of congenital diaphragmatic hernia are detected in the antenatal period. The presentation ...
  36. [36]
    Congenital diaphragmatic hernias - AMBOSS
    Sep 28, 2022 · Congenital diaphragmatic hernias (CDH) are a common developmental defect, resulting from an incomplete fusion of embryonic components of the diaphragm.
  37. [37]
    Diaphragm Eventration - StatPearls - NCBI Bookshelf
    Aug 11, 2024 · The etiology is congenital or acquired. Congenital: Due to abnormal migration of myoblasts during development. Acquired: Due to phrenic nerve ...
  38. [38]
    Diaphragm Eventration - an overview | ScienceDirect Topics
    Congenital eventration results from the incomplete development of the central tendon or muscular portion of the diaphragm. Most commonly left sided, bilateral ...
  39. [39]
    Morgagni Hernia - StatPearls - NCBI Bookshelf
    Aug 12, 2024 · A Morgagni hernia arises from a defect at the junction where the diaphragm's septum transversum and costal elements meet, allowing abdominal ...Missing: membrane | Show results with:membrane
  40. [40]
    Diaphragmatic Hernias - Medscape Reference
    Nov 22, 2024 · Morgagni hernias, on the other hand, are believed to be caused by a defect in the union of the transverse septum and lateral body wall. Most ...
  41. [41]
    Innovative use of mesh bolster for adult Morgagni hernia repair
    Jul 3, 2019 · Morgagni hernia is a rare type of congenital diaphragmatic hernia caused by lack of fusion of the pleuroperitoneal membrane anteriorly leading ...
  42. [42]
    Congenital Diaphragmatic Hernia Statistics - CDH International
    The incidence of CDH is approximately 1 in 2500 births, meaning over 1600 babies are born with CDH every year in the United States alone. With a 50% survival ...
  43. [43]
    Prevalence and Mortality among Children with Congenital ...
    Worldwide, CDH occurs in approximately 1 in every 3,000 live births. Respiratory failure, due to pulmonary hypertension and pulmonary hypoplasia, is the leading ...
  44. [44]
    Congenital diaphragmatic hernia | Radiology Reference Article
    Nov 2, 2024 · Most congenital diaphragmatic hernias are detected either soon after birth or on antenatal ultrasound. Mortality is predominantly due to the ...
  45. [45]
    Congenital Diaphragmatic Hernia (CDH)
    CDH is typically discovered during a routine prenatal ultrasound. The sonographer may notice stomach, intestine, or liver in your baby's chest where the lungs ...What is congenital... · Testing and diagnosis · Surgery · Congenital diaphragmatic...
  46. [46]
    Congenital Diaphragmatic Hernia (CDH) - Johns Hopkins Medicine
    CDH is most frequently diagnosed during the 20-week prenatal ultrasound. If there is a small hernia, the diagnosis may be made at birth by X-ray when the baby ...
  47. [47]
    Development of the diaphragm – a skeletal muscle essential for ...
    The muscle and its associated connective tis- sue and central tendon develop from three sources: the septum transversum, the pleuroperitoneal folds and the ...
  48. [48]
    Cornelia de Lange syndrome and congenital diaphragmatic hernia
    There is a known association between Cornelia de Lange syndrome (CdLS) and congenital diaphragmatic hernia (CDH), with CDH being the cause of death in 5%-20% ...
  49. [49]
    https://pubmed.ncbi.nlm.nih.gov/11485993/
  50. [50]
    Molecular genetics of congenital diaphragmatic defects - PMC
    A functional defect in mesenchymal progenitors in the septum transversum could impair development of the diaphragm, heart, and/or liver. This may, in part, ...
  51. [51]
    Distinct mesodermal signals, including BMPs from the septum ...
    Aug 1, 2001 · We find that BMP signaling from the septum transversum mesenchyme is necessary to induce liver genes in the endoderm and to exclude a pancreatic fate.
  52. [52]
    The twists and turns of left-right asymmetric gut morphogenesis - PMC
    Pitx2c is also expressed in the left side of the septum transversum ... Reversal of left-right asymmetry: a situs inversus mutation. Science 260 ...
  53. [53]
    Golden hour management of infants with congenital diaphragmatic ...
    Feb 21, 2025 · Despite increased severity, survival improved significantly over time, from 71% (2008–2013) to 82% (2014–2018) and 83% (2019–2023), p = 0.02 for ...
  54. [54]
    Diaphragm Disorders - StatPearls - NCBI Bookshelf - NIH
    Jul 18, 2024 · Disorders of the diaphragm, such as diaphragmatic paralysis, result from either muscle weakness or nerve damage.