Ribs
Rib Fractures
Cervical Rib
Cervical Rib Syndrome
Intercostal Muscles
Thoracic Wall
Thoracic Outlet Syndrome
Twelfth rib resection as an approach for portal vein cannulation in sheep. (1/621)
A surgical technique involving resection of the twelfth rib was used to insert silastic cannulas into the portal veins of three sheep to study amino acid metabolism. Good exposure to the vein was achieved by this method although it required positive ventilation due to the penetration of the thoracic cavity. All cannulas were buried subcutaneously and exteriorized near the dorsal midline. This facilitated continuous infusion into the portal cannula without disturbing cannula placement. (+info)Pathogenetic sequence for aneurysm revealed in mice underexpressing fibrillin-1. (2/621)
Dissecting aortic aneurysm is the hallmark of Marfan syndrome (MFS) and the result of mutations in fibrillin-1, the major constituent of elastin-associated extracellular microfibrils. It is yet to be established whether dysfunction of fibrillin-1 perturbs the ability of the elastic vessel wall to sustain hemodynamic stress by disrupting microfibrillar assembly, by impairing the homeostasis of established elastic fibers, or by a combination of both mechanisms. The pathogenic sequence responsible for the mechanical collapse of the elastic lamellae in the aortic wall is also unknown. Targeted mutation of the mouse fibrillin-1 gene has recently suggested that deficiency of fibrillin-1 reduces tissue homeostasis rather than elastic fiber formation. Here we describe another gene-targeting mutation, mgR, which shows that underexpression of fibrillin-1 similarly leads to MFS-like manifestations. Histopathological analysis of mgR/mgR specimens implicates medial calcification, the inflammatory-fibroproliferative response, and inflammation-mediated elastolysis in the natural history of dissecting aneurysm. More generally, the phenotypic severity associated with various combinations of normal and mutant fibrillin-1 alleles suggests a threshold phenomenon for the functional collapse of the vessel wall that is based on the level and the integrity of microfibrils. (+info)Osteochondroma of the first rib presenting as a prominent clavicle. A report of 2 cases. (3/621)
We describe and discuss two patients with osteochondromas of the first rib which presented as prominence of the medial end of the clavicle. (+info)Prenatal sonographic features of spondylocostal dysostosis and diaphragmatic hernia in the first trimester. (4/621)
Spondylocostal dysostosis is a congenital disorder characterized by multiple malformations of the vertebrae and ribs. We describe the sonographic features of an affected fetus at 12 and 14 weeks of gestation. The fetus had thoracic scoliosis, multiple vertebral and rib malformations and a grossly dilated stomach that had herniated into the chest through a left-sided diaphragmatic hernia. The stomach spanned the whole length of the fetal trunk. (+info)Rib truncations and fusions in the Sp2H mouse reveal a role for Pax3 in specification of the ventro-lateral and posterior parts of the somite. (5/621)
The splotch (Pax3) mouse mutant serves as a model for developmental defects of several types, including defective migration of dermomyotomal cells to form the limb musculature. Here, we describe abnormalities of the ribs, neural arches, and acromion in Sp2H homozygous embryos, indicating a widespread dependence of lateral somite development on Pax3 function. Moreover, the intercostal and body wall muscles, derivatives of the ventrolateral myotome, are also abnormal in Sp2H homozygotes. Pax3 is expressed in the dermomyotome, but not in either the sclerotome or the myotome, raising the possibility that Pax3-dependent inductive influences from the dermomyotome are necessary for early specification of lateral sclerotome and myotome. Support for this idea comes from analysis of gene expression markers of lateral sclerotome (tenascin-C and scleraxis) and myotome (myogenin, MyoD, and Myf5). All exhibit ventrally truncated domains of expression in Sp2H homozygotes, potentially accounting for the rib and intercostal muscle truncations. In contrast, the medial sclerotomal marker Pax1 is expressed normally in mutant embryos, arguing that Pax3 is not required for development of the medial sclerotome. Most of the somitic markers show ectopic expression in anteroposterior and mediolateral dimensions, suggesting a loss of definition of somite boundaries in splotch and explaining the rib and muscle fusions. An exception is Myf5, which is not ectopically expressed in Sp2H homozygotes, consistent with the previous suggestion that Pax3 and Myf5 function in different pathways of skeletal myogenesis. PDGFalpha and its receptor are candidates for mediating signalling between myotome and sclerotome. We find that both genes are misexpressed in Sp2H embryos, suggesting that PDGFalpha/PDGFRalpha may function downstream of Pax3, accounting for the close similarities between the splotch and Patch mutant phenotypes. Our findings point to additional regulatory functions for the Pax3 transcription factor, apart from those already demonstrated for development of the neural tube, neural crest, and dermomyotome. (+info)Transgenic rescue of congenital heart disease and spina bifida in Splotch mice. (6/621)
Pax3-deficient Splotch mice display neural tube defects and an array of neural crest related abnormalities including defects in the cardiac outflow tract, dorsal root ganglia and pigmentation. Pax3 is expressed in neural crest cells that emerge from the dorsal neural tube. Pax3 is also expressed in the somites, through which neural crest cells migrate, where it is required for hypaxial muscle development. Homozygous mutant Splotch embryos die by embryonic day 14. We have utilized the proximal 1.6 kb Pax3 promoter and upstream regulatory elements to engineer transgenic mice reproducing endogenous Pax3 expression in neural tube and neural crest, but not the somite. Over expression of Pax3 in these tissues reveals no discernible phenotype. Breeding of transgenic mice onto a Splotch background demonstrates that neural tube and neural crest expression of Pax3 is sufficient to rescue neural tube closure, cardiac development and other neural crest related defects. Transgenic Splotch mice survive until birth at which time they succumb to respiratory failure secondary to absence of a muscular diaphragm. Limb muscles are also absent. These results indicate that regulatory elements sufficient for functional expression of Pax3 required for cardiac development and neural tube closure are contained within the region 1.6 kb upstream of the Pax3 transcriptional start site. In addition, the single Pax3 isoform used for this transgene is sufficient to execute these developmental processes. Although the extracellular matrix and the environment of the somites through which neural crest migrates is known to influence neural crest behavior, our results indicate that Pax3-deficient somites are capable of supporting proper neural crest migration and function suggesting a cell autonomous role for Pax3 in neural crest. (+info)Age-related bone loss: relationship between age and regional bone mineral density. (7/621)
We assessed the changes in regional bone mineral density according to age and examined the relationship between various regional bone mineral densities. The study was conducted in 985 Japanese women divided into < 50-years group (n = 435) and > or = 50 years group (n = 550). The total body bone mineral density and that of the head, arm, leg, thoracic (T)-spine, lumbar (L)-spine, ribs, and pelvis were measured using dual energy x-ray absorptiometry. There was a significant generalized reduction of bone mineral density in all regions after the age of 50 years. The most marked age-related decrease was observed in the L-spine. Bone mineral densities in all regions significantly correlated to each other in both age groups, but the degree of significance varied among regions. The relationship between bone mineral density of the L-spine and that of T-spine regions was the most significant in both groups. In the < 50-years group, the correlation between bone mineral density of the pelvis and that of L-spine and T-spine was the highest, followed by that between the pelvis and the leg. On the other hand, in the > or = 50-years group, the correlation between bone mineral density of the pelvis and that of the leg was the highest, but not the L-spine or T-spine. Since spine measurements are affected by vertebral deformity and/or aortic calcification, our findings suggest the pelvis may be a useful region for screening measurements of bone mineral density, especially in older women. (+info)A gene for autosomal recessive spondylocostal dysostosis maps to 19q13.1-q13.3. (8/621)
In spondylocostal dysostosis (SD), vertebral-segmentation defects are associated with rib anomalies. This results in short-trunk short stature, nonprogressive kyphoscoliosis, and radiological features of multiple hemivertebrae and rib fusions. SD can be familial, and both autosomal dominant and autosomal recessive (AR) inheritance have been reported, but no genes have been identified or localized for nonsyndromic SD in humans. We performed genomewide scanning by homozygosity mapping in a large consanguineous ARSD Arab Israeli family with six definitely affected members. Significant linkage was found to chromosome 19q13, with a LOD score of 6.9. This was confirmed in a second Pakistani family with three affected members, with a LOD score of 2.4. The combined-haplotype data identify a critical region between D19S570 and D19S908, an interval of 8.5 cM on 19q13.1-19q13.3. This is the first study to localize a gene for nonsyndromic SD. ARSD is clinically heterogeneous and is likely to result from mutations in developmental genes or from regulating transcription factors. Identification of these genes will improve the understanding of the molecular processes contributing to both normal and abnormal human vertebral development. (+info)In medical terms, ribs are the long, curved bones that make up the ribcage in the human body. They articulate with the thoracic vertebrae posteriorly and connect to the sternum anteriorly via costal cartilages. There are 12 pairs of ribs in total, and they play a crucial role in protecting the lungs and heart, allowing room for expansion and contraction during breathing. Ribs also provide attachment points for various muscles involved in respiration and posture.
Rib fractures are breaks or cracks in the bones that make up the rib cage, which is the protective structure around the lungs and heart. Rib fractures can result from direct trauma to the chest, such as from a fall, motor vehicle accident, or physical assault. They can also occur from indirect forces, such as during coughing fits in people with weakened bones (osteoporosis).
Rib fractures are painful and can make breathing difficult, particularly when taking deep breaths or coughing. In some cases, rib fractures may lead to complications like punctured lungs (pneumothorax) or collapsed lungs (atelectasis), especially if multiple ribs are broken in several places.
It is essential to seek medical attention for suspected rib fractures, as proper diagnosis and management can help prevent further complications and promote healing. Treatment typically involves pain management, breathing exercises, and, in some cases, immobilization or surgery.
A cervical rib is a congenital anomaly, which means it is present at birth, and it refers to the existence of an extra rib that arises from the seventh cervical vertebra in the neck. Normally, humans have 12 pairs of ribs attached to the thoracic vertebrae in the chest region. However, in some individuals, an additional rib develops from one or both sides of the seventh cervical vertebra, resulting in a cervical rib.
Cervical ribs are usually asymptomatic and may not cause any issues. However, in some cases, they can compress nearby nerves (such as the brachial plexus) or blood vessels (like the subclavian artery), leading to symptoms like pain, numbness, tingling, or weakness in the arm and hand, also known as thoracic outlet syndrome. If the compression is severe or causes significant discomfort, treatment options may include physical therapy, pain management, or surgical removal of the cervical rib.
Cervical rib syndrome is a condition that results from the presence of an extra rib, called a cervical rib, that develops at the base of the neck and extends upwards from the seventh cervical vertebra. This additional rib can put pressure on the surrounding nerves and blood vessels, leading to symptoms such as:
* Pain or numbness in the arm, hand, or fingers
* Weakness or loss of coordination in the hands and arms
* Tingling or a sensation of "pins and needles" in the affected area
* Difficulty swallowing or breathing
The pressure on the brachial plexus, a network of nerves that passes through the cervical region and supplies the upper limb, can cause these symptoms. The compression of the subclavian artery, which runs between the cervical rib and the first rib, can also lead to insufficient blood flow to the arm, causing pain and discoloration.
Cervical rib syndrome is a rare condition that affects less than 1% of the population. Treatment options include physical therapy, pain management, and in some cases, surgical removal of the cervical rib.
The intercostal muscles are a group of muscles located between the ribs (intercostal spaces) in the thoracic region of the body. They play a crucial role in the process of breathing by assisting in the expansion and contraction of the chest wall during inspiration and expiration.
There are two sets of intercostal muscles: the external intercostals and the internal intercostals. The external intercostals run from the lower edge of one rib to the upper edge of the next lower rib, forming a layer that extends from the tubercles of the ribs down to the costochondral junctions (where the rib meets the cartilage). These muscles help elevate the ribcage during inspiration.
The internal intercostals are deeper and run in the opposite direction, originating at the lower edge of a rib and inserting into the upper edge of the next higher rib. They assist in lowering the ribcage during expiration.
Additionally, there is a third layer called the innermost intercostal muscles, which are even deeper than the internal intercostals and have similar functions. The intercostal membranes connect the ends of the ribs and complete the muscle layers between the ribs. Together, these muscles help maintain the structural integrity of the chest wall and contribute to respiratory function.
The thoracic wall refers to the anatomical structure that surrounds and protects the chest cavity or thorax, which contains the lungs, heart, and other vital organs. It is composed of several components:
1. Skeletal framework: This includes the 12 pairs of ribs, the sternum (breastbone) in the front, and the thoracic vertebrae in the back. The upper seven pairs of ribs are directly attached to the sternum in the front through costal cartilages. The lower five pairs of ribs are not directly connected to the sternum but are joined to the ribs above them.
2. Muscles: The thoracic wall contains several muscles, including the intercostal muscles (located between the ribs), the scalene muscles (at the side and back of the neck), and the serratus anterior muscle (on the sides of the chest). These muscles help in breathing by expanding and contracting the ribcage.
3. Soft tissues: The thoracic wall also contains various soft tissues, such as fascia, nerves, blood vessels, and fat. These structures support the functioning of the thoracic organs and contribute to the overall stability and protection of the chest cavity.
The primary function of the thoracic wall is to protect the vital organs within the chest cavity while allowing for adequate movement during respiration. Additionally, it provides a stable base for the attachment of various muscles involved in upper limb movement and posture.
Thoracic outlet syndrome (TOS) is a group of disorders that occur when the blood vessels or nerves in the thoracic outlet, the space between the collarbone (clavicle) and the first rib, become compressed. This compression can cause pain, numbness, and weakness in the neck, shoulder, arm, and hand.
There are three types of TOS:
1. Neurogenic TOS: This is the most common type and occurs when the nerves (brachial plexus) that pass through the thoracic outlet become compressed, causing symptoms such as pain, numbness, tingling, and weakness in the arm and hand.
2. Venous TOS: This type occurs when the veins that pass through the thoracic outlet become compressed, leading to swelling, pain, and discoloration of the arm.
3. Arterial TOS: This is the least common type and occurs when the arteries that pass through the thoracic outlet become compressed, causing decreased blood flow to the arm, which can result in pain, numbness, and coldness in the arm and hand.
TOS can be caused by a variety of factors, including an extra rib (cervical rib), muscle tightness or spasm, poor posture, repetitive motions, trauma, or tumors. Treatment for TOS may include physical therapy, pain management, and in some cases, surgery.
The sternum, also known as the breastbone, is a long, flat bone located in the central part of the chest. It serves as the attachment point for several muscles and tendons, including those involved in breathing. The sternum has three main parts: the manubrium at the top, the body in the middle, and the xiphoid process at the bottom. The upper seven pairs of ribs connect to the sternum via costal cartilages.