Advanced Pathophysiology
Bone Tumors
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Speaker 2: Bone tumors form when a bone cell divides uncontrollably and forms a mass or tumor. If the tumor remains confined and doesn't spread into surrounding tissues, then it's considered benign. But if the tumor invades into surrounding tissues and metastasizes or spreads through blood or lymph, then it's considered malignant. Malignant tumors can either be primary, which is when they arise from bone cells; or secondary, which is when a tumor developed somewhere else in the body, metastasized, and spread to the bones.
The most common sources of tumor cells that affect the bones but start somewhere else in the body, are the breast, prostate, the lungs, the thyroid, and the kidneys. Now, even though the bones vary in size and shape, they are all made of the same types of cells, and chief among them are osteoblasts, which build up new bone, and osteoclasts which help with bone breakdown or resorption. Now, in addition to these, there are some more primitive cells in the bone marrow called human mesenchymal stem cells and neuroectodermal cells, which have the ability to differentiate into many cell types including nerve, fat, bone, and cartilage cells.
Now, in terms of anatomy, looking at a long bone like the femur, it has two epiphyses, which are the ends that contribute to joints with other bones. Between the two epiphyses is the diaphysis, also called the bone shaft. In children and adolescents, there is an additional narrow portion between the epiphysis and the diaphysis called the metaphysis. The metaphysis contains the growth plate, the part of the bone that grows during childhood. In adults, the growth plate has ossified and fused with the diaphysis and the epiphysis.
Now, there are genes that promote normal cell growth called proto-oncogenes. With mutations, proto-oncogenes become oncogenes, and these overstimulate the cell growth. To balance out cell growth, there are other genes called tumor suppressor genes, which promote apoptosis or cell death of mutated cells. So oncogenes or mutated tumor suppressor genes allow cells to keep growing uncontrollably resulting into tumors.
All right, primary bone tumors can be divided up into ones that are most often benign, and those that are more often malignant. Let's start with the most common benign tumor, which is an osteochondroma and commonly affects males under 25 years of age. Osteochondroma is thought to arise from mutations in the Exostosin 1, or EXT1, and Exostosin 2, or EXT2, genes, which encode the Exostosin 1 and 2 proteins. These proteins help to synthesize heparin sulfate, which is a protein that regulates the growth of the growth plate. So in osteochondroma, a tumor arises from the growth plate, and it typically results in a lateral bony projection. This bony stalk is called an exostosis, and it has a cap, made mostly of hyaline cartilage. Now, osteochondromas typically develop in the metaphysis of long bones, most usually the distal femur and the proximal tibia, around the knee joint, but they can also occur in flat bones like the ilium, one of the hip bones, as well as the scapula.
Another benign tumor is the giant-cell tumor of the bone, quite a name. A risk factor for giant-cell tumors is having a bony trauma like a fracture or radiation exposure. The tumor cells arise from osteoclasts cells, but then develop into cells that have numerous nuclei, typically over 50 nuclei, so you can think of them as destructive little giants. The giant cell tumor typically arises in the epiphysis of the long bones, like the distal femur and the proximal tibia. On rare occasions, this tumor can become malignant, especially in elderly individuals.
Other benign tumors are osteoblastomas and osteoid osteomas, both of which arise from osteoblasts. Both of these tumors classically form a nidus, which is a disorganized mix of small blood vessels, tiny rods of bone called trabeculae, and unmineralized bony tissue called osteoid. In osteoid blastomas, the nidi, which is plural for nidus, are large with a diameter of over 1.5 centimeters. In osteoid osteomas, the nidi are smaller than 1.5 centimeters in diameter and are often surrounded by a ring of sclerotic bone tissue. That ring of sclerotic tissue often produces prostaglandins, which are small molecules that trigger the sensation of pain. Osteoblastomas also tend to affect the bones of the axial skeleton, usually the mandible, and erode the surrounding bone. In comparison, osteoid osteomas typically affect the diaphysis of long bones like the tibia and don't usually erode the surrounding bone.
Now, among malignant tumors, the most common one is osteosarcoma. Osteosarcomas arise from osteoblasts of different sizes called pleomorphic, and these cells produce too much osteoid tissue. Osteosarcomas often form in the metaphysis where there's a lot of cell division occurring. They most commonly affect adolescents. Some known mutations that are linked to osteosarcomas include mutations of the pRB protein, also seen in familial retinoblastoma, a childhood malignant tumor of the eye, and the p53 protein, which is also seen in Li-Fraumeni syndrome, a condition where there are a variety of cancers throughout the body.
Another type of malignant bone tumor is Ewing's sarcoma, which is also common in adolescents, typically between the age of 10 to 20 years. Ewing's sarcoma is thought to arise from neuroectodermal cells, which look like small, round, blue cells on microscopy. Ewing's sarcoma is associated with chromosomal mutations, specifically a translocation between the EWSR1 gene on chromosome 22 and the FLI1 gene on chromosome 11. You can remember this by 22 plus 11 equals 33, the Jersey number of the former basketball player, Patrick Ewing. The EWSR1-FLI1 fusion results in the expression of an abnormal protein called, you guessed it, the EWSR1-FLI1 fusion protein, or more simply the Ewing's sarcoma protein. This protein causes defects in the differentiation process of human mesenchymal stem cell in neuroectodermal cells, resulting in Ewing's sarcoma tumor cells. Ewing's sarcoma can affect a number of different bones, but most commonly affects the femur in the sacrum.
Finally, there are chondrosarcomas, which tend to affect the elderly. Chondrosarcoma arises from the chondrocytes, which are cartilage-producing cells. Chondrosarcoma mainly affects bones of the pelvis, but can also affect long bones like the proximal femur and proximal humerus. On imaging, the mass is typically within the medullary cavity.
Bone tumors commonly cause bone pain, swelling, and fractures. Some unique symptoms are that the pain of osteoid osteoma typically gets worse at night while osteochondromas and osteoblastomas sometimes press against spinal nerves causing numbness and limb weakness. They can also cause avascular necrosis of certain regions within the bone if the tumor impinges on a major blood vessel. Malignant tumors typically cause a chronic inflammatory response, which leads to fever, night sweats, and weight loss. Bony tumors often metastasize to the lungs so in that setting, they can cause pulmonary symptoms like coughing and shortness of breath.
The diagnosis of bone tumors starts with medical imaging like x-rays, CT scans, and MRI imaging, or testing for serum tumor markers that are specific for each type of tumor. Some tumors also have some classic x-ray findings. For example, osteochondroma causes exostosis while the giant cell tumor forms multi-cystic bone lesions that look like soap bubbles. Osteosarcoma form lytic bone lesions referred to as a sunburst appearance because the radiating tumor streaks look like sun rays. Osteosarcomas also cause the periosteum to lift, and that's commonly called Codman's triangle. In Ewing's sarcoma, x-ray shows lytic bone lesions referred to as an onion skin appearance because the periosteum looks like a sliced onion bulb. In chondrosarcoma, there are patchy lytic lesions that make the bone look like a moth-eaten piece of cloth.
The treatment of bone tumors depends on whether they are malignant or benign. Benign tumors can be surgically removed to reduce pain and the risk of fractures, while malignant tumors are treated with radiotherapy, chemotherapy, and surgery, depending on the type and the spread of the tumor.
All right, as a quick recap: benign tumors include osteochondroma, which presents with exostosis; giant cell tumor, which has giant cells and looks like soap bubbles on x-ray; osteoid osteoma, characterized by a nidus less than 1.5 centimeters; and osteoblastoma, whose nidus is greater than 1.5 centimeters. The primary malignant tumors include osteosarcoma that are made of large pleomorphic cells and have a sunburst appearance on x-ray; Ewing's sarcoma that has round blue cells and a sliced onion appearance on x-ray; and chondrosarcoma, which has large multi-nucleated chondrocytes and a moth-eaten appearance on x-ray.
There are no known causes of the bone tumors, but among risk factors we have rapid bone growth, bone trauma, exposure to radiations, and positive family history of bone tumors. Osteosarcoma is linked to RB1 and TP53 gene mutations while Ewing's sarcoma is thought to arise when there are EWSR1 and FLI1 gene mutations. Benign tumors can be surgically removed if they're causing symptoms while the treatment for malignant tumors requires radiotherapy, chemotherapy, and surgery.