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Bone Structure01:55

Bone Structure

Within the skeletal system, the structure of a bone, or osseous tissue, can be exemplified in a long bone, like the femur, where there are two types of osseous tissue: cortical and cancellous.
Compact Bone01:27

Compact Bone

Most bones contain compact and spongy osseous tissue, but their distribution and concentration vary based on the bone's overall function.
Compact bone, also called cortical bone, is the denser, stronger of the two types of bone tissue. It is found under the periosteum and in the diaphyses of long bones, where it provides support and protection. The microscopic structural unit of compact bone is called an osteon, or haversian system. Each osteon is composed of concentric rings of calcified...
Spongy Bone01:09

Spongy Bone

All bones comprise an outer layer of compact bone, and an interior made up of spongy bone tissue, also called cancellous or trabecular bone. In long bones, spongy bone tissue is mainly found in the interior of the epiphyses (broad ends of the bone).
Spongy bone is more porous, and less dense compared to compact bone. It is composed of concentric lamellae that are arranged irregularly to form the trabecular network. In some bones, the spaces between trabeculae contain red marrow, where...
Gross Anatomy of Bone01:17

Gross Anatomy of Bone

The two main features of a long bone are the diaphysis and the epiphysis.
The diaphysis is the tubular shaft that runs between the proximal and distal ends of the bone. The walls of the diaphysis are composed of dense and hard compact bone made of numerous osteons — the functional unit of the compact bone. The hollow region in the diaphysis is called the medullary cavity, which harbors the bone marrow. In infants and children, this marrow cavity is filled with red marrow, whereas in adults, it...
Bone Remodeling01:40

Bone Remodeling

Bone remodeling is a continuous and balanced process of bone resorption by osteoclasts and bone formation by osteoblasts. In adults, it helps maintain bone mass and calcium homeostasis. While mechanical stress can stimulate turnover as part of the normal maintenance and reparative process, several hormones also regulate bone remodeling.
Bone Cells and Tissue01:30

Bone Cells and Tissue

Bones contain a relatively small number of cells entrenched in a matrix of organic and inorganic components. Although bone cells compose only a small amount of the bone volume, they are crucial to its function. Four types of cells are found within the bone tissue— osteoblasts, osteocytes, osteogenic cells, and osteoclasts.
Osteoblasts and Osteocytes
The osteoblast is the bone cell responsible for forming new bone tissue. It is found in the growing portions of bone, including the periosteum and...

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Artificial intelligence on the identification of risk groups for osteoporosis, a general review.

Biomedical engineering online·2018
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Related Experiment Video

Updated: Jun 6, 2026

Comprehensive Characterization of Tissue Mineralization in an Ex Vivo Model
07:29

Comprehensive Characterization of Tissue Mineralization in an Ex Vivo Model

Published on: September 27, 2024

Characterization of bone tissue using microstrip antennas.

Jannayna D Barros1, Jose Josemar de Oliveira, Sandro G da Silva

  • 1PPgEEC/CT/UFRN, Campus Universitário, 59072-970, Natal-RN, Brazil. jannadb@gmail.com

Annual International Conference of the IEEE Engineering in Medicine and Biology Society. IEEE Engineering in Medicine and Biology Society. Annual International Conference
|November 25, 2010
PubMed
Summary
This summary is machine-generated.

Electromagnetic waves can differentiate bone tissues by mass. Microwave frequencies reveal distinct behaviors in bones with varying bone mass, aiding in tissue characterization.

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Area of Science:

  • Biomedical Engineering
  • Electromagnetics
  • Biophysics

Background:

  • Electromagnetic waves interact with biological materials, a phenomenon known since the 19th century.
  • Characterizing biological tissues using electromagnetic properties is an established scientific field.
  • Understanding tissue properties is crucial for medical diagnostics and research.

Purpose of the Study:

  • To investigate the use of electromagnetic waves for characterizing biological tissues.
  • To differentiate bone tissues based on their varying bone mass levels.
  • To analyze the behavior of bone tissues across different microwave frequencies.

Main Methods:

  • Utilized an antenna array fabricated on microstrip lines.
  • Employed microwave frequencies for tissue analysis.
  • Focused on characterizing bone samples with different bone mass densities.

Main Results:

  • Observed distinct electromagnetic wave interactions with bones of varying mass.
  • Demonstrated that bone mass significantly influences tissue behavior at microwave frequencies.
  • Confirmed the efficacy of the microstrip line antenna array for this application.

Conclusions:

  • Electromagnetic wave characterization is effective for differentiating bone tissues by mass.
  • Microwave frequency analysis provides a viable method for assessing bone density variations.
  • The developed antenna array shows promise for future biomedical applications.