Microindentation Device Measures Bone Health
By HospiMedica International staff writers Posted on 14 Dec 2021 |
Image: The OsteoProbe handheld bone measurement tool (Photo courtesy of Active Life Scientific)
A novel testing tool physically interacts with bone tissue at the microscopic level, quantifying bone health using a measurable score.
The Active Life Scientific (ALSI; Santa Barbara, CA, USA) OsteoProbe is a handheld tool that uses reference point indentation (RPI) technology in order to investigate bone’s ability to resist puncture. The output is the bone material strength index (BMSi), the ratio between the indentation distance in bone versus a polymathylmethacrylate (PMMA) reference. The BMSi score represents bone properties that resist the separation of mineralized collagen fibrils. Patient bone scores fall between 45 (low) to 105 (high).
“There's a difference between how much bone you have, or density, and how good your bone tissue is. Most patients who suffer a fracture due to fragile bones do not have osteoporotic bone density,” said Professor Paul Hansma, PhD, who invented the technology behind the OsteoProbe. “The Bone Score test quantifies how bone tissue resists a physical challenge, on a safe, microscopic level, and provides previously unavailable data for physicians to consider when investigating the quality of a patient's bone.”
“It's been decades since a new measurement method was introduced to the field of osteoporosis, as DEXA and ultrasound technologies have been widely used since the 1990s. New clinical tools are desperately needed to understand the health of our bones,” said Peter Burks, CEO of ALSI. “Many diseases have a library of measurement tools available, but bone health management remains mostly limited to radiation-based imaging technologies. Physical interaction with bone tissue unlocks a previously unavailable data stream for physicians to consider when evaluating their patients.”
RPI testing is based on the Mohs scale of mineral hardness, in which materials are ranked according to what they can scratch and are, in turn, scratched by. During the course of indentation, a record of the depth of penetration is made, and then the area of the indent is determined using the known geometry of the indentation tip. These values can be plotted to create a load-displacement curve, which can be used to extract more sophisticated mechanical properties of the material.
Related Links:
Active Life Scientific
The Active Life Scientific (ALSI; Santa Barbara, CA, USA) OsteoProbe is a handheld tool that uses reference point indentation (RPI) technology in order to investigate bone’s ability to resist puncture. The output is the bone material strength index (BMSi), the ratio between the indentation distance in bone versus a polymathylmethacrylate (PMMA) reference. The BMSi score represents bone properties that resist the separation of mineralized collagen fibrils. Patient bone scores fall between 45 (low) to 105 (high).
“There's a difference between how much bone you have, or density, and how good your bone tissue is. Most patients who suffer a fracture due to fragile bones do not have osteoporotic bone density,” said Professor Paul Hansma, PhD, who invented the technology behind the OsteoProbe. “The Bone Score test quantifies how bone tissue resists a physical challenge, on a safe, microscopic level, and provides previously unavailable data for physicians to consider when investigating the quality of a patient's bone.”
“It's been decades since a new measurement method was introduced to the field of osteoporosis, as DEXA and ultrasound technologies have been widely used since the 1990s. New clinical tools are desperately needed to understand the health of our bones,” said Peter Burks, CEO of ALSI. “Many diseases have a library of measurement tools available, but bone health management remains mostly limited to radiation-based imaging technologies. Physical interaction with bone tissue unlocks a previously unavailable data stream for physicians to consider when evaluating their patients.”
RPI testing is based on the Mohs scale of mineral hardness, in which materials are ranked according to what they can scratch and are, in turn, scratched by. During the course of indentation, a record of the depth of penetration is made, and then the area of the indent is determined using the known geometry of the indentation tip. These values can be plotted to create a load-displacement curve, which can be used to extract more sophisticated mechanical properties of the material.
Related Links:
Active Life Scientific
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