Noninvasive monitoring of gas in the lungs and intestines of newborn infants using diode lasers: feasibility study

Lundin, Patrik; Svanberg, Emilie Krite; Cocola, Lorenzo; Xu, Märta Lewander; Somesfalean, Gabriel; Andersson‐Engels, Stefan; Jahr, John; Fellman, Vineta; Svanberg, Katarina; Svanberg, Sune

doi:10.1117/1.jbo.18.12.127005

Cited by 26 publications

(26 citation statements)

References 30 publications

(15 reference statements)

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“…In our pilot study (21), water vapor was detected in the lungs of three infants, but no oxygen, even though obviously present during the measurements, probably due to the fact that the Articles oxygen absorption is much weaker than that of water vapor. For this reason, the power of the diode laser (at 760 nm) detecting oxygen was now increased to around 30 mW.…”

Section: Discussionmentioning

confidence: 61%

“…Our results show that the revised system is capable of detecting oxygen, the gas of main interest, in the lungs of infants ranging from <3,000 g up to almost 4,000 g. However, further technical developments are clearly needed for a more stable and robust performance, where oxygen would be detectable at all relevant locations. According to the findings in our pilot study (21), the geometry chosen for measurements was in the midclavicular line between the collar bone and the nipple bilateral. Three different positions following this line were used (Figure 3) showing similar signal intensities.…”

Section: Discussionmentioning

confidence: 99%

“…A detailed description of the basic system is published (21). It enables quantification of gas constituents in cavities surrounded by solid materials from gas absorption imprints in light transmitted through the cavity.…”

Section: Spectroscopic Techniquementioning

confidence: 99%

“…Light emitted from this laser was coupled through a 2-m multimode 600-µm fiber (Thorlabs, Newton, New Jersey) into a probe. This probe comprised a highly reflecting polytetrafluoroethylene plate (thickness 6 mm, diameter 15 mm) with threaded connectors for optical fibers from the 30 mW oxygen (Toptica, Munich, Germany) and 4 mW water vapor (Nanoplus, Gerbrunn, Germany) lasers, as well as for a small reference photodiode (21). All emitting fiber tips were covered with thin transparent light-diffusing material (polypropylene).…”

Section: Spectroscopic Techniquementioning

confidence: 99%

“…We could detect both oxygen gas and water vapor in a feasibility in vitro study of the optical GASMAS technique applied on a wild boar lung phantom, covered with gelatin layers with scattering particles and absorbing ink to resemble the chest of a small infant (20). In a pilot in vivo study, we showed that water vapor was detectable with GASMAS in the lungs and in the gastrointestinal tract of three full-term infants weighing 4,000-5,000 g (21). Since absorption lines for oxygen are much weaker than those for water vapor, and since thoracic tissue layers covering the lungs are thicker in larger than in smaller infants, penetration of light into the lungs was probably too low to enable detection of intrapulmonary oxygen gas in that study.…”

mentioning

confidence: 94%

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Diode laser spectroscopy for noninvasive monitoring of oxygen in the lungs of newborn infants

et al. 2015

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Section: Discussionmentioning

confidence: 61%

Section: Discussionmentioning

confidence: 99%

Section: Spectroscopic Techniquementioning

confidence: 99%

Section: Spectroscopic Techniquementioning

confidence: 99%

mentioning

confidence: 94%

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Diode laser spectroscopy for noninvasive monitoring of oxygen in the lungs of newborn infants

et al. 2015

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Gas in Scattering Media Absorption Spectroscopy

Svanberg

2019

Encyclopedia of Analytical Chemistry

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Gas in scattering media absorption spectroscopy (GASMAS) is a new variety of tunable diode laser spectroscopy (TDLS). It combines concepts from atmospheric trace‐gas monitoring with those pertinent to biological tissue optics. The former field deals with high‐resolution spectroscopy in nonscattering media, whereas the latter area is characterized by broad absorption structures in strongly scattering media. GASMAS provides novel applications in, for example, the material science and biophotonics fields. The absorptive imprints of free gases inside pores or cavities in surrounding solid or liquid matter are typically many orders of magnitude narrower than those of the host material, a fact that is critically utilized. The gas signals are detected in the weak, multiply scattered light emerging from the illuminated sample. Wavelength‐modulation and phase‐sensitive detection techniques are employed, typically in connection with single‐mode CW lasers. Any gas with useful absorption at wavelengths where the host material does not absorb strongly can be detected. For biological tissue, containing liquid water and blood, this limits the useful region to the ‘tissue optical window’ − 650–1400 nm – where, however, the interesting gases oxygen and water vapor absorb at around 760 and 950 nm, respectively. This limitation does not pertain to other materials, particularly not to those that do not contain liquid water. GASMAS experiments, which relate to basic physics, include studies of nanoporous ceramics, where wall collisions influence the line shape and provide information on pore‐size distribution. A small piece of strongly scattering ceramic can serve as an alignment‐free multipass cell with effective path length hundreds of times longer than the physical dimension. Porosity and gas transport studies in construction materials such as polystyrene foams, wood, ceramics, and paper are examples of applications in the material science field. The technique is further very powerful for studying gas in the human body and products that humans eat, such as packaged foods, fruits, and pharmaceutical preparations. A key aspect of food packaging is to prevent oxygen to influence the food. Frequently, modified atmospheres with nitrogen or carbon dioxide as filling gases are used. Applications include monitoring the performance of packaging machines and measurements of the product on the shelf. Porosity in pharmaceutical tablets is important to determine, as it has bearing on controlled release. Following initial work on healthy volunteers, a clinical trial concerning human sinus cavities has been performed. Gas filling and composition can be used as a diagnostic tool in connection with sinusitis, a very common disorder, also related to the problem with heavy overprescription of antibiotics and associated growing bacterial resistance. Following realistic phantom studies, it was shown that it is possible to detect gas in the lungs and intestines of a newborn baby, which could be of considerable interest for the future care of prematurely born children. Gas diffusion and transport can be dynamically studied in response to an abrupt change in gas composition in medicine as well as in material science. The GASMAS technique is fully nonintrusive and nondestructive.

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Diagnostics of femoral head status in humans using laser spectroscopy – In vitro studies

Lin

Zhang

et al. 2016

Journal of Biophotonics

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Osteonecrosis of the femoral head (ONFH), a recalcitrant and disabling disease, is caused by inadequate or fully disrupted blood supply to the affected segment of the subchondral bone. Theoretically, there will develop gas-filled pores during the bone decay process due to lacking blood supply. Unfortunately, the relationship between the gas-filled pores and ONFH is still unclear. Here, we have introduced diode laser absorption spectroscopy to detect oxygen and water vapor signals in the femoral heads from hip replacement in 19 patients. Five samples are affected by osteoarthritis (OA) and the others are related to ONFH. Oxygen and water vapor signals could be obtained, demonstrating the presence of gas-filled pores in both the OA and ONFH groups while the measurement results showed no significant difference. A study of gas exchange was also performed on one excised bone sample to study how these gas pores communicate with the ambient air. The results suggested that the obtained oxygen signals inside the bone samples originate from the invasion of ambient air, which is not expected in vivo. In conclusion, the ability to detect the gas signal of laser absorption spectroscopy shows the potential for the medical application of assessing the human femoral head in vivo.

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Noninvasive monitoring of gas in the lungs and intestines of newborn infants using diode lasers: feasibility study

Cited by 26 publications

References 30 publications

Diode laser spectroscopy for noninvasive monitoring of oxygen in the lungs of newborn infants

Diode laser spectroscopy for noninvasive monitoring of oxygen in the lungs of newborn infants

Gas in Scattering Media Absorption Spectroscopy

Diagnostics of femoral head status in humans using laser spectroscopy – In vitro studies

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