Assessment of Bandaged Burn Wounds Using Porcine Skin and Millimetric Radiometry

Millimetre Wave and Terahertz Sensors and Technology XII

Salmon

2019

Self Cite

Our recent studies in the human skin signatures indicate a strong correlation between the human skin emissivity and factors such as the body mass index, the gender, the age, and the ethnicities of the participants. The key innovation in this is in recognising that signatures from the human body enable regions of the body to be identified as skin. This will enable increased the detection probabilities of anomalies, and reduced the false alarm rates in security screening portals. This is a capability that is being demanded internationally by governments and in the UK by the Home Office Future Aviation Security Solutions (FASS) programme and the Joint Security and Resilience Centre (JSaRC). In this paper, radiometric measurements conducted on human skin in the millimetre wave band region (80-100) GHz show variation in the human skin emissivity before and after conducting physical activity (jogging) subject to the same participant. The measurements were conducted on the palm of the hand and the back of the hand skin. The measurements reveal that the emissivity of the skin is significantly lower in the rest state of the body compared with the active state by mean values of 0.088 and 0.07 for the palm of the hand and the back of the hand skin respectively. The differences in the mean emissivity values were found to be linked to the length of time exercising and the hydration level of the skin i.e. (sweat). Radiometric measurements on palms of the hand and on the back of the hand skin before and after the application of an aqueous gel indicate a strong correlation between the human skin signature and the hydration level of the skin. The mean differences in emissivity values before and after the application of an aqueous gel indicate a scatter in the range of 0.02 to 0.26. These findings suggested trends in the human skin emissivity and indicate the potential of a new non-contact passive method for remote sensing of the physical state of human beings. Understanding these signatures and variations of the human skin emissivity are very important for both security screening (anomalies detection) and medical applications (non-invasive diagnosis of human body).

Section: Introductionmentioning

confidence: 99%

Variation in the electromagnetic signatures of the human skin with physical activity and hydration level of the skin

Millimetre Wave and Terahertz Sensors and Technology XII

Salmon

2019

Self Cite

“…Ex vivo porcine skin samples were taken from the back region of a healthy animal having age of eight months and an average weight of 70 kg. This region is free from hair follicles [44] which presents a limitation for both porcine skin and gelatine phantoms. The purchased sample of porcine skin was cut to have a rectangular shape and dimensions (140×60 mm, 10 mm thickness).…”

Section: Ex Vivo Porcine Skin Fittingmentioning

confidence: 99%

Electrical properties, accuracy, and multi-day performance of gelatine phantoms for electrophysiology

Casson

2020

Preprint

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Gelatine based phantoms for electrophysiology are becoming widely used as they allow the controlled validation of new electrode and new instrumentation designs. The phantoms mimic the electrical properties of the human body and allow a pre-recorded electrophysiology signal to be played-out, giving a known signal for the novel electrode or instrumentation to collect. Such controlled testing is not possible with on-person experiments where the signal to be recorded is intrinsically unknown. However, despite the rising interest in gelatine based phantoms there is relatively little public information about their electrical properties and accuracy, how these vary with phantom formulation, and across both time and frequency. This paper investigates ten different phantom configurations, characterising the impedance path through the phantom and comparing this impedance path to both previously reported electrical models of Ag/AgCl electrodes placed on skin and to a model made from ex vivo porcine skin. This article shows how the electrical properties of the phantoms can be tuned using different concentrations of gelatine and of sodium chloride (NaCl) added to the mixture, and how these properties vary over the course of seven days for a.c. frequencies in the range 20-1000 Hz. The results demonstrate that gelatine phantoms can accurately mimic the frequency response properties of the body-electrode system to allow for the controlled testing of new electrode and instrumentation designs.

“…The relative demerits for this practice are being uncomfortable and painful to the patient (especially for children) [2]. As an alternative to the current medical practice, technologies are emerging to enhance the medical assessment of burn wounds such as terahertz imaging [4][5][6][7], optical coherence tomography [8][9][10][11][12], ultrasound imaging [13][14][15][16], infrared imaging [17][18][19][20], and microwave and millimetre wave (MMW) sensing [2,[21][22][23][24][25][26][27]. The latter is the subject of the research in this paper.…”

Section: Introductionmentioning

confidence: 99%

“…These measurements [23,[36][37][38] reveal that variations in the human skin emissivity are related to the skin thickness and water content. As burn wounds affect significantly the water content of the skin and the skin thickness; we have investigated the feasibility of using a single channel radiometry (passive sensing) to distinguish between unburned and burned skin in [2,27]. Radiometric measurements obtained from a chicken phantom using a 95 GHz radiometer in [2] indicate that there are well define differences in the mean emissivity values between unburned and burned skin and these differences are observable through dressing materials, indicating the feasibility of using radiometry to detect changes in tissue emissivity under dressing materials.…”

Section: Introductionmentioning

confidence: 99%

“…Radiometric measurements obtained from a chicken phantom using a 95 GHz radiometer in [2] indicate that there are well define differences in the mean emissivity values between unburned and burned skin and these differences are observable through dressing materials, indicating the feasibility of using radiometry to detect changes in tissue emissivity under dressing materials. Further, Radiometric measurements in [27] indicate that millimeter-wave radiometry generates a clear signature of porcine skin burns and this could be used as a non-contact method to determine the severity of the burns and the degree of the burns. As an active sensing technology has the advantage of higher penetration capability compared with the passive sensing technology; a mono-static radar system in [21] was used for measuring the propagation path length and the thickness of the dressing materials at different states (dry, wet, and with medicinal cream).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Synthetic Aperture Radar Imaging for Burn Wounds Diagnostics

Rezgui

2020

Sensors

Self Cite

The need for technologies to monitor the wound healing under dressing materials has led us to investigate the feasibility of using microwave and millimetre wave radiations due to their sensitivity to water, non- ionising nature, and transparency to dressing materials and clothing. This paper presents synthetic aperture radar (SAR) images obtained from an active microwave and millimetre wave scanner operating over the band 15–40 GHz. Experimental images obtained from porcine skin samples with the presence of dressing materials and after the application of localised heat treatments reveal that SAR images can be used for diagnosing burns and for potentially monitoring the healing under dressing materials. The experimental images were extracted separately from the amplitude and phase measurements of the input reflection coefficient (S11). The acquired images indicate that skin and burns can be detected and observed through dressing materials as well as features of the skin such as edges, irregularities, bends, burns, and variation in the reflectance of the skin. These unique findings enable a microwave and millimetre-wave scanner to be used for evaluating the wound healing progress under dressing materials without their often-painful removal: a capability that will reduce the cost of healthcare, distress caused by long waiting hours, and the healthcare interventional time.