Johan Zötterman scite author profile

Objective. Electrical stimulation of the peripheral nervous system (PNS) can treat various diseases and disorders, including the healing process after nerve injury. A major challenge when designing electrodes for PNS stimulation is the mechanical mismatch between the nerve and the device, which can lead to non-conformal contact, tissue damage and inefficient stimulation due to current leakage. Soft and stretchable cuff electrodes promise to tackle these challenges but often have limited performance and rely on unconventional materials. The aim of this study is to develop a high performance soft and stretchable cuff electrode based on inert materials for low-voltage nerve stimulation. Approach. We developed 50 µm thick stretchable cuff electrodes based on silicone rubber, gold nanowire conductors and platinum coated nanowire electrodes. The electrode performance was characterized under strain cycling to assess the durability of the electrodes. The stimulation capability of the cuff electrodes was evaluated in an in vivo sciatic nerve rat model by measuring the electromyography response to various stimulation pulses. Main results. The stretchable cuff electrodes showed excellent stability for 50% strain cycling and one million stimulation pulses. Saturated homogeneous stimulation of the sciatic nerve was achieved at only 200 mV due to the excellent conformability of the electrodes, the low conductor resistance (0.3 Ohm sq−1), and the low electrode impedance. Significance. The developed stretchable cuff electrode combines favourable mechanical properties and good electrode performance with inert and stable materials, making it ideal for low power supply applications within bioelectronic medicine.

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Methodological concerns with laser speckle contrast imaging in clinical evaluation of microcirculation

Zötterman

Mirdell

Horsten

et al. 2017

PLoS ONE

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BackgroundLaser Speckle Contrast Imaging (LSCI) is a non-invasive and fast technique for measuring microvascular blood flow that recently has found clinical use for burn assessment and evaluation of flaps. Tissue motion caused by for example breathing or patient movements may however affect the measurements in these clinical applications, as may distance between the camera and the skin and tissue curvature. Therefore, the aims of this study were to investigate the effect of frame rate, number of frames/image, movement of the tissue, measuring distance and tissue curvature on the measured perfusion.MethodsMethyl nicotinate-induced vasodilation in the forearm skin was measured using LSCI during controlled motion at different speeds, using different combinations of frame rate and number of frames/image, and at varying camera angles and distances. Experiments were made on healthy volunteers and on a cloth soaked in a colloidal suspension of polystyrene microspheres.ResultsMeasured perfusion increased with tissue motion speed. The relation was independent of the absolute perfusion in the skin and of frame rate and number of frames/image. The measured perfusion decreased with increasing angles (16% at 60°, p = 0.01). Measured perfusion did not vary significantly between measurement distances from 15 to 40 cm (p = 0.77, %CV 0.9%).ConclusionTissue motion increases and measurement angles beyond 45° decrease the measured perfusion in LSCI. These findings have to be taken into account when LSCI is used to assess moving or curved tissue surfaces, which is common in clinical applications.

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Monitoring of partial and full venous outflow obstruction in a porcine flap model using laser speckle contrast imaging

Zötterman

Bergkvist

Iredahl

et al. 2016

Journal of Plastic, Reconstructive & Aesthetic Surgery

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The use of laser speckle contrast imaging to predict flap necrosis: An experimental study in a porcine flap model

Zötterman

Tesselaar

Farnebo

2019

Journal of Plastic, Reconstructive & Aesthetic Surgery

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Background: We have evaluated the use of Laser Speckle Contrast Imaging (LSCI) in the perioperative planning in reconstructive surgery. The aim of the study was to investigate if LSCI can predict regions with a high risk of developing postoperative necrosis. Our hypothesis was that, perioperatively, such regions have perfusion values below a threshold value and show a negative perfusion trend. Methods: A porcine flap model based on the cranial gluteal artery perforator was used. Images were acquired prior to surgery, immediately after surgery (t=0), after 30 minutes (t=30 min) and after 72 hours (t=72 h). Regions of Interest (ROI) were chosen along the central axis of the flap. Clinical evaluation of the flap was done during each time point. Results: At t=72h a demarcation line could be seen at 15.8±0.4 cm from the proximal border of the flaps. At t=0 perfusion decreased gradually from proximal to distal ROI. At t=30 min perfusion was significantly lower in ROI distal to the final demarcation line compared to t=0 and every flap these ROI had a perfusion >25 PU. At t=72 perfusion in ROI proximal of this line returned to baseline levels, while perfusion in distal ROI remained low. Conclusions: In our model a decrease in perfusion during the first 30 minutes after surgery, and a perfusion <25 PU at t=30 min was a predictor for tissue morbidity 72 hours after surgery, indicating that LSCI is a promising technique for perioperative monitoring in reconstructive surgery.

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Intraoperative Laser Speckle Contrast Imaging in DIEP Breast Reconstruction: A Prospective Case Series Study

Zötterman

Opsomer²,

Farnebo

et al. 2020

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Introduction: Laser speckle contrast imaging (LSCI) is a laser-based perfusion imaging technique that recently has been shown to predict ischemic necrosis in an experimental flap model and predicting healing time of scald burns. The aims were to investigate perfusion in relation to the selected perforator during deep inferior epigastric artery perforator (DIEP) flap surgery, and to evaluate LSCI in assisting of prediction of postoperative complications. Methods: Twenty-three patients who underwent DIEP-procedures for breast reconstruction at 2 centers were included. Perfusion was measured in 4 zones at baseline, after raising, after anastomosis, and after shaping the flap. The perfusion in relation to the selected perforator and the accuracy of LSCI in predicting complications were analyzed. Results: After raising the flap, zone I showed the highest perfusion (65 ± 10 perfusion units, PU), followed by zone II (58 ± 12 PU), zone III (53 ± 10 PU), and zone IV (45 ± 10 PU). The perfusion in zone I was higher than zone III (P = 0.002) and zone IV (P < 0.001). After anastomosis, zone IV had lower perfusion than zone I (P < 0.001), zone II (P = 0.01), and zone III (P = 0.02). Flaps with areas <30 PU after surgery had partial necrosis postoperatively (n = 4). Conclusions: Perfusion is highest in zone I. No perfusion difference was found between zones II and III. Perfusion <30 PU after surgery was correlated with partial necrosis. LSCI is a promising tool for measurement of flap perfusion and assessment of risk of postoperative ischemic complications.

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