Home Medicine Novel wireless measurement system of pressure dedicated to in vivo studies
Article Open Access

Novel wireless measurement system of pressure dedicated to in vivo studies

  • Enrique Bances , Antonio Fiestas and Hartmut Witte EMAIL logo
Published/Copyright: September 30, 2016
Download Article (PDF)
Become an author with De Gruyter Brill
Author Information Explore this Subject
Current Directions in Biomedical Engineering
From the journal Current Directions in Biomedical Engineering Volume 2 Issue 1

Abstract

This paper reports on the development of a wireless system to monitor the thoracic cavity pressure in mammals. This project seeks to open a new field using the radio frequency (RF) technology in the studies of the interaction between breathing and locomotion in mammals. Furthermore, this study embodies the first step to develop a method of telemetry and remote monitoring based on implantable devices. In addition, it can be modified with other sensors to measure different physiological parameters.

Keywords: implantable device; locomotor-respiratory coupling; pressure sensor; wireless

1 Introduction

Over the last 30 years, implantable wireless devices have been used in many applications, becoming valuable biomedical tool for telemetry in vivo. Based on this approach, the purpose of this paper is to present an implemented wireless communication system, as an alternate method to study the interaction between locomotion and breathing in mammals. The core system consists of a transmitter and a receiver. In addition, this project seeks for a versatile and reliable telemetry system for future applications, such as monitoring and collecting data of other physiological parameters.

The remainder of the paper is organized into five sections: Section 2 gives a brief review on the coupling of locomotion and breathing in mammals, an overview of implantable pressure devices, and describes the challenges of their design. Section 3 presents the description of the system developed. Experimental results concerning the system are reported in Section 4. Finally, Section 5 presents the discussion and conclusions.

2 Overview of the interaction between the breathing and locomotion in quadrupeds mammals

Human being and their phylogenetic relatives (quadrupedal and bipedal mammals) use the sucking type of breathing. As well for a functio-morphological understanding of that kind of breathing as for the development of technical devices to study thoracal mechanics in human beings, median-sized quadrupedal mammals form a reference.

In literature, several theories have been proposed to explain mechanical interactions between locomotion and breathing in mammals. Bramble and Carrier [1] made a valuable study on quadruped mammals. This research describes the differences between horse and human locomotion cycles in states as trotting and galloping. These studies introduce the concept of Locomotor-respiratory coupling (LCR).

Alexander [2] in a study on wallabies and horses described three coupling mechanisms for running and hopping particularly in mammals: (1) The thorax receives an impact when the forelimbs hit the ground, (2) lumbar flexion considering the contraction in the abdominal muscles and, (3) the inertial movements of the visceral mass in each stride called the “visceral piston”. In recent years, researches on the locomotor-respiratory coupling considered modern technology to support these studies. One example was presented by Simons [3], a hypothesis of visceral displacement in rabbits was developed, based on results of synchronized videographic, cineradiographic and pneumotachographic measurements.

2.1 RF implantable devices and design challenges

Some consideration must be taken into account in the design of implantable devices. The main item to be considered is the choice of a radio frequency (RF) band for the communication. The Federal Communications Commission (FCC) established the Industrial, Scientific, Medical (ISM) bands with the basic frequency of 433 MHz. These bands have become a reliable alternative for short-range and low power communications systems.

On the other hand, other requirement should be considered during the design of implantable devices, such as minimal size and weight, low power consumption and minimization of pain sensation and discomfort to the host. Furthermore, whereas advances in semiconductor and microelectromechanical systems have developed rapidly in recent decades, the antenna and battery size are still a challenge to overcome. The system presented here was designed based on the implantable device features mentioned above, and the commercial components were selected mainly considering the low power consumption and the high reliability, including a pressure sensor accredited for possible future medical applications.

Nowadays, any physiological parameters could be monitored by a telemetry tool like an implantable device. In particular, for pressure monitoring in vivo, researchers have proposed various methods for different applications. Tan et al.[4] developed a pressure device for use in short-term urological studies and patient monitoring. Lin et al. [5] also developed a device to measure pressure changes in the upper urinary tract per degree of obstruction. It is worth mentioning that all the devices presented have the flexibility to connect other sensors, as Valdastri [6] suggested.

This work also takes into account the possibility to connect more pressure sensors in parallel or another type such as an accelerometer to measure diaphragm velocity and acceleration during breathing.

3 Development of wireless system

The structure of the system is based on three basic circuits ensuring proper functioning. This structure is implemented for the transmitter and receiver each. The main component is a microcontroller, which manages and controls all the data flow via the wireless interface. The second component is the transceiver; this module manages the radio frequency communication, allowing data transmission and reception. In the system presented, the design of the device includes a microcontroller and a transceiver coupled in the same chip called System on Chip (SoC). It allows programming the RF communication and the data acquisition in the same chip.

Particularly, the transmitter contains a sensor signal conditioner (SSC), the main function of which is to adapt the sensor signal before microcontroller processing. The SSC in the transmitter is a ZSC31014; the main advantage is the internal CMOS circuit for highly accurate amplification and analog to digital conversion of the signals of the differential piezoresistive sensor. The data output is transmitted to the SoC by SPI channel as is shown in Figure 1.

Figure 1: Transmitter blocks diagram.
Figure 1:

Transmitter blocks diagram.

Finally, the piezoresistive pressure sensor belongs to the series NPC-100, designed specifically for medical applications. Further, the catheter is wrapped with a biocompatible silicone Nusil MED-4011.

The evaluation board (EB) SmartRF®04EB with a RF module based on the SoC was chosen as a receiver. Further, this EB in connected with the PC, where the Graphic unit interface (GUI) implemented in Matlab®(R2013a, The MathWorks, Inc.) decodes and shows the data received.

As was mentioned above, the focus of this paper is on the proper functioning of the wireless system with pressure data acquisition as a first step of a future implantable device. For practical operation, this system also includes other connectors for power supply and additional headers to monitor the principal signals. All characteristics of the transmitter are illustrated in Figure 1 and 2.

Figure 2: Developed module of the transmitter.
Figure 2:

Developed module of the transmitter.

3.1 Electrical features of the transmitter

The power supply board hosts mainly the coin cell lithium battery (CR1216) of 3.0 Vdc. Additionally, it includes a reed switch, activated by an external electromagnetic field. Thus, the devices inside the thoracic cavity can be switched on exclusively during the data transmission.

The total current consumption of the device in the transmission mode is around 35 mA. This value references when the device is programmed at 10 dBm. The total power consumption with 3 Vdc. of power supply is 1068 mW.

4 Experimental results and analysis

The main goals in our experiments were to test mainly three characteristic of our system: (1) The performance of the pressure sensor catheter, (2) the data wireless communication (protocol) between the transmitter and the receiver, (3) the graphic unit interface connected with the receiver, showing and processing the data in the computer in real time.

To test the sensor catheter and the transmitter, we used a container filled with a bio-material such as pork meat. Externally, a rubber bulb was connected to change the pressure inside the container. The experiment structure can be seen in Figure 3.

Figure 3: Graphical illustration of experimental test
Figure 3:

Graphical illustration of experimental test

In addition, the transmitter was located outside the container and sent the pressure data wirelessly using the frequency of 433 MHz. Finally, a digital manometer measured the pressure inside the container to provide a pressure reference. Figure 4 shows the pressure sensor and the silicone catheter. The wires were connected to the transmitter through a flexible medical tube (Tygon ND 100-65), which protected and isolated the wires from the material inside the container.

Figure 4: Piezoresistive sensor NPC-100 and catheter.
Figure 4:

Piezoresistive sensor NPC-100 and catheter.

The first results confirmed the sensor linearity mentioned in the data sheet. This is important to consider due to the demand that the system needs to assure that the sensor is linear in the pressure range required (–40 mmHg to +40 mmHg), as shown in Figure 5. This test was made in the container without any material, the sensor was located on the bottom of the container and the data was compared with that of the manometer. Figure 6 illustrates the second test, the container was filled with pork meat, and the sensor was placed inside the meat. To generate pressure variations inside the container, via the bulb we introduced small amounts of air. The hermetic lid released the air slowly and the digital manometer measured the data in real time. On the other hand, the sensor measured the pressure changes and the transmitter processed and sent the data wirelessly. The communication between the transmitter and receiver worked without any interference and continuously.

Figure 5: Calibrated values of the sensor compared with the sensor ideal response.
Figure 5:

Calibrated values of the sensor compared with the sensor ideal response.

Figure 6: Implemented test bench.
Figure 6:

Implemented test bench.

Figure 7 presents the rapid pressures changes detected by the sensor. The differences between the data measured by the manometer and the sensor basically responds to two factors: (1) the calibration parameter of the sensor needs to be adjusted, (2) the digital value of the manometer was measured visually.

Figure 7: Response of the sensor after an air impulse inside the container. Reference is the m pressure reported by the manometer.
Figure 7:

Response of the sensor after an air impulse inside the container. Reference is the m pressure reported by the manometer.

5 Discussion and conclusion

In summary, we developed a wireless device to measure in future the pressure in vivo within the thoracic cavity of a medium size quadruped mammal. Next step has to be an in vivo evaluation of its functions in animal experiments.

The system was designed considering the technical specification of implantable devices, such as low power consumption, standard communication protocols, biocompatible material to reduce any kind of infection in the animal and the flexibility to extend the device using other sensors.

The RF technology used in this application, responses to the commercial frequency range (433 MHz) for medical devices according to the international standards bands (ISM). However, the device supports also the frequency band for implantable devices.

Concerning the experiments and results, we could test the sensor performance in a simulated bio-environment. The linearity of the NPC-100 sensor guarantees a correct measurement of the pressure. However, it is necessary to test other sensor with similar technical conditions in order to make more reliable devices. Finally, this device was developed to measure pressure. However, it can be expanded to additional sensing modalities, such as accelerometry to measure the position and speed of the diaphragm during breathing, or a thermistor for measurements of thoracic temperature.

Acknowledgement

The authors of this paper would like to thank Dr.-Ing. Ralf Stephan and his team in the Microwave Technology Group of Technische Univesität Ilmenau for the help provided during this work. We also thank the Peruvian institution “Fincyt” for the financial support of the Peruvians researchers.

Author’s Statement

Research funding: The author state no funding involved. Conflict of interest: Authors state no conflict of interest. Material and Methods: Informed consent: Informed consent has been obtained from all individuals included in this study. Ethical approval: The research related to animal use complies all the relevant national regulations and institutional policies for the care and use of animals.

References

[1] Bramble DM, Carrier DR. Running and breathing in mammals. Science. 1983;219:251–6.10.1126/science.6849136Search in Google Scholar PubMed

[2] Alexander RMcN. On the synchronization of breathing with running in wallabies (macropus spp.) and horses (equus caballus). J Zool. 1989;218:69–85.10.1111/j.1469-7998.1989.tb02526.xSearch in Google Scholar

[3] Simons RS. Running, breathing and visceral motion in the domestic rabbit (oryctolagus cuniculus): testing visceral displacement hypotheses. J Exp Biol. 1999;202:563–77.10.1242/jeb.202.5.563Search in Google Scholar PubMed

[4] Tan R, McClure T, Lin CK, Jea D, Dabiri F, Massey T, et al. Development of a fully implantable wireless pressure monitoring system. Biomed Microdevices. 2009;11:259–64.10.1007/s10544-008-9232-1Search in Google Scholar PubMed

[5] Lin CK, Jea D, Dabiri F, Massey T, Tan R, Sarrafzadeh M, et al. The development of an in-vivo active pressure monitoring system. In: 4th International Workshop on Wearable and Implantable Body Sensor Networks (BSN 2007). Springer; 2007;105–10.10.1007/978-3-540-70994-7_18Search in Google Scholar

[6] Valdastri P, Menciassi A, Arena A, Caccamo C, Dario P. An implantable telemetry platform system for in vivo monitoring of physiological parameters. IEEE Trans on Inf Technol Biomed. 2004;8:271–8.10.1109/TITB.2004.834389Search in Google Scholar PubMed

Published Online: 2016-9-30
Published in Print: 2016-9-1

©2016 Hartmut Witte et al., licensee De Gruyter.

This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.

Articles in the same Issue

  1. Synthesis and characterization of PIL/pNIPAAm hybrid hydrogels
  2. Novel blood protein based scaffolds for cardiovascular tissue engineering
  3. Cell adhesion and viability of human endothelial cells on electrospun polymer scaffolds
  4. Effects of heat treatment and welding process on superelastic behaviour and microstructure of micro electron beam welded NiTi
  5. Long-term stable modifications of silicone elastomer for improved hemocompatibility
  6. The effect of thermal treatment on the mechanical properties of PLLA tubular specimens
  7. Biocompatible wear-resistant thick ceramic coating
  8. Protection of active implant electronics with organosilicon open air plasma coating for plastic overmolding
  9. Examination of dielectric strength of thin Parylene C films under various conditions
  10. Open air plasma deposited antimicrobial SiOx/TiOx composite films for biomedical applications
  11. Systemic analysis about residual chloroform in PLLA films
  12. A macrophage model of osseointegration
  13. Towards in silico prognosis using big data
  14. Technical concept and evaluation of a novel shoulder simulator with adaptive muscle force generation and free motion
  15. Usability evaluation of a locomotor therapy device considering different strategies
  16. Hypoxia-on-a-chip
  17. Integration of a semi-automatic in-vitro RFA procedure into an experimental setup
  18. Fabrication of MEMS-based 3D-μECoG-MEAs
  19. High speed digital interfacing for a neural data acquisition system
  20. Bionic forceps for the handling of sensitive tissue
  21. Experimental studies on 3D printing of barium titanate ceramics for medical applications
  22. Patient specific root-analogue dental implants – additive manufacturing and finite element analysis
  23. 3D printing – a key technology for tailored biomedical cell culture lab ware
  24. 3D printing of hydrogels in a temperature controlled environment with high spatial resolution
  25. Biocompatibility of photopolymers for additive manufacturing
  26. Biochemical piezoresistive sensors based on pH- and glucose-sensitive hydrogels for medical applications
  27. Novel wireless measurement system of pressure dedicated to in vivo studies
  28. Portable auricular device for real-time swallow and chew detection
  29. Detection of miRNA using a surface plasmon resonance biosensor and antibody amplification
  30. Simulation and evaluation of stimulation scenarios for targeted vestibular nerve excitation
  31. Deep brain stimulation: increasing efficiency by alternative waveforms
  32. Prediction of immediately occurring microsleep events from brain electric signals
  33. Determining cardiac vagal threshold from short term heart rate complexity
  34. Classification of cardiac excitation patterns during atrial fibrillation
  35. An algorithm to automatically determine the cycle length coverage to identify rotational activity during atrial fibrillation – a simulation study
  36. Deriving respiration from high resolution 12-channel-ECG during cycling exercise
  37. Reducing of gradient induced artifacts on the ECG signal during MRI examinations using Wilcoxon filter
  38. Automatic detection and mapping of double potentials in intracardiac electrograms
  39. Modeling the pelvic region for non-invasive pelvic intraoperative neuromonitoring
  40. Postprocessing algorithm for automated analysis of pelvic intraoperative neuromonitoring signals
  41. Best practice: surgeon driven application in pelvic operations
  42. Vasomotor assessment by camera-based photoplethysmography
  43. Classification of morphologic changes in photoplethysmographic waveforms
  44. Novel computation of pulse transit time from multi-channel PPG signals by wavelet transform
  45. Efficient design of FIR filter based low-pass differentiators for biomedical signal processing
  46. Nonlinear causal influences assessed by mutual compression entropy
  47. Comparative study of methods for solving the correspondence problem in EMD applications
  48. fNIRS for future use in auditory diagnostics
  49. Semi-automated detection of fractional shortening in zebrafish embryo heart videos
  50. Blood pressure measurement on the cheek
  51. Derivation of the respiratory rate from directly and indirectly measured respiratory signals using autocorrelation
  52. Left cardiac atrioventricular delay and inter-ventricular delay in cardiac resynchronization therapy responder and non-responder
  53. An automatic systolic peak detector of blood pressure waveforms using 4th order cumulants
  54. Real-time QRS detection using integrated variance for ECG gated cardiac MRI
  55. Preprocessing of unipolar signals acquired by a novel intracardiac mapping system
  56. In-vitro experiments to characterize ventricular electromechanics
  57. Continuous non-invasive monitoring of blood pressure in the operating room: a cuffless optical technology at the fingertip
  58. Application of microwave sensor technology in cardiovascular disease for plaque detection
  59. Artificial blood circulatory and special Ultrasound Doppler probes for detecting and sizing gaseous embolism
  60. Detection of microsleep events in a car driving simulation study using electrocardiographic features
  61. A method to determine the kink resistance of stents and stent delivery systems according to international standards
  62. Comparison of stented bifurcation and straight vessel 3D-simulation with a prior simulated velocity profile inlet
  63. Transient Euler-Lagrange/DEM simulation of stent thrombosis
  64. Automated control of the laser welding process of heart valve scaffolds
  65. Automation of a test bench for accessing the bendability of electrospun vascular grafts
  66. Influence of storage conditions on the release of growth factors in platelet-rich blood derivatives
  67. Cryopreservation of cells using defined serum-free cryoprotective agents
  68. New bioreactor vessel for tissue engineering of human nasal septal chondrocytes
  69. Determination of the membrane hydraulic permeability of MSCs
  70. Climate retainment in carbon dioxide incubators
  71. Multiple factors influencing OR ventilation system effectiveness
  72. Evaluation of an app-based stress protocol
  73. Medication process in Styrian hospitals
  74. Control tower to surgical theater
  75. Development of a skull phantom for the assessment of implant X-ray visibility
  76. Surgical navigation with QR codes
  77. Investigation of the pressure gradient of embolic protection devices
  78. Computer assistance in femoral derotation osteotomy: a bottom-up approach
  79. Automatic depth scanning system for 3D infrared thermography
  80. A service for monitoring the quality of intraoperative cone beam CT images
  81. Resectoscope with an easy to use twist mechanism for improved handling
  82. In vitro simulation of distribution processes following intramuscular injection
  83. Adjusting inkjet printhead parameters to deposit drugs into micro-sized reservoirs
  84. A flexible standalone system with integrated sensor feedback for multi-pad electrode FES of the hand
  85. Smart control for functional electrical stimulation with optimal pulse intensity
  86. Tactile display on the remaining hand for unilateral hand amputees
  87. Effects of sustained electrical stimulation on spasticity assessed by the pendulum test
  88. An improved tracking framework for ultrasound probe localization in image-guided radiosurgery
  89. Improvement of a subviral particle tracker by the use of a LAP-Kalman-algorithm
  90. Learning discriminative classification models for grading anal intraepithelial neoplasia
  91. Regularization of EIT reconstruction based on multi-scales wavelet transforms
  92. Assessing MRI susceptibility artefact through an indicator of image distortion
  93. EyeGuidance – a computer controlled system to guide eye movements
  94. A framework for feedback-based segmentation of 3D image stacks
  95. Doppler optical coherence tomography as a promising tool for detecting fluid in the human middle ear
  96. 3D Local in vivo Environment (LivE) imaging for single cell protein analysis of bone tissue
  97. Inside-Out access strategy using new trans-vascular catheter approach
  98. US/MRI fusion with new optical tracking and marker approach for interventional procedures inside the MRI suite
  99. Impact of different registration methods in MEG source analysis
  100. 3D segmentation of thyroid ultrasound images using active contours
  101. Designing a compact MRI motion phantom
  102. Cerebral cortex classification by conditional random fields applied to intraoperative thermal imaging
  103. Classification of indirect immunofluorescence images using thresholded local binary count features
  104. Analysis of muscle fatigue conditions using time-frequency images and GLCM features
  105. Numerical evaluation of image parameters of ETR-1
  106. Fabrication of a compliant phantom of the human aortic arch for use in Particle Image Velocimetry (PIV) experimentation
  107. Effect of the number of electrodes on the reconstructed lung shape in electrical impedance tomography
  108. Hardware dependencies of GPU-accelerated beamformer performances for microwave breast cancer detection
  109. Computer assisted assessment of progressing osteoradionecrosis of the jaw for clinical diagnosis and treatment
  110. Evaluation of reconstruction parameters of electrical impedance tomography on aorta detection during saline bolus injection
  111. Evaluation of open-source software for the lung segmentation
  112. Automatic determination of lung features of CF patients in CT scans
  113. Image analysis of self-organized multicellular patterns
  114. Effect of key parameters on synthesis of superparamagnetic nanoparticles (SPIONs)
  115. Radiopacity assessment of neurovascular implants
  116. Development of a desiccant based dielectric for monitoring humidity conditions in miniaturized hermetic implantable packages
  117. Development of an artifact-free aneurysm clip
  118. Enhancing the regeneration of bone defects by alkalizing the peri-implant zone – an in vitro approach
  119. Rapid prototyping of replica knee implants for in vitro testing
  120. Protecting ultra- and hyperhydrophilic implant surfaces in dry state from loss of wettability
  121. Advanced wettability analysis of implant surfaces
  122. Patient-specific hip prostheses designed by surgeons
  123. Plasma treatment on novel carbon fiber reinforced PEEK cages to enhance bioactivity
  124. Wear of a total intervertebral disc prosthesis
  125. Digital health and digital biomarkers – enabling value chains on health data
  126. Usability in the lifecycle of medical software development
  127. Influence of different test gases in a non-destructive 100% quality control system for medical devices
  128. Device development guided by user satisfaction survey on auricular vagus nerve stimulation
  129. Empirical assessment of the time course of innovation in biomedical engineering: first results of a comparative approach
  130. Effect of left atrial hypertrophy on P-wave morphology in a computational model
  131. Simulation of intracardiac electrograms around acute ablation lesions
  132. Parametrization of activation based cardiac electrophysiology models using bidomain model simulations
  133. Assessment of nasal resistance using computational fluid dynamics
  134. Resistance in a non-linear autoregressive model of pulmonary mechanics
  135. Inspiratory and expiratory elastance in a non-linear autoregressive model of pulmonary mechanics
  136. Determination of regional lung function in cystic fibrosis using electrical impedance tomography
  137. Development of parietal bone surrogates for parietal graft lift training
  138. Numerical simulation of mechanically stimulated bone remodelling
  139. Conversion of engineering stresses to Cauchy stresses in tensile and compression tests of thermoplastic polymers
  140. Numerical examinations of simplified spondylodesis models concerning energy absorption in magnetic resonance imaging
  141. Principle study on the signal connection at transabdominal fetal pulse oximetry
  142. Influence of Siluron® insertion on model drug distribution in the simulated vitreous body
  143. Evaluating different approaches to identify a three parameter gas exchange model
  144. Effects of fibrosis on the extracellular potential based on 3D reconstructions from histological sections of heart tissue
  145. From imaging to hemodynamics – how reconstruction kernels influence the blood flow predictions in intracranial aneurysms
  146. Flow optimised design of a novel point-of-care diagnostic device for the detection of disease specific biomarkers
  147. Improved FPGA controlled artificial vascular system for plethysmographic measurements
  148. Minimally spaced electrode positions for multi-functional chest sensors: ECG and respiratory signal estimation
  149. Automated detection of alveolar arches for nasoalveolar molding in cleft lip and palate treatment
  150. Control scheme selection in human-machine- interfaces by analysis of activity signals
  151. Event-based sampling for reducing communication load in realtime human motion analysis by wireless inertial sensor networks
  152. Automatic pairing of inertial sensors to lower limb segments – a plug-and-play approach
  153. Contactless respiratory monitoring system for magnetic resonance imaging applications using a laser range sensor
  154. Interactive monitoring system for visual respiratory biofeedback
  155. Development of a low-cost senor based aid for visually impaired people
  156. Patient assistive system for the shoulder joint
  157. A passive beating heart setup for interventional cardiology training
https://doi.org/10.1515/cdbme-2016-0030
Keywords for this article
implantable device; locomotor-respiratory coupling; pressure sensor; wireless
Creative Commons
BY-NC-ND 4.0

Articles in the same Issue

  1. Synthesis and characterization of PIL/pNIPAAm hybrid hydrogels
  2. Novel blood protein based scaffolds for cardiovascular tissue engineering
  3. Cell adhesion and viability of human endothelial cells on electrospun polymer scaffolds
  4. Effects of heat treatment and welding process on superelastic behaviour and microstructure of micro electron beam welded NiTi
  5. Long-term stable modifications of silicone elastomer for improved hemocompatibility
  6. The effect of thermal treatment on the mechanical properties of PLLA tubular specimens
  7. Biocompatible wear-resistant thick ceramic coating
  8. Protection of active implant electronics with organosilicon open air plasma coating for plastic overmolding
  9. Examination of dielectric strength of thin Parylene C films under various conditions
  10. Open air plasma deposited antimicrobial SiOx/TiOx composite films for biomedical applications
  11. Systemic analysis about residual chloroform in PLLA films
  12. A macrophage model of osseointegration
  13. Towards in silico prognosis using big data
  14. Technical concept and evaluation of a novel shoulder simulator with adaptive muscle force generation and free motion
  15. Usability evaluation of a locomotor therapy device considering different strategies
  16. Hypoxia-on-a-chip
  17. Integration of a semi-automatic in-vitro RFA procedure into an experimental setup
  18. Fabrication of MEMS-based 3D-μECoG-MEAs
  19. High speed digital interfacing for a neural data acquisition system
  20. Bionic forceps for the handling of sensitive tissue
  21. Experimental studies on 3D printing of barium titanate ceramics for medical applications
  22. Patient specific root-analogue dental implants – additive manufacturing and finite element analysis
  23. 3D printing – a key technology for tailored biomedical cell culture lab ware
  24. 3D printing of hydrogels in a temperature controlled environment with high spatial resolution
  25. Biocompatibility of photopolymers for additive manufacturing
  26. Biochemical piezoresistive sensors based on pH- and glucose-sensitive hydrogels for medical applications
  27. Novel wireless measurement system of pressure dedicated to in vivo studies
  28. Portable auricular device for real-time swallow and chew detection
  29. Detection of miRNA using a surface plasmon resonance biosensor and antibody amplification
  30. Simulation and evaluation of stimulation scenarios for targeted vestibular nerve excitation
  31. Deep brain stimulation: increasing efficiency by alternative waveforms
  32. Prediction of immediately occurring microsleep events from brain electric signals
  33. Determining cardiac vagal threshold from short term heart rate complexity
  34. Classification of cardiac excitation patterns during atrial fibrillation
  35. An algorithm to automatically determine the cycle length coverage to identify rotational activity during atrial fibrillation – a simulation study
  36. Deriving respiration from high resolution 12-channel-ECG during cycling exercise
  37. Reducing of gradient induced artifacts on the ECG signal during MRI examinations using Wilcoxon filter
  38. Automatic detection and mapping of double potentials in intracardiac electrograms
  39. Modeling the pelvic region for non-invasive pelvic intraoperative neuromonitoring
  40. Postprocessing algorithm for automated analysis of pelvic intraoperative neuromonitoring signals
  41. Best practice: surgeon driven application in pelvic operations
  42. Vasomotor assessment by camera-based photoplethysmography
  43. Classification of morphologic changes in photoplethysmographic waveforms
  44. Novel computation of pulse transit time from multi-channel PPG signals by wavelet transform
  45. Efficient design of FIR filter based low-pass differentiators for biomedical signal processing
  46. Nonlinear causal influences assessed by mutual compression entropy
  47. Comparative study of methods for solving the correspondence problem in EMD applications
  48. fNIRS for future use in auditory diagnostics
  49. Semi-automated detection of fractional shortening in zebrafish embryo heart videos
  50. Blood pressure measurement on the cheek
  51. Derivation of the respiratory rate from directly and indirectly measured respiratory signals using autocorrelation
  52. Left cardiac atrioventricular delay and inter-ventricular delay in cardiac resynchronization therapy responder and non-responder
  53. An automatic systolic peak detector of blood pressure waveforms using 4th order cumulants
  54. Real-time QRS detection using integrated variance for ECG gated cardiac MRI
  55. Preprocessing of unipolar signals acquired by a novel intracardiac mapping system
  56. In-vitro experiments to characterize ventricular electromechanics
  57. Continuous non-invasive monitoring of blood pressure in the operating room: a cuffless optical technology at the fingertip
  58. Application of microwave sensor technology in cardiovascular disease for plaque detection
  59. Artificial blood circulatory and special Ultrasound Doppler probes for detecting and sizing gaseous embolism
  60. Detection of microsleep events in a car driving simulation study using electrocardiographic features
  61. A method to determine the kink resistance of stents and stent delivery systems according to international standards
  62. Comparison of stented bifurcation and straight vessel 3D-simulation with a prior simulated velocity profile inlet
  63. Transient Euler-Lagrange/DEM simulation of stent thrombosis
  64. Automated control of the laser welding process of heart valve scaffolds
  65. Automation of a test bench for accessing the bendability of electrospun vascular grafts
  66. Influence of storage conditions on the release of growth factors in platelet-rich blood derivatives
  67. Cryopreservation of cells using defined serum-free cryoprotective agents
  68. New bioreactor vessel for tissue engineering of human nasal septal chondrocytes
  69. Determination of the membrane hydraulic permeability of MSCs
  70. Climate retainment in carbon dioxide incubators
  71. Multiple factors influencing OR ventilation system effectiveness
  72. Evaluation of an app-based stress protocol
  73. Medication process in Styrian hospitals
  74. Control tower to surgical theater
  75. Development of a skull phantom for the assessment of implant X-ray visibility
  76. Surgical navigation with QR codes
  77. Investigation of the pressure gradient of embolic protection devices
  78. Computer assistance in femoral derotation osteotomy: a bottom-up approach
  79. Automatic depth scanning system for 3D infrared thermography
  80. A service for monitoring the quality of intraoperative cone beam CT images
  81. Resectoscope with an easy to use twist mechanism for improved handling
  82. In vitro simulation of distribution processes following intramuscular injection
  83. Adjusting inkjet printhead parameters to deposit drugs into micro-sized reservoirs
  84. A flexible standalone system with integrated sensor feedback for multi-pad electrode FES of the hand
  85. Smart control for functional electrical stimulation with optimal pulse intensity
  86. Tactile display on the remaining hand for unilateral hand amputees
  87. Effects of sustained electrical stimulation on spasticity assessed by the pendulum test
  88. An improved tracking framework for ultrasound probe localization in image-guided radiosurgery
  89. Improvement of a subviral particle tracker by the use of a LAP-Kalman-algorithm
  90. Learning discriminative classification models for grading anal intraepithelial neoplasia
  91. Regularization of EIT reconstruction based on multi-scales wavelet transforms
  92. Assessing MRI susceptibility artefact through an indicator of image distortion
  93. EyeGuidance – a computer controlled system to guide eye movements
  94. A framework for feedback-based segmentation of 3D image stacks
  95. Doppler optical coherence tomography as a promising tool for detecting fluid in the human middle ear
  96. 3D Local in vivo Environment (LivE) imaging for single cell protein analysis of bone tissue
  97. Inside-Out access strategy using new trans-vascular catheter approach
  98. US/MRI fusion with new optical tracking and marker approach for interventional procedures inside the MRI suite
  99. Impact of different registration methods in MEG source analysis
  100. 3D segmentation of thyroid ultrasound images using active contours
  101. Designing a compact MRI motion phantom
  102. Cerebral cortex classification by conditional random fields applied to intraoperative thermal imaging
  103. Classification of indirect immunofluorescence images using thresholded local binary count features
  104. Analysis of muscle fatigue conditions using time-frequency images and GLCM features
  105. Numerical evaluation of image parameters of ETR-1
  106. Fabrication of a compliant phantom of the human aortic arch for use in Particle Image Velocimetry (PIV) experimentation
  107. Effect of the number of electrodes on the reconstructed lung shape in electrical impedance tomography
  108. Hardware dependencies of GPU-accelerated beamformer performances for microwave breast cancer detection
  109. Computer assisted assessment of progressing osteoradionecrosis of the jaw for clinical diagnosis and treatment
  110. Evaluation of reconstruction parameters of electrical impedance tomography on aorta detection during saline bolus injection
  111. Evaluation of open-source software for the lung segmentation
  112. Automatic determination of lung features of CF patients in CT scans
  113. Image analysis of self-organized multicellular patterns
  114. Effect of key parameters on synthesis of superparamagnetic nanoparticles (SPIONs)
  115. Radiopacity assessment of neurovascular implants
  116. Development of a desiccant based dielectric for monitoring humidity conditions in miniaturized hermetic implantable packages
  117. Development of an artifact-free aneurysm clip
  118. Enhancing the regeneration of bone defects by alkalizing the peri-implant zone – an in vitro approach
  119. Rapid prototyping of replica knee implants for in vitro testing
  120. Protecting ultra- and hyperhydrophilic implant surfaces in dry state from loss of wettability
  121. Advanced wettability analysis of implant surfaces
  122. Patient-specific hip prostheses designed by surgeons
  123. Plasma treatment on novel carbon fiber reinforced PEEK cages to enhance bioactivity
  124. Wear of a total intervertebral disc prosthesis
  125. Digital health and digital biomarkers – enabling value chains on health data
  126. Usability in the lifecycle of medical software development
  127. Influence of different test gases in a non-destructive 100% quality control system for medical devices
  128. Device development guided by user satisfaction survey on auricular vagus nerve stimulation
  129. Empirical assessment of the time course of innovation in biomedical engineering: first results of a comparative approach
  130. Effect of left atrial hypertrophy on P-wave morphology in a computational model
  131. Simulation of intracardiac electrograms around acute ablation lesions
  132. Parametrization of activation based cardiac electrophysiology models using bidomain model simulations
  133. Assessment of nasal resistance using computational fluid dynamics
  134. Resistance in a non-linear autoregressive model of pulmonary mechanics
  135. Inspiratory and expiratory elastance in a non-linear autoregressive model of pulmonary mechanics
  136. Determination of regional lung function in cystic fibrosis using electrical impedance tomography
  137. Development of parietal bone surrogates for parietal graft lift training
  138. Numerical simulation of mechanically stimulated bone remodelling
  139. Conversion of engineering stresses to Cauchy stresses in tensile and compression tests of thermoplastic polymers
  140. Numerical examinations of simplified spondylodesis models concerning energy absorption in magnetic resonance imaging
  141. Principle study on the signal connection at transabdominal fetal pulse oximetry
  142. Influence of Siluron® insertion on model drug distribution in the simulated vitreous body
  143. Evaluating different approaches to identify a three parameter gas exchange model
  144. Effects of fibrosis on the extracellular potential based on 3D reconstructions from histological sections of heart tissue
  145. From imaging to hemodynamics – how reconstruction kernels influence the blood flow predictions in intracranial aneurysms
  146. Flow optimised design of a novel point-of-care diagnostic device for the detection of disease specific biomarkers
  147. Improved FPGA controlled artificial vascular system for plethysmographic measurements
  148. Minimally spaced electrode positions for multi-functional chest sensors: ECG and respiratory signal estimation
  149. Automated detection of alveolar arches for nasoalveolar molding in cleft lip and palate treatment
  150. Control scheme selection in human-machine- interfaces by analysis of activity signals
  151. Event-based sampling for reducing communication load in realtime human motion analysis by wireless inertial sensor networks
  152. Automatic pairing of inertial sensors to lower limb segments – a plug-and-play approach
  153. Contactless respiratory monitoring system for magnetic resonance imaging applications using a laser range sensor
  154. Interactive monitoring system for visual respiratory biofeedback
  155. Development of a low-cost senor based aid for visually impaired people
  156. Patient assistive system for the shoulder joint
  157. A passive beating heart setup for interventional cardiology training
Sign up now to receive a 20% welcome discount
Institutional Access
How does access work?
Winner of the OpenAthens UX Award 2026
Winner of the OpenAthens UX Award 2026
Have an idea on how to improve our website?
Please write us.
© 2026 De Gruyter Brill
Downloaded on 5.3.2026 from https://www.degruyterbrill.com/document/doi/10.1515/cdbme-2016-0030/html
Scroll to top button