IRJET- Survey on Robust Real-Time Needle Tracking in 2-D Ultrasound Images using Statistical Filtering
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This survey examines methods for robust real-time needle tracking in 2D ultrasound images using statistical filtering. One method introduces selecting a region of interest and finding the needle tip and axis using Kalman and particle filters to improve accuracy and precision. These filters are used to reduce noise and outliers when tracking the needle tip during both manual and robotic needle insertion procedures. The advantages of automatic robotic needle insertion over manual insertion include increased accuracy and reduced execution time.
![International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 05 Issue: 12 | Dec 2018 www.irjet.net p-ISSN: 2395-0072
© 2018, IRJET | Impact Factor value: 7.211 | ISO 9001:2008 Certified Journal | Page 42
improve the accuracy and precisionofthetiptracking,to
filter out the noise. There are different methods for
needle insertion. But none of themhaveaccurateresults.
Fig. 1. Experimental setup
Nowadays, surgical robots are used for the treatment of
malignant tumors [1]. The main objective of this method is to
provide surgeons with robots to assist them. Robotassistants,
like surgeon extenders and auxiliary surgical supports,
provide a fundamental aid to the tasks surgeons in the
execution of critical surgical. They perform simple surgical
actions. Medical image processing simply extracts the
clinically useful information of the patient in the form of an
image. And this extracted information can be used for health
analysis and to provide the appropriatetreatment. Nowadays
in the fully automatic environment robots are used to insert
the needle into the patient’s body and this needle tip is under
tracking. This type of needle tracking in 2D ultrasound
images are a very prominent application of medical image
processing.
insertion into a soft-tissue using an ultrasound
transducer. The transducer is used to measure the needle
tip movement. In this algorithm,a compensatorisusedfor
out of plane motion and also determine the needle tip
velocity to find the out of plane motion.
Percutaneous needle procedures, such as biopsy
and drug delivery, are commonly used in medical
practices. Visibility of the needle plays an important role
in the success of these procedures. Particularlyinbiopsies,
if the needle is misplaced, erroneous samples might be
collected and organs might be punctured leading to
internal bleeding. In order to prevent such failures, the
trajectory of the needle has to be predetermined and the
needle tip should be tracked using medical imaging
techniques.
Ultrasound-guided biopsy is a commonly
performed medical procedure routine in clinical practice.
To improve the precision in theexecutionand thesafetyof
the patient, the task could be performed by robotic
systems. Both robotic and human procedures could
greatly benefit from real-time localization of the needlein
US images. The robot or the specialists can be guided by
this retrieved information. The actual problem is that US
data provide very low-qualityimagesofthe needlemaking
this task quite complex. In the [4] proposed algorithm
presents a needle localization method which is able to
extract the needle orientation and the tip position. Here
using an optical tracking system to measure the position
and the orientation of the needle and the US probe.
The needle should be detected precisely in the
percutaneous needle procedures using ultrasound
imaging in order to avoid damage to the tissue and to get
the samples from the appropriatesite.Thedetectionofthe
needle and its tip is actually too difficult due to the
excessive artifacts and low resolution of the ultrasound
images. Using image processing it is possible to enhance
the needle tip. In the [5] algorithm proposes a novel
needle detection method in 2D US images based on the
Gabor filter. The suggested method enhances the needle
outline along with the suppression of the other structures
in the image. The needle insertion angle is estimated first.
And then the needle trajectory is found with the RANSAC
line estimator.
A design specification process for the
development of intelligent surgical robotsisdescribed[6].
Nowadays, the surgeons manually controlled the surgical
robots by using teleoperation. This goal of fully automatic
robotic surgery can only be achieved by means ofa formal
assessment of surgical requirements and these needs to
translate into behavioral specifications.Theapplicationof
Requirements Engineering to surgical knowledge
formalization is also explained in the paper.
Nowadays, automatic needle insertion is one of
the most commonly performed procedures in themedical
field. It improves the accuracy and decreases the
execution time. The advantage of this algorithm is an easy
insertion of the needle. This paper presents [3], a real-
time algorithm for the tracking of flexible needles during
In [2], a new method is introduced for finding the
needle axis and needle tip position by manual insertionof the
needle. This method uses a 3 D ultrasound image. This
method proposed a new real-time algorithm for tracking the
needle tip. This algorithm is used to detect the needle and it
provides a feedback signal as the feedback variable.
Extracting the needle tip position from theultrasoundimages
by using this algorithm and also verifying that the needle tip
is not close to any forbidden regions.](https://image.slidesharecdn.com/irjet-v5i1209-181227065638/85/IRJET-Survey-on-Robust-Real-Time-Needle-Tracking-in-2-D-Ultrasound-Images-using-Statistical-Filtering-2-320.jpg){kind=tracking}
![International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 05 Issue: 12 | Dec 2018 www.irjet.net p-ISSN: 2395-0072
© 2018, IRJET | Impact Factor value: 7.211 | ISO 9001:2008 Certified Journal | Page 43
3. CONCLUSION
Nowadays robotics in the medical field with medical image
processing is a highly active research area.Eventhoughmany
ideas and concepts have beenproposedtheoretically,theyare
not actually implemented in the real word environment.Ifwe
can develop a fully automatic medical robotic environment
with précised medical image processing, it can help us to
suppress the faults in treatment and can improve the quality
of life of a patient.
REFERENCES
[1] P. Chatelain, A. Krupa, and M. Marchal, “Real-time
needle detection andtrackingusinga visuallyservoed
3D ultrasound probe,” in Proc. IEEE Int. Conf. Robot.
Autom., May 2013, pp. 1676–1681.
[2] E. M. Boctor, M. A. Choti, E. C. Burdette, and R. J. Webster,
III, “Threedimensional ultrasound-guided roboticneedle
placement: An experimental evaluation,” Int. J. Med.
Robot. Comput. Assist. Surgery, vol. 4, no. 2, pp. 180–191,
2008.
[3] G. J. Vrooijink, M. Abayazid, and S. Misra, “Real-time
threedimensional flexible needle tracking using two-
dimensional ultrasound,” in Proc. IEEE Int. Conf.
Robot. Autom., May 2013, pp. 1688–1693.
[4] G. J. Vrooijink, M. Abayazid, and S. Misra, “Real-time
threedimensional flexible needletrackingusingtwo-
dimensional ultrasound,” in Proc. IEEE Int. Conf.
Robot. Autom., May 2013, pp. 1688–1693.
[5] M. Kaya and O. Bebek, “Needle localization using Gabor
filtering in 2D ultrasoundimages,”in Proc.IEEEInt.Conf.
Robot. Autom. (ICRA), May/Jun.2014,pp.4881–4886. G.
J. Vrooijink, M. Abayazid, and S. Misra, “Real-time
threedimensional flexible needle tracking using two-
dimensional ultrasound,” in Proc. IEEE Int. Conf. Robot.
Autom., May 2013, pp. 1688–1693.
[6] M. Bonfè et al., “Towards automated surgical robotics: A
requirements engineering approach,” in Proc. 4th IEEE
RAS EMBS Int. Conf. Biomed. Robot. Biomechatronics
(BioRob), Jun. 2012, pp. 56–61.
BIOGRAPHIES
Neethu S Kumar received the
Bachelor’s Degree in Computer
Science and Engineering fromSree
Buddha college of Engineering,
Kerala, India in 2017. She is
currently pursing Master’s Degree
in Computer Science and
Engineering in Sree Buddha
College of Engineering, Kerala,
India.
Prof. Supriya L P. has more than 12
years of experience in teaching,
Research and industry. She
completed her post-graduation in
Computer Science from Madras
University in 2003. She received
her M.Phil. Fromthedepartmentof
computer Science in 2007,
Annamalai University specialized
in image processing .She received
her Master of Engineering (M.E)
degree from School of Computing,
Sathyabama University, Computer
Science and Engineering in 2009.
At present she is pursuingherPhD.
She started her career as a faculty
of Computer Science in 2004 at
Chennai. She has got a number of
publications in conferences and
Journals national/international.](https://image.slidesharecdn.com/irjet-v5i1209-181227065638/85/IRJET-Survey-on-Robust-Real-Time-Needle-Tracking-in-2-D-Ultrasound-Images-using-Statistical-Filtering-3-320.jpg){kind=tracking}
IRJET- Survey on Robust Real-Time Needle Tracking in 2-D Ultrasound Images using Statistical Filtering
- 1. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056 Volume: 05 Issue: 12 | Dec 2018 www.irjet.net p-ISSN: 2395-0072 © 2018, IRJET | Impact Factor value: 7.211 | ISO 9001:2008 Certified Journal | Page 41 SURVEY ON ROBUST REAL-TIME NEEDLE TRACKING IN 2-D ULTRASOUND IMAGES USING STATISTICAL FILTERING Neethu S Kumar1, Supriya L P2 1MTech, Dept. of Computer Science & Engineering, Sree Buddha College of Engineering, Pathanamthitta, Kerala 2 Assistant Professor, Dept. of computer science & Engineering, Sree Buddha College of Engineering, Pathanamthitta, Kerala ---------------------------------------------------------------------***---------------------------------------------------------------------- Abstract:- This paper presents a survey of the automation of needle insertion by a robot. The main advantage of this method is to increase accuracy and decrease the execution time. For the treatment of malignant tumors, there is a minimally invasive surgical procedure by using a needle or a needle-shaped probe. There are different methods has been developed for insertion of the needle. In this method, the needle tip is extracted from ultrasoundimagesforverifyingthatthetip is not come to close any forbidden regions. The method for estimating the tip has been developed by using Hough transform, image filtering. This paper improves introducing a method for selection of the region in the ultrasound images and to finding the needle tip and needle axis by using Kalman filter and Particle filter. Key Words: Kalman filter, Particle filter 1. INTRODUCTION The advantages compared with manual insertion is to demolish only a small amount of healthy body parts, low cost, and faster retrieval. Image techniques are used for finding the needle axis and needle tip from theultrasound images. Ultrasound guidance is the commonly used for thermal ablation and biopsy. A needle inserted from the outside of into the human body which destroys one or more pathologic tissue through the manual insertion of the needle. The insertion of the needle by a robot which increases the accuracy and decreases the execution time. The robot insertion will reduce the number of CT scans. The needle is the endfeet of the robotfortracking the needle tip position. The needle tip estimationfromthe ultrasound images for verifying that the needle is not reaching any forbidden regions. There are several methods for tracking the needle tip during the insertion. The insertion of the needle is directly controlled by the Robot as the feedback variable for estimating the correct tip position. In addition, when a robot is inserting the needle, the insertion path is planned using ultrasound images and the movement during the interposition from precalibrated design. In manual insertion, the insertionof the needle tip is very difficult and hard compared with automatic insertion. The automatic insertionoftheneedle is very helpful to increase the accuracy. There are several methods fortrackingtheneedle axis and estimating the needle tip. But there is no method using ultrasound image feedback signal during the insertion of the needle. There are different real-time algorithms for detecting needle tip based on the Hough transform, which does not provide a good accuracy for needle tip position. There are different real-time methods for finding the curved needles tip in ultrasound images. This algorithm finds the needlepoint but does not provide a well-founded estimation of the needle tip position. In this method, a new real-time algorithm for finding the needle tip based on the 2D ultrasound images. This method is presented for improving some following aspects. First, finding the region of interest for estimating the needle tip. Second, statistical filters are used to increase the accuracyand precision of thetiptracking.The algorithm can also rely on velocity measurements to improve tracking accuracy when the insertion is performed by a robotic system. The performance of the algorithm in manual and robotic insertions are in different ways. The insertion of the needle by a robot is a better way than manual insertion. In this method, the implementation of the algorithm by using statistical filters.TheKalmanfilterand Particle filter are used for the implementation of the algorithm for estimating the needle axis and tracking the needle tip position. These filters have been used to improve the accuracy and precision of the tip tracking, to filter out the noise, and to cope with outliers. There are main two objectives in this paper. First is to design an accurate and robust observer for a robotic system inserting a needle. Second is provide a method that may assist physicians inserting a needle manually. 2. RELATED WORKS There are several roboticapproachestofindtheneedle insertion, but there is no method use ultrasound image feedback during the insertion. In this paper, the method is an automatic insertion of the needle by using Robot could increase the accuracy and decrease the execution of time. This method is introducing a selection of the region of interest in the ultrasound images by using Kalman filter and Particle filter. These filters are used to
- 2. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056 Volume: 05 Issue: 12 | Dec 2018 www.irjet.net p-ISSN: 2395-0072 © 2018, IRJET | Impact Factor value: 7.211 | ISO 9001:2008 Certified Journal | Page 42 improve the accuracy and precisionofthetiptracking,to filter out the noise. There are different methods for needle insertion. But none of themhaveaccurateresults. Fig. 1. Experimental setup Nowadays, surgical robots are used for the treatment of malignant tumors [1]. The main objective of this method is to provide surgeons with robots to assist them. Robotassistants, like surgeon extenders and auxiliary surgical supports, provide a fundamental aid to the tasks surgeons in the execution of critical surgical. They perform simple surgical actions. Medical image processing simply extracts the clinically useful information of the patient in the form of an image. And this extracted information can be used for health analysis and to provide the appropriatetreatment. Nowadays in the fully automatic environment robots are used to insert the needle into the patient’s body and this needle tip is under tracking. This type of needle tracking in 2D ultrasound images are a very prominent application of medical image processing. insertion into a soft-tissue using an ultrasound transducer. The transducer is used to measure the needle tip movement. In this algorithm,a compensatorisusedfor out of plane motion and also determine the needle tip velocity to find the out of plane motion. Percutaneous needle procedures, such as biopsy and drug delivery, are commonly used in medical practices. Visibility of the needle plays an important role in the success of these procedures. Particularlyinbiopsies, if the needle is misplaced, erroneous samples might be collected and organs might be punctured leading to internal bleeding. In order to prevent such failures, the trajectory of the needle has to be predetermined and the needle tip should be tracked using medical imaging techniques. Ultrasound-guided biopsy is a commonly performed medical procedure routine in clinical practice. To improve the precision in theexecutionand thesafetyof the patient, the task could be performed by robotic systems. Both robotic and human procedures could greatly benefit from real-time localization of the needlein US images. The robot or the specialists can be guided by this retrieved information. The actual problem is that US data provide very low-qualityimagesofthe needlemaking this task quite complex. In the [4] proposed algorithm presents a needle localization method which is able to extract the needle orientation and the tip position. Here using an optical tracking system to measure the position and the orientation of the needle and the US probe. The needle should be detected precisely in the percutaneous needle procedures using ultrasound imaging in order to avoid damage to the tissue and to get the samples from the appropriatesite.Thedetectionofthe needle and its tip is actually too difficult due to the excessive artifacts and low resolution of the ultrasound images. Using image processing it is possible to enhance the needle tip. In the [5] algorithm proposes a novel needle detection method in 2D US images based on the Gabor filter. The suggested method enhances the needle outline along with the suppression of the other structures in the image. The needle insertion angle is estimated first. And then the needle trajectory is found with the RANSAC line estimator. A design specification process for the development of intelligent surgical robotsisdescribed[6]. Nowadays, the surgeons manually controlled the surgical robots by using teleoperation. This goal of fully automatic robotic surgery can only be achieved by means ofa formal assessment of surgical requirements and these needs to translate into behavioral specifications.Theapplicationof Requirements Engineering to surgical knowledge formalization is also explained in the paper. Nowadays, automatic needle insertion is one of the most commonly performed procedures in themedical field. It improves the accuracy and decreases the execution time. The advantage of this algorithm is an easy insertion of the needle. This paper presents [3], a real- time algorithm for the tracking of flexible needles during In [2], a new method is introduced for finding the needle axis and needle tip position by manual insertionof the needle. This method uses a 3 D ultrasound image. This method proposed a new real-time algorithm for tracking the needle tip. This algorithm is used to detect the needle and it provides a feedback signal as the feedback variable. Extracting the needle tip position from theultrasoundimages by using this algorithm and also verifying that the needle tip is not close to any forbidden regions.
- 3. International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056 Volume: 05 Issue: 12 | Dec 2018 www.irjet.net p-ISSN: 2395-0072 © 2018, IRJET | Impact Factor value: 7.211 | ISO 9001:2008 Certified Journal | Page 43 3. CONCLUSION Nowadays robotics in the medical field with medical image processing is a highly active research area.Eventhoughmany ideas and concepts have beenproposedtheoretically,theyare not actually implemented in the real word environment.Ifwe can develop a fully automatic medical robotic environment with précised medical image processing, it can help us to suppress the faults in treatment and can improve the quality of life of a patient. REFERENCES [1] P. Chatelain, A. Krupa, and M. Marchal, “Real-time needle detection andtrackingusinga visuallyservoed 3D ultrasound probe,” in Proc. IEEE Int. Conf. Robot. Autom., May 2013, pp. 1676–1681. [2] E. M. Boctor, M. A. Choti, E. C. Burdette, and R. J. Webster, III, “Threedimensional ultrasound-guided roboticneedle placement: An experimental evaluation,” Int. J. Med. Robot. Comput. Assist. Surgery, vol. 4, no. 2, pp. 180–191, 2008. [3] G. J. Vrooijink, M. Abayazid, and S. Misra, “Real-time threedimensional flexible needle tracking using two- dimensional ultrasound,” in Proc. IEEE Int. Conf. Robot. Autom., May 2013, pp. 1688–1693. [4] G. J. Vrooijink, M. Abayazid, and S. Misra, “Real-time threedimensional flexible needletrackingusingtwo- dimensional ultrasound,” in Proc. IEEE Int. Conf. Robot. Autom., May 2013, pp. 1688–1693. [5] M. Kaya and O. Bebek, “Needle localization using Gabor filtering in 2D ultrasoundimages,”in Proc.IEEEInt.Conf. Robot. Autom. (ICRA), May/Jun.2014,pp.4881–4886. G. J. Vrooijink, M. Abayazid, and S. Misra, “Real-time threedimensional flexible needle tracking using two- dimensional ultrasound,” in Proc. IEEE Int. Conf. Robot. Autom., May 2013, pp. 1688–1693. [6] M. Bonfè et al., “Towards automated surgical robotics: A requirements engineering approach,” in Proc. 4th IEEE RAS EMBS Int. Conf. Biomed. Robot. Biomechatronics (BioRob), Jun. 2012, pp. 56–61. BIOGRAPHIES Neethu S Kumar received the Bachelor’s Degree in Computer Science and Engineering fromSree Buddha college of Engineering, Kerala, India in 2017. She is currently pursing Master’s Degree in Computer Science and Engineering in Sree Buddha College of Engineering, Kerala, India. Prof. Supriya L P. has more than 12 years of experience in teaching, Research and industry. She completed her post-graduation in Computer Science from Madras University in 2003. She received her M.Phil. Fromthedepartmentof computer Science in 2007, Annamalai University specialized in image processing .She received her Master of Engineering (M.E) degree from School of Computing, Sathyabama University, Computer Science and Engineering in 2009. At present she is pursuingherPhD. She started her career as a faculty of Computer Science in 2004 at Chennai. She has got a number of publications in conferences and Journals national/international.