Research on algorithms of uterine contraction curve analysis and its real-time status identification_Journal of Biomedical Engineering

Authors：

LIU Gaochao ,  LU Yaosheng , LIN Zidong , GUO Lirui , LI Xiaodong

Department of Electronic Engineering, College of Information Science and Technology, Jinan University, Guangzhou 510632, P.R.China;

Corresponding author：

LU Yaosheng, Email: tluys@jnu.edu.cn

Keywords：

uterine contraction status; baseline estimation; finite state machines; real-time identification

DOI：

10.7507/1001-5515.201610021

Video：

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Abstract Full text Figures/Tables Video References Cited by

Identification of real-time uterine contraction status is very significant to labor analgesia, but the traditional uterine contraction analysis algorithms and systems cannot meet the requirement. According to the situations mentioned above, this paper designs a set of algorithms for the real-time analysis of uterine contraction status. The algorithms include uterine contraction signal preprocessing, uterine contraction baseline extraction based on histogram and linear iteration and an algorithm for the real-time analysis of uterine contraction status based on finite state machines theory. It uses the last uterine status and a series of state transfer conditions to identify the current uterine contraction status, as well as a buffer mechanism to avoid false status transitions. To evaluate the performance of the algorithm, we compare it with an existing uterine contraction analysis algorithm used in the electronic fetal monitor. The experiments show that our algorithm can analyze the uterine contraction status while monitoring the uterine contraction signal in a real-time. Its sensitivity reaches 0.939 9 and its positive predictive value is 0.869 3, suggesting that the algorithm has high accuracy and meets the need of clinical monitoring.

Citation： LIU Gaochao, LU Yaosheng, LIN Zidong, GUO Lirui, LI Xiaodong. Research on algorithms of uterine contraction curve analysis and its real-time status identification. Journal of Biomedical Engineering, 2017, 34(5): 738-744. doi: 10.7507/1001-5515.201610021 Copy

1.	Vallejo M C, Firestone L L, Mandell G L, et al. Effect of epidural analgesia with ambulation on labor duration. Anesthesiology, 2001, 95(4): 857-861.
2.	Zagami S E, Golmakani N, Saadatjoo S R, et al. The shape of uterine contractions and labor progress in the spontaneous active labor. Iran J Med Sci, 2015, 40(2): 98-103.
3.	Klossner N J. Introductory maternity and pediatricnursing. Lippincott Williams & Wilkins, 2006. 176-177.
4.	Ricci S S, Kyle T, Maternity and pediatric nursing. Lippincott Williams&wilkins, 2009: 370-373.
5.	邓松波, 陆尧胜, 方堃, 等. 生物反馈式经皮神经电刺激分娩镇痛系统的研制. 生物医学工程学杂志, 2015, 32(3): 667-6720.
6.	Kaplan B, Rabinerson D, Lurie S, et al. Transcutaneous electrical nerve stimulation(TENS)for adjuvant pain-relief during labor and delivery. Int J GynaecolObstet, 1998, 60(3): 251-255.
7.	Bedwell C, Dowswell T, Neilson J P, et al. The use of transcutaneous electrical nerve stimulation (TENS) for pain relief in Labour: a review of the evidence. Midwifery, 2011, 27(5): e141-e148.
8.	Horoba K, Matonia A, Jezewski J, et al. Analysis of uterine contraction activity using two ways of signal acquisition//XI Conference Medical Informatics&Technologies, 2006: 199-204.
9.	Georgieva A, Payne S J, Redman C. Computerised electronic foetal heart rate monitoring in Labour: automated contraction identification. Med BiolEngComput, 2009, 47(12): 1315-1320.
10.	杨建平, 肖开选. 一种评价宫缩强度的小波能量值分析方法. 生物医学工程学杂志, 2012, 29(1): 80-830.
11.	van de Laar J. Kierkels J J M. Automatic analysis of uterine activity signals and application for enhancement of labor and delivery experience, WO2014/045221. A1. 2014. 03. 27.
12.	Huang Zifang, Shyu M L, Tien J M, et al. Prediction of uterine contractions using Knowledge-Assisted sequential pattern analysis. IEEE Trans Biomed Eng, 2013, 60(5): 1290-1297.
13.	Lu Y, Bao L, Lu C, et al. A computer-aided analyzing system for fetal monitoring parameters//2010 3rd International Conference on Biomedical Engineering and Informatics. Yantai, China, 2010: 684-688.
14.	Gorry P A. General least-squares smoothing and differentiation by the convolution(Savitzky-Golay)method. Anal Chem, 1990, 62(6): 570-573.
15.	Dawes G S, Houghton C R S, Redman C W G. Baseline in human fetal heart‐rate records. Br J ObestetGynaecol, 1982, 89(4): 270-275.
16.	Mantel R, van Geijn H P, Caron F M, et al. Computer analysis of antepartum fetal heart rate: 1. Baseline determination. Int J Biomed Comput, 1990, 25(4): 261-272.
17.	Blumensath A, Grädel E. Finite presentations of infinite structures: Automata and interpretations. Theory of Computing Systems, 2004, 37(6): 641.
18.	Ayres-de-Campos D, Bernardes J, Garrido A, et al. SisPorto 2.0: a program for automated analysis of cardiotocograms. JMatern Fetal Med, 2000, 9(5): 311-318.

1. Vallejo M C, Firestone L L, Mandell G L, et al. Effect of epidural analgesia with ambulation on labor duration. Anesthesiology, 2001, 95(4): 857-861.
2. Zagami S E, Golmakani N, Saadatjoo S R, et al. The shape of uterine contractions and labor progress in the spontaneous active labor. Iran J Med Sci, 2015, 40(2): 98-103.
3. Klossner N J. Introductory maternity and pediatricnursing. Lippincott Williams & Wilkins, 2006. 176-177.
4. Ricci S S, Kyle T, Maternity and pediatric nursing. Lippincott Williams&wilkins, 2009: 370-373.
5. 邓松波, 陆尧胜, 方堃, 等. 生物反馈式经皮神经电刺激分娩镇痛系统的研制. 生物医学工程学杂志, 2015, 32(3): 667-6720.
6. Kaplan B, Rabinerson D, Lurie S, et al. Transcutaneous electrical nerve stimulation(TENS)for adjuvant pain-relief during labor and delivery. Int J GynaecolObstet, 1998, 60(3): 251-255.
7. Bedwell C, Dowswell T, Neilson J P, et al. The use of transcutaneous electrical nerve stimulation (TENS) for pain relief in Labour: a review of the evidence. Midwifery, 2011, 27(5): e141-e148.
8. Horoba K, Matonia A, Jezewski J, et al. Analysis of uterine contraction activity using two ways of signal acquisition//XI Conference Medical Informatics&Technologies, 2006: 199-204.
9. Georgieva A, Payne S J, Redman C. Computerised electronic foetal heart rate monitoring in Labour: automated contraction identification. Med BiolEngComput, 2009, 47(12): 1315-1320.
10. 杨建平, 肖开选. 一种评价宫缩强度的小波能量值分析方法. 生物医学工程学杂志, 2012, 29(1): 80-830.
11. van de Laar J. Kierkels J J M. Automatic analysis of uterine activity signals and application for enhancement of labor and delivery experience, WO2014/045221. A1. 2014. 03. 27.
12. Huang Zifang, Shyu M L, Tien J M, et al. Prediction of uterine contractions using Knowledge-Assisted sequential pattern analysis. IEEE Trans Biomed Eng, 2013, 60(5): 1290-1297.
13. Lu Y, Bao L, Lu C, et al. A computer-aided analyzing system for fetal monitoring parameters//2010 3rd International Conference on Biomedical Engineering and Informatics. Yantai, China, 2010: 684-688.
14. Gorry P A. General least-squares smoothing and differentiation by the convolution(Savitzky-Golay)method. Anal Chem, 1990, 62(6): 570-573.
15. Dawes G S, Houghton C R S, Redman C W G. Baseline in human fetal heart‐rate records. Br J ObestetGynaecol, 1982, 89(4): 270-275.
16. Mantel R, van Geijn H P, Caron F M, et al. Computer analysis of antepartum fetal heart rate: 1. Baseline determination. Int J Biomed Comput, 1990, 25(4): 261-272.
17. Blumensath A, Grädel E. Finite presentations of infinite structures: Automata and interpretations. Theory of Computing Systems, 2004, 37(6): 641.
18. Ayres-de-Campos D, Bernardes J, Garrido A, et al. SisPorto 2.0: a program for automated analysis of cardiotocograms. JMatern Fetal Med, 2000, 9(5): 311-318.

Journal of Biomedical Engineering

Research on algorithms of uterine contraction curve analysis and its real-time status identification

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