Full Text:
<5176>
Summary: 
<1788>
CLC number: TP309.7
On-line Access: 2024-08-27
Received: 2023-10-17
Revision Accepted: 2024-05-08
Crosschecked: 2021-06-16
Cited: 0
Clicked: 5859
Citations: Bibtex RefMan EndNote GB/T7714
Bio-inspired cryptosystem on the reciprocal domain: DNA strands mutate to secure health data
| ||||||||||||||
S. Aashiq Banu, Rengarajan Amirtharajan. Bio-inspired cryptosystem on the reciprocal domain: DNA strands mutate to secure health data[J]. Frontiers of Information Technology & Electronic Engineering, 2021, 22(7): 940-956.
@article{title="Bio-inspired cryptosystem on the reciprocal domain: DNA strands mutate to secure health data",
author="S. Aashiq Banu, Rengarajan Amirtharajan",
journal="Frontiers of Information Technology & Electronic Engineering",
volume="22",
number="7",
pages="940-956",
year="2021",
publisher="Zhejiang University Press & Springer",
doi="10.1631/FITEE.2000071"
}
%0 Journal Article
%T Bio-inspired cryptosystem on the reciprocal domain: DNA strands mutate to secure health data
%A S. Aashiq Banu
%A Rengarajan Amirtharajan
%J Frontiers of Information Technology & Electronic Engineering
%V 22
%N 7
%P 940-956
%@ 2095-9184
%D 2021
%I Zhejiang University Press & Springer
%DOI 10.1631/FITEE.2000071
TY - JOUR
T1 - Bio-inspired cryptosystem on the reciprocal domain: DNA strands mutate to secure health data
A1 - S. Aashiq Banu
A1 - Rengarajan Amirtharajan
J0 - Frontiers of Information Technology & Electronic Engineering
VL - 22
IS - 7
SP - 940
EP - 956
%@ 2095-9184
Y1 - 2021
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/FITEE.2000071
Abstract: Healthcare and telemedicine industries are relying on technology that is connected to the Internet. Digital health data are more prone to cyber attacks because of the treasure trove of personal data they possess. This necessitates protection of digital medical images and their secure transmission. In this paper, an encryption technique based on DNA mutated with Lorenz and Lü chaotic attractors is employed to generate high pseudo-random key streams. The proposed chaos-DNA cryptic system operates on the integer wavelet transform (IWT) domain and a bio-inspired crossover, mutation unit for enhancing the confusion and diffusion phase in an approximation coefficient. Finally, an XOR operation is performed with a quantised chaotic set from the developed combined attractors. The algorithm attains an average entropy of 7.9973, near-zero correlation with an NPCR of 99.642%, a UACI of 33.438%, and a keyspace of 10203. Further, the experimental analyses and NIST statistical test suite have been designed such that the proposed medical image encryption technique has the potency to withstand any statistical, differential, and brute force attacks.
[1]Aashiq Banu S, Amirtharajan R, 2020. A robust medical image encryption in dual domain: chaos-DNA-IWT combined approach. Med Biol Eng Comput, 58:1445-1458.
[2]Al-Hazaimeh OM, Al-Jamal MF, Alhindawi N, et al., 2017. Image encryption algorithm based on Lorenz chaotic map with dynamic secret keys. Neur Comput Appl, 31(7):2395-2405.
[3]Aqeel-ur-Rehman, Liao XF, Hahsmi MA, et al., 2018. An efficient mixed inter-intra pixels substitution at 2bits-level for image encryption technique using DNA and chaos. Optik, 153:117-134.
[4]Arumugham S, Rajagopalan S, Rayappan JBB, et al., 2018. Networked medical data sharing on secure medium—a web publishing mode for DICOM viewer with three layer authentication. J Biomed Inform, 86:90-105.
[5]Belazi A, El-latif AAA, Belghith S, 2016. A novel image encryption scheme based on substitution-permutation network and chaos. Signal Process, 128:155-170.
[6]Belazi A, El-Latif AAA, Diaconu AV, et al., 2017. Chaos-based partial image encryption scheme based on linear fractional and lifting wavelet transforms. Opt Laser Eng, 88:37-50.
[7]Belazi A, Talha M, Kharbech S, et al., 2019. Novel medical image encryption scheme based on chaos and DNA encoding. IEEE Access, 7:36667-36681.
[8]Bolourian Haghighi B, Taherinia AH, Mohajerzadeh AH, 2019. TRLG: fragile blind quad watermarking for image tamper detection and recovery by providing compact digests with optimized quality using LWT and GA. Inform Sci, 486:204-230.
[9]Chai XL, Gan ZH, Yuan K, et al., 2019. A novel image encryption scheme based on DNA sequence operations and chaotic systems. Neur Comput Appl, 31(1):219-237.
[10]Chen YC, Tang CM, Ye RS, 2020. Cryptanalysis and improvement of medical image encryption using high-speed scrambling and pixel adaptive diffusion. Signal Process, 167:107286.
[11]Dagadu JC, Li JP, Addo PC, 2019a. An image cryptosystem based on pseudorandomly enhanced chaotic DNA and random permutation. Multim Tools Appl, 78(17):24979-25000.
[12]Dagadu JC, Li JP, Aboagye EO, 2019b. Medical image encryption based on hybrid chaotic DNA diffusion. Wirel Pers Commun, 108(1):591-612.
[13]Daubechies I, Sweldens W, 1998. Factoring wavelet transforms into lifting steps. J Four Anal Appl, 4(3):247-269.
[14]Devi RS, Thenmozhi K, Rayappan JBB, et al., 2019. Entropy influenced RNA diffused quantum chaos to conserve medical data privacy. Int J Theor Phys, 58(6):1937-1956.
[15]Dhall S, Pal SK, Sharma K, 2018. Cryptanalysis of image encryption scheme based on a new 1D chaotic system. Signal Process, 146:22-32.
[16]Diaconu AV, 2016. Circular inter–intra pixels bit-level permutation and chaos-based image encryption. Inform Sci, 355-356:314-327.
[17]Dzwonkowski M, Rykaczewski R, 2019. Secure quaternion Feistel cipher for DICOM images. IEEE Trans Image Process, 28(1):371-380.
[18]Farah MAB, Guesmi R, Kachouri A, et al., 2020. A novel chaos based optical image encryption using fractional fourier transform and DNA sequence operation. Opt Laser Technol, 121:105777.
[19]Fridrich J, 1998. Symmetric ciphers based on two-dimensional chaotic maps. Int J Bifurc Chaos, 8(6):1259-1284.
[20]Ghebleh M, Kanso A, 2019. A novel efficient image encryption scheme based on chained skew tent maps. Neur Comput Appl, 31(7):2415-2430.
[21]Guan MM, Yang XL, Hu WS, 2019. Chaotic image encryption algorithm using frequency-domain DNA encoding. IET Image Process, 13(9):1535-1539.
[22]Hua ZY, Yi S, Zhou YC, 2018. Medical image encryption using high-speed scrambling and pixel adaptive diffusion. Signal Process, 144:134-144.
[23]Kumar S, Panna B, Jha RK, 2019. Medical image encryption using fractional discrete cosine transform with chaotic function. Med Biol Eng Comput, 57(11):2517-2533.
[24]Liu H, Zhao B, Huang LQ, 2019a. A novel quantum image encryption algorithm based on crossover operation and mutation operation. Multim Tools Appl, 78(14):20465-20483.
[25]Liu H, Zhao B, Huang LQ, 2019b. A remote-sensing image encryption scheme using DNA bases probability and two-dimensional logistic map. IEEE Access, 7:65450-65459.
[26]Liu JZ, Tang SS, Lian J, et al., 2019. A novel fourth order chaotic system and its algorithm for medical image encryption. Multidim Syst Sign Process, 30(4):1637-1657.
[27]Liu ZT, Wu CX, Wang J, et al., 2019. A color image encryption using dynamic DNA and 4-D memristive hyper-chaos. IEEE Access, 7:78367-78378.
[28]Luo J, Qu SC, Xiong ZL, et al., 2019. Observer-based finite-time modified projective synchronization of multiple uncertain chaotic systems and applications to secure communication using DNA encoding. IEEE Access, 7:65527-65543.
[29]Luo Y, Du M, Liu J, 2015. A symmetrical image encryption scheme in wavelet and time domain. Commun Nonl Sci Numer Simul, 20(2):447-460.
[30]Mahdi MSR, Al Aziz MM, Alhadidi D, et al., 2019. Secure similar patients query on encrypted genomic data. IEEE J Biomed Health Inform, 23(6):2611-2618.
[31]Moafimadani SS, Chen YC, Tang CM, 2019. A new algorithm for medical color images encryption using chaotic systems. Entropy, 21(6):577.
[32]Mohamed Parvees MY, Abdul Samath J, Parameswaran Bose B, 2017. Medical images are safe—an enhanced chaotic scrambling approach. J Med Syst, 41(10):167.
[33]Praveenkumar P, Amirtharajan R, Thenmozhi K, et al., 2015. Medical data sheet in safe havens—a tri-layer cryptic solution. Comput Biol Med, 62:264-276.
[34]Premkumar R, Anand S, 2019. Secured and compound 3-D chaos image encryption using hybrid mutation and crossover operator. Multim Tools Appl, 78(8):9577-9593.
[35]Ravichandran D, Praveenkumar P, Balaguru Rayappan JB, et al., 2016. Chaos based crossover and mutation for securing DICOM image. Comput Biol Med, 72:170-184.
[36]Ravichandran D, Praveenkumar P, Rayappan JBB, et al., 2017. DNA chaos blend to secure medical privacy. IEEE Trans NanoBiosci, 16(8):850-858.
[37]Rehman AU, Wang HW, Shahid MMA, et al., 2019. A selective cross-substitution technique for encrypting color images using chaos, DNA rules and SHA-512. IEEE Access, 7:162786-162802.
[38]Stalin S, Maheshwary P, Shukla PK, et al., 2019. Fast and secure medical image encryption based on non linear 4D logistic map and DNA sequences (NL4DLM_DNA). J Med Syst, 43(8):267.
[39]Suri S, Vijay R, 2020. A Pareto-optimal evolutionary approach of image encryption using coupled map lattice and DNA. Neur Comput Appl, 32:11859-11873.
[40]Wang XY, Zhang JJ, Cao GH, 2019. An image encryption algorithm based on zigzag transform and LL compound chaotic system. Opt Laser Technol, 119:105581.
[41]Yosefnezhad Irani B, Ayubi P, Amani Jabalkandi F, et al., 2019. Digital image scrambling based on a new one-dimensional coupled sine map. Nonl Dynam, 97(4):2693-2721.
[42]Zhang XC, Zhou Z, Niu Y, 2018. An image encryption method based on the feistel network and dynamic DNA encoding. IEEE Photon J, 10(4):3901014.
ORCID: 
Open peer comments: Debate/Discuss/Question/Opinion
<1>