Abstract
The study aimed to (ⅰ) examines whether quantitative and qualitative digital analysis of hepatic ultrasound images can be used to detect fatty liver and grading its severity, (ⅱ) to estimate the concentration of serum β-hydroxybutyrate content in normal and diseased animals. A total of 50 buffaloes (15 clinically normal and 35 suffered from decreased milk production, loss of appetite, and loss of body weight) 2-4 weeks after parturition were studied. Buffaloes were examined by real-time ultrasound using a 3.5 MHz convex probe. Ultrasound images were saved for qualitative and quantitative analysis, using computer aid Fatty-Liver software (programmed in Matlab language). Based on the digital analysis of ultrasound images, the diseased buffaloes were classified as mild (n=20), moderate (n=7) and severe (n=8) fatty liver affection. Results indicated that the concentration of β-hydroxybutyrate estimated via ELISA were 0.409, 0.735, 0.923, 1.708 mmol/dL in normal, mild, moderate, and severe diseased buffaloes respectively. However, a significant difference has been encountered among normal and diseased animals. It has been concluded that buffaloes at Mosul suffered from fatty liver and digital analysis of ultrasound images was a suitable method for clinical diagnosis, furthermore, estimation of β-hydroxybutyrate was a suitable method for laboratory diagnosis.
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Ultrasound image analysis for detection of fatty liver and grading its severity in buffaloes at Mosul, Iraq
Ziena Hazim Hasan1, Osamah Muwaffag Al-iraqi1, Ielaf O. Abdul Majjed2
1Department of Medicine, College of Veterinary Medicine, University of Mosul, 2Department of Computer Sciences, College of Computer Sciences and Mathematics, University of Mosul
zena.vmp17@student.uomosul.edu.iq, 0000-0003-3673
osamamuwafaq@uomosul.edu.iq, 0000-0001-8229, corresponding
ie_osamah@uomosul.edu.iq, 000-0002-8520
Abstract
The study aimed to (ⅰ) examines whether quantitative and qualitative digital analysis of hepatic ultrasound images can be used to detect fatty liver and grading its severity, (ⅱ) to estimate the concentration of serum β-hydroxybutyrate content in normal and diseased animals. A total of 50 buffaloes (15 clinically normal and 35 suffered from decreased milk production, loss of appetite, and loss of body weight) 2-4 weeks after parturition were studied. Buffaloes were examined by real-time ultrasound using a 3.5 MHz convex probe. Ultrasound images were saved for qualitative and quantitative analysis, using computer aid Fatty-Liver software (programmed in Matlab language). Based on the digital analysis of ultrasound images, the diseased buffaloes were classified as mild (n=20), moderate (n=7) and severe (n=8) fatty liver affection. Results indicated that the concentration of β-hydroxybutyrate estimated via ELISA were 0.409, 0.735, 0.923, 1.708 mmol/dL in normal, mild, moderate, and severe diseased buffaloes respectively. However, a significant difference has been encountered among normal and diseased animals. It has been concluded that buffaloes at Mosul suffered from fatty liver and digital analysis of ultrasound images was a suitable method for clinical diagnosis, furthermore, estimation of β-hydroxybutyrate was a suitable method for laboratory diagnosis.
Keywords: Buffaloes, Fatty liver, Ultrasound analysis, β-hydroxybutyrate
تحلیل صور الموجات فوق الصوتیة للکبد الدهنی فی الجاموس فی الموصل، العراق
زینة حازم حسن1، أسامة موفق العراقی1 و إیلاف أسامة عبد المجید2
1فرع الطب الباطنی، کلیة الطب البیطری، 2قسم علوم الحاسبات، کلیة علوم الحاسبات والریاضیات، جامعة الموصل
الخلاصة
هدفت الدراسة إلى معرفة إمکانیة استخدام التحلیل الرقمی النوعی والکمی لصور الکبد بالموجات فوق الصوتیة للکشف عن الکبد الدهنی وتصنیف شدته ولتقدیر ترکیز محتوى بیتاهیدروکسی بیوتریت فی الدم فی الحیوانات السلیمة والمریضة. تمت دراسة 50 جاموسة (15 طبیعیة سریریا و 35 تعانی من انخفاض إنتاج الحلیب وفقدان الشهیة وفقدان وزن الجسم) بعد 2-4 أسابیع من الولادة. تم فحص الجاموس بواسطة الموجات فوق الصوتیة باستخدام مسبار محدب 3.5 میجا هرتز. تم حفظ صور الموجات فوق الصوتیة للتحلیل النوعی والکمی، باستخدام برنامج الکبد الدهنی (یعتمد لغة البرمجة مات لاب). بناء على التحلیل الرقمی لصور الموجات فوق الصوتیة، تم تصنیف الجاموس المصاب بالکبد الدهنی إلى 20 إصابة خفیفة و7متوسطة و 8 شدیدة. أشارت النتائج إلى أن ترکیز بیتاهیدروکسی بیوتریت بواسطة اختبار المقایسة المناعی المرتبط بالإنزیم کان 0.409 و 0.735 و 0.923 و 1.708 ملیمول/دیسیلتر فی الجاموس الطبیعی، والجاموس المصاب إصابة خفیف، متوسطة وشدیدة على التوالی ومع وجود فرق معنوی بین الحیوانات السلیمة والمریضة. وقد تم التوصل إلى أن الجاموس فی الموصل یعانی من الکبد الدهنی وان التحلیل الرقمی للصور بالموجات فوق الصوتیة کانت طریقة مناسبة للتشخیص السریری، علاوة على ذلک کان تقدیر بیتاهیدروکسی بیوتریت طریقة مناسبة للتشخیص المختبری.
Introduction
Fatty liver is a metabolic disease that affect ruminants and occur when the animal suffered from negative energy balance mainly after parturition , however, about 50% of cow affected at 4 week postpartum resulting in losses in about 60 million US dollar (1). The disease cause interference with animal production, fertility and performance (2). Cattle commonly affected with fatty liver because of having less ability to export the accumulated fat in their hepatocyte related to decrease hepatic activity and thus resulted in an increase of the non-esterified fatty acid, acetoacetate, and β-hydroxybutyrate (3). Fasciolosis considered as important cause of liver damage (4,5) which could predispose to fatty liver syndrome (6). Fatty liver is defined as the percentage of liver lipid or Triacylglycerol (TGA), which is associated with disrupted well-being, health status and reproductive performance of dairy cows and early culling of diseased animals. Fatty liver causes many defects in liver parenchyma such as fatty cysts, increased hepatocytes size, damage of mitochondria, nuclei volume compression and the decrease of organelles. The severity of Fatty liver depends on the accumulation extension of TGA and can be classified to mild, moderate, and severe (2).
The diagnosis of fatty liver depends on the triacylglycerol concentration by using biopsy and other laboratory examination methods, including the biochemical analysis, however, it has been shown that, ELISA are more useful for detecting β-hydroxybutyrate (BHB) and Non-esterified fatty acids (NEFA) (7,8). The liver consists of fibrofatty tissues, which give parallel echogenicities by ultrasound (9). Ultrasound as a non-invasive technique, which was recently used for clinical detection of many diseases like left displaced abomasum (LDA) (10), fatty abscess (11), fatty liver in camels (12), dairy cattle and buffaloes (6,13, 14). The real-time images of the liver give a benefit of ultrasound for showing actual hepatic parenchymal changes (15). Digital analysis has the highest sensitivity, specificity, accuracy and positive and negative predictive values for diagnosing the fatty liver followed by ultrasonography (16). The quantitative analysis characterized by increase echogenicity of liver parenchyma, deep attenuation and vascular blurring (15), while qualitative analysis relies on the computer-aided digital analysis which represents the future of ultrasound (17,18). Moreover, recently, there has been a new quantification method of liver fat, conducted by using Magnetic Resonance Imaging (19). However, the buffaloes in Mosul suffer from metabolic disorders (20) and some of them have low reproductive performance (21,22) hence, the current study was conducted to detect the fatty liver and grading its severity in buffaloes using quantitative image analysis, and to evaluate the serum β-hydroxybutyrate concentration using ELISA.
Materials and methods
Animals
The current study was conducted to examine 50 female buffaloes 4-12 years and 2-4 weeks after calving from different areas of Mosul governorate, Iraq, form the period started in September 2020 to February 2021. Thirty-five buffaloes show signs of loss of appetite and decrease in both of milk production and body weight loss were selected. Furthermore, 15 clinically normal buffaloes were selected as the control group.
Ultrasonographic examination
The liver was scanned by using a KX5100VET real time ultrasound portable machine at the standing position after controlling the animal without using anesthesia. Machine setting was fixed for all animals (Gain: 90, Near: -15, Far: 00, Dynamic: 66). On the right side the 10th to 12th intercostal space was clipped then transmission gel was applied and examination was performed from the dorsal to the ventral by using a 3.5 MHz convex probe (15).
Digital analysis
Pictures were saved to be used for quality analysis normal liver, mild, moderate and severe fatty liver were considered according to Komeilian et al. (23) and quantity analysis was conducted using Matlab 2020a programming language, in which the image is analyzed, and the required location of the sonar images was determined based on the normal images. Image processing methods were employed to transform the colored images into gray, then white and black and to calculate the percentage of white color that indicates injury. (0=normal, 1-10=mild, 11-20 =moderate, 21-50=severe); the higher the percentage, the higher the injury was. The system was linked to an Excel program that stores the outputs, and this file can be opened whenever a new image is analyzed. Thus, a database was built for all the tested cases.
Enzyme-linked immunosorbent assay
Blood samples (5 ml) of were collected from the milk vein, then serum was separated using gel tube. The level of β-hydroxybutyrate (BHB) was estimated by means of using ELISA kit according to the manufacture procedure (bioassay technology laboratory, china).
Statistical analysis
Data of ELISA were offered as a mean ± standard error and the comparison between diseased and control animals was conducted by using IBM SPSS statistic 21.
Results
Results indicated that out of 50 buffaloes, 15 animals were normal and by the use of ultrasound, they showed normal liver characterized by homogenously equally-distributed weak echoes with clearly visible small and large vessels (Figure 1). On the contrary, the other 35 buffaloes suffered from a decrease in milk production, loss of appetite after parturition. They had a fatty liver and the digital image and qualitative analysis of ultrasound revealed a total of 35 diseased buffaloes. Results indicated that, 20 buffaloes suffered from mild fatty liver and showed a mild increase in parenchyma echogenicity, unclear small vessels, and clear large vessels (Figure 2), while 8 buffaloes had a moderate fatty liver Where it showed an increase in echogenicity with unclear the small and large vessels (Figure 3). Furthermore, 7 buffaloes suffered from the severe fatty liver in which the parenchyma was severely echogenic and the edge is barely visible (Figure 4).
Figure 1: Ultrasonogram of liver from the twelfth intercostal space. The abdominal wall (1), liver (2), small vessel (3), portal vein (4), ventral edge of liver (arrow), Ds: dorsal, Vt: ventral.
Figure 2: Ultrasonogram of the liver of a buffalo with mild fatty liver. The abdominal wall (1), liver (2), portal vein (3), Ds: dorsal, Vt: ventral.
Figure 3: Ultrasonogram of the liver of a buffalo with moderate fatty liver. The abdominal wall (1), liver (2), portal vein (3), Ds: dorsal, Vt: ventral.
Figure 4: Ultrasonogram of the liver of a buffalo with sever fatty liver. The abdominal wall (1), liver (2), Ds: dorsal, Vt: ventral.
Quantitative analysis of total 35 abnormal hepatic images showed 20, 7 and 8 mild, moderate and severe fatty liver respectively, depending on the percentage of white dots in the hepatic image, (Figure 5). From the results of ELISA, there were a significant difference at P
Table 1: Concentration of BHB in normal and diseased buffaloes
Buffaloes |
BHB concentration (Mean±SD) |
||
Normal |
0.409±0.01 |
||
Diseased |
0.995±0.02 * |
||
Mild (N=20) |
Moderate (N=7) |
Sever (N=8) |
|
0.735±0.20a |
0.923±0.01b |
1.708±0.44c |
* Significant at p<0.05, different letter means significant at P<0.05.
Figure 5: Qualitative image digital analysis of hepatic parenchyma by using fatty-liver software. Red rectangle: area of analysis.
Discussion
Results of the current study indicated that Iraqi buffaloes have developed fatty liver and show clinical signs of decrease performance, these results are similar to those recorded by Abdelaal et al. (13), fatty liver disease cause severe economic losses due to decrease animals production with morbidity rate may reach 25% and case fatality rate about 90% (3).
There are many methods for diagnosis fatty liver as biochemical analysis, liver biopsy and image analysis (16) the accuracy of biochemical tests may have affected by damage of other tissues or organ lead to valid results, furthermore the liver biopsy should perform with animal under anesthesia and can produce sever liver damage, on the other hand the ultrasonography provide actual hepatic lesions by using real time imaging (24). Results of the qualitative ultrasound image analysis revealed that 20, 8 and 7 buffaloes showed mild, moderate and severe fatty liver respectively, these results agree with (15). The most characteristic changes by ultrasound are the bright pattern, blurring of edges, vascular blurring and deep attenuation (16). The change in hepatic echo patterns due to the presence of fat, which causes difference in hepatic structure, these changes can easily diagnose by ultrasound with a sensitivity of about 90% and a very low false positive (25).
Results of quantitative image analysis show that 35 abnormal images of hepatic parenchyma include 20 mild, 8 moderate and 7 severe fatty liver. These results are in agreement with (6), Buffaloes did not have early pathological changes in their hepatic parenchyma and this made it more accurate to detect mild cases compared to the qualitative analysis and so it should consider a practicable method for detecting fatty liver in buffaloes (13). The estimates of BHB consider as an efficient method for detection of energy balance in cows and buffaloes (2). ELIZA results shows a significant increase in BHB level in diseased buffalo 0.995 mmol/L compared to control group 0.409 mmol/L and these results are consistent with Tharwat (15), NEFA begin increasing from day of parturition due to stress of birth and reach a highest level during the first month post parturition which indicate inability of liver to utilize these metabolites, on the other hand a feeding low quality or quantity diet considered an important predisposing factor (3). From results of ELISA, there were three levels of fatty liver disease in Iraqi female buffaloes and most of them 20 (75.14%) animals within the mild level, this result agrees with Tharwat (15) the difference in these three levels depend on the type of feeding and management practice.
Conclusion
This study indicates that the use of ELIZA can predicts fatty liver stages at laboratory and most of buffaloes have a mild form, which makes clinical diagnosis more difficult practically. Therefore, the use of ultrasound as a noninvasive technique provide an optimal diagnosis of fatty liver and can detect the severity by use Fatty_Liver software.
Acknowledgement
This article was supported by the College of Veterinary Medicine, University of Mosul, Iraq. The authors extend their sincere thanks and gratitude to the Deanship of the College of Veterinary Medicine, University of Mosul for their support in the completion of this study.
Conflict of interest
The authors declare that there are no conflicts of interest regarding the publication of this manuscript.
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