Makram, M., Eskander, F., Khalil, F., Salem, N. (2023). Assessment of Serum Aldo-Keto Reductase Family 1 Member B10 for Early Diagnosis of Hepatocellular Carcinoma Patients in Suez Canal University Hospital, Egypt . Afro-Egyptian Journal of Infectious and Endemic Diseases, 13(2), 90-100. doi: 10.21608/aeji.2023.193103.1281
Mariam M Makram; Fikry G Eskander; Fawzy A Khalil; Naglaa E Salem. "Assessment of Serum Aldo-Keto Reductase Family 1 Member B10 for Early Diagnosis of Hepatocellular Carcinoma Patients in Suez Canal University Hospital, Egypt ". Afro-Egyptian Journal of Infectious and Endemic Diseases, 13, 2, 2023, 90-100. doi: 10.21608/aeji.2023.193103.1281
Makram, M., Eskander, F., Khalil, F., Salem, N. (2023). 'Assessment of Serum Aldo-Keto Reductase Family 1 Member B10 for Early Diagnosis of Hepatocellular Carcinoma Patients in Suez Canal University Hospital, Egypt ', Afro-Egyptian Journal of Infectious and Endemic Diseases, 13(2), pp. 90-100. doi: 10.21608/aeji.2023.193103.1281
Makram, M., Eskander, F., Khalil, F., Salem, N. Assessment of Serum Aldo-Keto Reductase Family 1 Member B10 for Early Diagnosis of Hepatocellular Carcinoma Patients in Suez Canal University Hospital, Egypt . Afro-Egyptian Journal of Infectious and Endemic Diseases, 2023; 13(2): 90-100. doi: 10.21608/aeji.2023.193103.1281
Assessment of Serum Aldo-Keto Reductase Family 1 Member B10 for Early Diagnosis of Hepatocellular Carcinoma Patients in Suez Canal University Hospital, Egypt
1Department of Clinical and Chemical Pathology. Faculty of Medicine, Suez Canal University, Egypt.
2Department of Internal Medicine, Faculty of Medicine, Suez Canal University, Egypt.
Abstract
Background and study aim: Hepatocellular carcinoma is a challenging malignancy of global importance as it is considered the 2nd cause of mortality worldwide. This study aimed at finding additional blood biomarkers for hepatocellular carcinoma that may help in early diagnosis in Egyptian patients. Methods: This comparative analytical study was conducted at the Clinical Pathology laboratory at Suez Canal University Hospital, Ismailia. A total sample of 88 participants were recruited by simple random sampling and divided into 4 equal groups, early and intermediate, late-stage HCC, cirrhotic patients without HCC and apparently healthy control. All study groups were subjected to an interview questionnaire and laboratory investigations like ALT, AST, PT, albumin, total bilirubin, INR, AFP and AKR1B10. Results: The mean age was 63.6± 5.1 years 67.6± 5.9 years, 65.1± 4.1 years and 64.9± 7.0 years among four groups respectively. Males were higher among the HCC group. AFP showed significant differences between the late HCC and three other groups. AKR1B10 was significantly higher in early to moderate HCC than the other three groups. AKR1B10 could significantly detect early to moderate hepatocellular carcinoma with sensitivity of 72.7%, specificity of 89.4% at cut off value ≥ 0.91ng/ml. While AFP had a lower diagnostic value for detecting early to moderate hepatocellular carcinoma as it had sensitivity of 63.6%, specificity of 74.2% at cut off value ≥6.9 ng/ml. Conclusion: AKR1B10 can help in early recognition of hepatocellular carcinoma in highly suspicious patients with good diagnostic value.
Highlights
AKR1B10 could significantly detect early to moderate hepatocellular carcinoma with sensitivity of 72.7%, specificity of 89.4% at cut off value ≥ 0.91ng/ml .
AKR1B10 can help in early recognition of hepatocellular carcinoma in highly suspicious patients with good diagnostic value.
Given that it is the 2nd cause that leading to mortality globally and the 6th most frequent cancer, hepatocellular carcinoma (HCC) is a difficult cancer of major global significance[1]. In Egypt, hepatocellular carcinoma is the 4th most prevalent cancer. Egypt is the third in Africa and the fifteenth worldwide as most populous country [2].
Chronic hepatitis B and C virus infections, non-alcoholic fatty liver disease, excessive use of alcohol, a family history of the disease, being obese, diabetes mellitus type 2, and smoking are all risk factors for hepatocellular carcinoma. Other risk factors include a family history of the disease [3].
The most common known risk factor for hepatocellular carcinoma is cirrhotic liver especially that associated with virus B and C infection [4]. The actual important factors to make the prognosis of HCC better, is early detection of disease, because the treatment, which may be surgical resection or interventional radiology or liver transplantation ,will be more effective and benefitable than in the advanced stage [5].
There are many blood biomarkers for early diagnosis of HCC which are classified into genetic biomarkers, clinical biomarkers and protein biomarkers. Genetic biomarkers like circulating cell-free DNA, circular RNAs and microRNA, and clinical biomarkers like pre-albumin, D-Dimer, alanine transferase (ALT), activated partial thromboplastin time and mean platelet volume [6].
Protein biomarkers are classified into 3 groups: the traditional group, the emerging group and the autoantibody group. Unfortunately, none of the traditional groups are ideal in clinical diagnosis of HCC. But Aldo keto reductase family 1 member b10 (AKRF1MB10) ,which is one of the emerging groups, may show a promising diagnostic value in HCC [6,7]
Most people with early-stage HCC are asymptomatic, and liver function is unaffected. For surveillance, ultrasound (U/S) and serum alpha feto protein (AFP) level testing in blood are advised only for patients with high risk factors for HCC. The most often reported HCC biomarker worldwide is AFP [8].
As using U/S and AFP in diagnosis HCC is inaccurate because in early stage U/S could not determine benign from malignant nodules in the small cirrhotic liver , and not all patients are positive for AFP in this stage , so finding a promising biomarker is important for early diagnosis of HCC[9].
The Aldo-keto reductase superfamily includes the protein that is commonly referred to as AKR1B10. It is overexpressed in many other tumors besides HCC, such as breast cancer and cancer of lung, and it is expressed in the gastrointestinal tract. Other types of tumors, such as lung cancer, also express it [10].
As AKR1B10 may show a promising diagnostic value in Egypt, we estimated its level among HCC patients at Suez Canal University Hospital. So, this study aimed at Finding additional blood biomarkers for HCC that may help in early diagnosis in Egyptian patients with the main objectives To identify the role of serum (AKR1B10) among HCC patients and To estimate its sensitivity in early diagnosis of HCC.
PATIENTS AND METHODS
Study design: This was a comparative analytical cross-sectional study.
Study setting: Patients recruited from the hepatic outpatient clinic and oncology department of the Suez Canal University Hospital, Ismailia.
Study population: First group: early and intermediate stage HCC, second group: late-stage HCC, third group: cirrhotic liver patients without HCC. And fourth group: apparently healthy people.
Participants aged from 18 to 80 years for both gender. According to The Barcelona Clinic Liver Cancer (BCLC) Staging System, Group I includes very early, early, intermediate stage HCC. Group II includes advanced and terminal stage HCC. Regarding The Four-Stage Cirrhosis Classification System Group III includes patients with liver cirrhosis without HCC (including all stages of cirrhosis: compensated and decompensated). Group IV includes apparently healthy people. Participants who refused to participate were excluded from this study.
Sample size:
Using the following equation [11] with 95% confidence interval and 80% power:
σ = the estimate of the standard deviation=2.4 ng/ml [7].
µ1 = mean serum AKR1B10 level in HCC patients=3.27 ng/ml [7].
µ2 = mean serum AKR1B10 level in chronic hepatitis patients =1.24 ng/ml. [7]
So, the sample size equals 22 subjects per group, the total sample size equals 88 subjects.
The participants enrolled in this study by simple random sampling.
Data collection:
All study groups were subjected to interview questionnaire including sociodemographic data, present history: onset, course, duration of symptoms and past history and drug history.
Laboratory Investigations were done to all participants as Several biochemical markers and liver enzymes, such as alanine aminotransferase (ALT), international normalized ratio (INR), aspartate aminotransferase (AST), albumin, alpha-fetoprotein (AFP), total bilirubin and prothrombin time, and were measured and evaluated. In addition, the AKR1B10 concentration in the serum was determined using sandwich ELISA and an AKR1B10 ELISA kit.[12]
Preparations:
Before beginning the test, ensure that all of the reagents, standard solutions, and samples have been brought to room temperature. Additionally, determine how many test strips will be required for the procedure. Insert the strips into the frames so that they can be used. Standard volume of 50 μl is being poured into the standard well. After adding 10 μl of anti-AKR1B10 antibody to the sample wells and 50 μl of streptavidin-HRP to the sample wells, pour 40 μl of the sample into each sample well.
Statistical analysis
The data that were gathered were input into a computer, and then the Statistical Package for Social Science SPSS version 26 program which was used to perform statistical analysis on them. Using the Shapiro Walk test, we checked to see if the data followed a normal distribution. The qualitative data were presented using frequencies and relative percentages as their respective representations. To determine the degree of dissimilarity between the qualitative variables under consideration, a Chi-square test (2) was carried out. Calculating the difference between quantitative variable in ≥ 2 groups was accomplished with the help of a Kruskal Wallis test and one-way ANOVA, respectively for parametric and non-parametric variables. The relationship between two parametric and non-parametric quantitative variables was analyzed with the use of the Spearman correlation and Pearson correlation tests, respectively. ROC curve for the detection of validity in contrast to the cut-off point used to ensure diagnostic accuracy. If p value was < 0.05, it was considered significant.
RESULTS
A total sample of a total of 88 participants were classified into 4 equal groups: First group: early and intermediate stage HCC. Second group: late-stage HCC. Third group: cirrhotic liver without HCC. Fourth group: apparently healthy people. The mean age was 63.6± 5.1 years, 67.6± 5.9 years, 65.1± 4.1years and 64.9± 7.0 years among groups I, II, III and IV respectively, with no significant difference. The gender was comparable between the four groups: 81.8%, 72.7%, 77.3% and 54.5% males among the four groups respectively (Table 1).
According to our results, PT showed significant differences between the participating groups. INR was significantly higher among early and late HCC and liver cirrhosis groups than in control groups. Total bilirubin was significantly the highest among the late HCC group rather than the early HCC, cirrhotic and control groups. Albumin significantly differed between groups, but there was no significant difference between the early HCC group and the control group. AST was higher among early to moderate HCC, severe HCC and cirrhotic liver groups than control. Also, significant difference was reported between the early and late groups regarding AST. ALT was higher among early to moderate HCC, severe HCC and cirrhotic liver groups than control (Table 2).
AKR could significantly detect early to moderate hepatocellular carcinoma with sensitivity of 72.7%, specificity of 89.4% and area under the curve of 0.874 at cut off value ≥ 0.91. While AFP had a lower diagnostic value for detecting early to moderate hepatocellular carcinoma as it had sensitivity of 63.6%, specificity of 74.2% and area under the curve of 0.680 at cut off value ≥6.9 (Table 3, Figure 1).
AFP could significantly detect severe hepatocellular carcinoma with sensitivity of 68.2%, specificity of 69.7% and area under the curve of 0.794 at cut off value ≥ 4.35. While AKR had no statistical significant diagnostic value for severe hepatocellular carcinoma (Table 4, Figure 2).
AFP showed significant differences between severe HCC and three other groups; early, chronic liver disease and healthy groups. It was the highest level among HCC patients with a mild increase among liver cirrhosis patients. While AKR was significantly higher among groups with early to moderate HCC than the other three groups, severe HCC, chronic liver disease and control groups. Also, AKR was higher in the cirrhosis group than in controls (Table 5).
There was a weak (+) correlation between AKR and AFP (p=0.001). While AFP had a positive moderate correlation with PT, INR, total bilirubin, AST and ALT and a weak negative correlation with albumin. There was no significant correlation with other parameters. Regarding AKR, it had a significantly weak positive correlation with AST and ALT and no other significant correlation with other parameters (Table 6, Figure 3).
Table 1. Basic characteristics of the participated groups.
Variable
Early HCC
n= 22
Late HCC
n= 22
Cirrhosis without HCC
n= 22
Control
n=22
P value
Age (years)
Mean ± SD
63.6± 5.1
67.6± 5.9
65.1± 4.1
64.9± 7.0
0.136a
Gender
Female, n (%)
4 (18.2)
6 (27.3)
5 (22.7)
10 (45.5)
0.234b
Male, n (%)
18 (81.8)
16 (72.7)
17 (77.3)
12 (54.5)
a; Kruskal Wallis test, b; Chi square test; *p is significant at <0.05; HCC; Hepatocellular Carcinoma
Table 2. Comparing laboratory data between the participated groups.
Variable
Early HCC
Mean ± SD
Late HCC
Mean ± SD
Cirrhosis without HCC
Mean ± SD
Control
Mean ± SD
P value
PT (seconds)
15.5±3.6
17.4± 4.0
14.6± 2.5
13.0± 0
<0.001*abef
INR
1.2± 0.2
1.4± 0.3
1.2± 0.2
1± 0
<0.001*abcef
Total bilirubin (mg/dl)
1.2± 0.9
6.5± 9.3
1.08 ± 0.8
0.7± 0.2
<0.001*abf
Albumin (g/dl)
3.6± 1.0
2.6± 0.5
3.1± 0.7
3.7± 0.5
<0.001*abcdf
AST (IU/L)
37.3± 25.1
77.6± 58.6
45.4± 50.9
16.7± 1.9
<0.001*abcf
ALT (IU/L)
27.2± 14.6
48.2± 55.1
41.2± 95.0
16.4± 3.3
0.001*e
One way ANOVA; *p is significant at <0.05
Post hoc test (LSD) was used to assess difference between each 2 groups
a; significance between group I and II
b; significance between group II and III
c; significance between group III and IV
d; significance between group I and III
e; significance between group I and IV
f; significance between group II and IV
HCC; Hepatocellular Carcinoma, PT; Prothrombin Time, INR; international normalized ratio, AST; aspartate aminotransferase, ALT; Alanine aminotransferase
Table 3. Diagnostic value of AKR and AFP in diagnosis of early to moderate hepatocellular carcinoma.
Variable
AUC
Cut off
value
Sensitivity
Specificity
P value
AKR (ng/ml)
0.874
0.91
72.7%
89.4%
<0.001*
AFP (ng/ml)
0.680
6.9
63.6%
74.2%
0.008*
AUC; area under the curve, AKR;Aldo-Keto Reductase, AFP; alpha-fetoprotein
Table 4. Diagnostic value of AKR and AFP in diagnosis of severe hepatocellular carcinoma.
Variable
AUC
Cut off
value
Sensitivity
Specificity
P value
AKR (ng/ml)
0.395
0.61
40.9%
45.5%
0.092
AFP (ng/ml)
0.794
4.35
68.2%
69.7%
<0.001*
AUC; area under curve, AKR;Aldo-Keto Reductase, AFP; alpha-fetoprotein
Table 5. Comparing AFP and AKR between the four participated groups.
Variable
Early HCC
Mean ± SD
Late HCC
Mean ± SD
Cirrhosis without HCC
Mean ± SD
Control
Mean ± SD
P value
F test
AFP (ng/ml)
135.6± 232.4
22978.2± 58232.2
9.4± 26.4
1.3± 0.9
<0.001*
P value
(post hoc test)
a= 0.011*
b= 0.011*
c= 0.999
d= 0.989
e= 0.988
f= 0.011*
AKR (ng/ml)
1.2± 0.5
0.6± 0.2
0.8± 0.4
0.4± 0.4
<0.001*
P value
(post hoc test)
a= <0.001*
b= 0.050
c= 0.001*
d= <0.001*
e= <0.001*
f= 0.129
Kruskal Wallis test; *p is significant at <0.05
Post hoc test (LSD) was used to assess difference between each 2 groups
a; significance between group I and II
b; significance between group II and III
c; significance between group III and IV
d; significance between group I and III
e; significance between group I and IV
f; significance between group II and IV
AKR;Aldo-Keto Reductase, AFP; alpha-fetoprotein
Table 6. Correlation between AKR, AFP and other laboratory data.
Variable
AKR
AFP
r
p
r
p
Age (years)
-0.096
0.374
-0.002
0.986
PT (seconds)
0.066
0.541
0.351
<0.001*
INR
0.130
0.228
0.409
<0.001*
Total bilirubin (mg/dl)
-0.001
0.994
0.459
<0.001*
Albumin (g/dl)
0.045
0.679
-0.297
0.005*
AST (IU/L)
0.259
0.015*
0.518
<0.001*
ALT (IU/L)
0.229
0.032*
0.511
<0.001*
AFP (ng/ml)
0.344
0.001*
-
-
spearman correlation, *p is significant at <0.05
HCC; Hepatocellular Carcinoma, PT; Prothrombin Time, INR; international normalized ratio, AST; aspartate aminotransferase, ALT; Alanine aminotransferase, AKR;Aldo-Keto Reductase, AFP; alpha-fetoprotein
DISCUSSION
This comparative analytical study was conducted with the aim of finding additional serum biomarker for HCC that may help in early diagnosis in Egyptian patients.
A total sample of 88 participants were enrolled in this study and classified into 4 equal groups for first group: early and intermediate stage HCC, second group: late-stage HCC, third group: patients with liver cirrhosis without HCC and fourth group: apparently healthy people. The current study found that theage was, 63.6± 5.1 years among early to moderate HCC group, 67.6± 5.9 years in the late group, 65.1± 4.1 years in the cirrhotic group and 64.9± 7.0 years in the control group, with no difference. Gender was comparable between the four groups: 81.8%, 72.7% ,77.3% and 54.5% males among the four groups respectively. Males were higher among the HCC group with no significant difference between groups.
A similar study by Han[7] had three levels of liver diseases and a healthy control group. The mean age among the HCC group was 57 (33-78) years, 55 (31-75) years among the liver cirrhosis group, 36 (23-57) years among the chronic hepatitis group and 32 (28-40) years among healthy controls. Males were higher among the HCC group but not significantly assessedHan[7]. This goes in line with Matkowskyj[13]who found similar age ranges among HCC patients with predominance of male gender than females.
In Egypt, Gadallah[14] compared HCC patients, liver cirrhosis patients and controls with mean age of 59.4 ± 6.00, 57.9 ± 5.04 and 55.8 ± 11.1 years respectively with no significant difference. Males reported a higher percentage than females among HCC patients. These results go in line with Sato[15] regarding comparable age for HCC and healthy controls.
This study reported thatINRwas significantly higher among early and late HCC and liver cirrhosis groups than in control groups. This was in line with Han[7] as INR was higher among HCC group and cirrhotic group than the control group.
In agreement with this study Liang[16] found that HCC patients had high INR compared to cirrhotic patients without HCC with significant difference (p= 0.026). Similarly, Tahon[17] revealed that INR was significantly differ between HCC, cirrhosis and healthy control groups (1.61±0.21, 1.52±0.49, vs 1.03±0.05; p less than 0.001).
In disagreement with our results, Gadallah[14] found no significant difference in INR among HCC, liver cirrhosis and healthy control groups.
Regarding our results,total bilirubin was significantly the highest among the late HCC group rather than in the early HCC, cirrhotic and control groups.
Similarly Han[7] found that HCC had highest level of total bilirubin than liver cirrhosis and control groups (59.19±90.31 vs 47.23±74.16 and 11.50±3.96 µmol/l). In agreement, Gadallah[14] admitted that total bilirubin was significantly higher among HCC compared to liver cirrhosis patients and healthy control groups.
Based on our study findings,healthy controls had significantly higher serum albumin levels than early to moderate and late HCC and liver cirrhosis groups. Additionally, Han[7] demonstrated the same results as healthy controls had higher levels of serum albumin than HCC patients and liver cirrhosis patients (39.81±3.75 vs 32.82±6.03 and 33.52±6.79 g/L).
The same results were reported byGadallah[14], serum albumin was higher among healthy controls than in HCC and liver cirrhosis patients with significant differences.
According to the findings of this study,ALT was higher among early to moderate HCC than among control with significant differences. Like our results, Han[7] reported significant difference in the level of ALT between HCC and liver cirrhosis groups compared to healthy controls.
In accordance, Kobeisy[18] found a high ALT was associated with HCC in late stages (95% CI 8.27 (3.47–19.70); p <0.001). In agreement, Tahon[17]found that ALT was higher among HCC patients than cirrhotic patients and controls with significant difference (80.53U/L±26.96, 41.00U/L±37.46, vs 23.47U/L±3.83; p <0.001).
Gadallah[14] agreed that ALT was higher among HCC patients and liver cirrhosis patients than healthy controls. And Hsu[19] agreed that ALT was higher among HCC patients than healthy controls. In consistence with our results, Sato[15] revealed higher ALT levels among HCC patients than healthy controls.
In contrast, Mori[20] found that ALT was higher among group without HCC in comparison with group with HCC but with no significant difference (89 U/L vs 65 U/L respectively).
In this study,AST was higher among early to moderate HCC, late HCC and cirrhotic liver groups than control. Similar to our results,Han[7] reported significant difference in the level of AST between the HCC group and the liver cirrhosis group when compared to healthy controls. In addition to that,Gadallah[14] found higher levels of AST among HCC patients and liver cirrhosis patients than controls. Similar results were reported by Hsu[19]who agreed that AST level was higher among HCC patients than controls.
In agreement, Tahon[17]found that AST was significantly higher among HCC patients than cirrhotic patients and controls with significant difference (103.63U/L±32.18, 53.37U/L±30.55, vs 23.80U/L±2.40; p <0.001). Additionally, Kobeisy[18] found that high AST was significantly associated with late stages of HCC (95% CI 4.24 (1.94–9.25); p <0.001) and Sato[15] also found that AST showed higher levels among HCC positive group compared with HCC negative group (97U/L vs 43U/L respectively; p < 0.001).
In the current study,AFP showed significant differences between late HCC and three other groups: early, cirrhotic and control groups. It was the highest level among HCC patients with a mild increase among liver cirrhosis patients.
Also, Han[7] demonstrated that AFP showed higher levels in the late stages of HCC than the early to intermediate stages of HCC.
In consistency, another Egyptian study by Kobeisy[18]found that high AFP (AFP >10 ng/ml) was significantly associated with HCC and fibrosis especially late stages III/ IV. Bruden[22]reported that AFP levels has been used to screen high risk people for human hepatocellular carcinoma, including those with cirrhosis or HCV.
The results of a screening for HCC who were chronically infected with hepatitis B are shown here.by McMahon[23],they agreed that AFP was effective in detecting most HCC tumors. This was accepted also in a systematic review by Gebo [24]who agreed that HCC was detected in patients who had screening two times/ year with serum alpha-fetoprotein.
In agreement, Ye[25] reported increased levels of serum AFP among HCC patients and to some extent liver cirrhosis patients. Similar to our results, Gadallah[14] found that AFP and HCC were associated. As it showed higher levels among HCC than liver cirrhosis and controls.
Based on Hsu[19] results, AFP showed significantly higher levels associated with hepatocellular carcinoma. This goes in line with another study by Sato[15].
Considering our suggested biomarker, AKR1B10 was significantly higher among groups with early to moderate HCC than three other groups: late HCC, liver cirrhosis and control groups. Which in turn indicates that AKR1B10 (p<0.001) had a close relation with early development of hepatocellular carcinoma.
Additionally, Ye[25]reported that patients with HCC had much greater levels of AKR1B10 than the control group did, and this difference was statistically significant (p 0.001). Also, AKR1B10 revealed a slight rise among patients with liver cirrhosis. A study by Zhu[26] agreed that AKR1B10 was significantly associated with early diagnosis of HCC and associated with the risk of HCC (p< 0.05). Jin[27] reported that significant upregulation of AKR1B10 was observed in tandem with the incremental development of hepatocarcinogenesis (from liver cirrhosis to moderately differentiated HCC) (p <0.001).
Tsuzura[28] stated that compared to normal livers, livers with chronic hepatitis or cirrhosis preneoplastic diseases that underlie HCC—had significantly greater levels of AKR1B10, and AKR1B10 expression was still higher in HCC (p < 0.001). To add to that, Han[7] agreed that AKR1B10 level showed significantly (p< 005) higher levels among early and intermediate stages of HCC than the late and terminal stages of HCC. On the same hand, Matkowskyj[13] described a significant association between AKR1B10 levels and hepatocellular carcinoma. As AKR1B10 level was higher among HCC patients when compared with liver cirrhosis and controls (p <0.05).
AKR1B10 was found with a significant (p<0.001) high level among HCC patients in a study by Gadallah[14]. This goes in line with a study compared between animals and humans with HCC by Torres-Mena [29]who suggested that AKR1B10 level was increased in HCC and could be used as a biomarker of it (p <0.05).
This study found that there was a weak positive correlation between AKR1B10 and AFP (p=0.014). This goes in line with Ye[25]who found an association between AKR1B10 and AFP (p <0.05). Similarly, Zhu[26] found that AKR1B10 was significantly associated with AFP. This agrees with the study by Gadallah[14] who found a correlation between AKR1B10 and AFP.
Our current results found that AKR1B10 had no relation with ALT and AST. Similarly, Gadallah[14] found no correlation between AKR1B10 and ALT but correlation with AST was found significant. In the same line,Mori[20] agreed that ALT levels were not correlated with AKR1B10 expression.
Unlike our results, Ye [25] reported an association between AKR1B10 and ALT and AST.
Based on the results of this study,AKR1B10 could significantly detect early to moderate hepatocellular carcinoma with sensitivity of 72.7%, specificity of 89.4% and area under the curve of 0.874 at cut off value ≥ 0.91ng/ml. While AFP had a lower diagnostic value for detecting early to moderate hepatocellular carcinoma as it had sensitivity of 63.6%, specificity of 74.2% and area under the curve of 0.680 at cut off value ≥6.9ng/ml.
AFP could significantly detect late stage of hepatocellular carcinoma with sensitivity of 68.2%, specificity of 69.7% and area under the curve of 0.794 at cut off value ≥ 4.35 ng/ml. While AKR had no statistically significant diagnostic value to severe hepatocellular carcinoma.
Bruce[30] reported that an elevated AFP with cut off > 8 ng/ml has a high positive predictive value (78%) for HCC with 39% sensitivity and 95% specificity. Additionally, Zhu [26]revealed that the the area under the curve (AUC) for AKR1B10 in serum was 0.866 with a 95 percent confidence interval (CI) of 0.826---0.907, and the best diagnostic cut-off was 232.7 pg/mL.. Ye and colleagues[25]agreed that the optimal diagnostic cut off value of AKR1B10 level was 267.9 pg/ml, which had a sensitivity of 64.4%, specificity of 92.3% and an AUC of 0.831. on the other hand, AFP showed at cut off value of 20.2 ng/ml a sensitivity of 59.5% and a specificity of 77.7%.
Similar to our results, Kanno[31]studied different stages of liver cirrhosis and reported that serum AKR1B10 at a cut off value of 1.03 ng/ml can predict late stage of cirrhosis with early HCC detection. Its sensitivity was 71.4% and specificity of 94.7%.
According to the Egyptian study by Gadallah[14], AKR1B10 had a good diagnostic value of early to moderate HCC at a cut off value of 0.945 ng/ml, reported sensitivity of 86.7% and specificity of 70%. While AFP showed at cut off 17.9 ng/ml, a sensitivity of 67% and a higher specificity of 88%. Which goes in line with our results that AKR1B10 had a higher diagnostic value for detection of early HCC than AFP.
Similar to that Mori[20]who agreed that due to the association between high hepatic AKR1B10 expression and an increased risk of developing HCC, AKR1B10 can predict the incidence of HCC. To add to that, Sato [21] demonstrated that the adjusted hazard ratio (HR) showed that high AKR1B10 expression was a significant independent predictor of HCC formation and that AKR1B10 expression 6% was connected to a more than sixfold increased risk of HCC development.
The difference in the diagnostic value of both AKR1B10 and AFP may suggest that AKR1B10 plays a role in the pathogenesis of hepatocellular carcinoma and developed earlier than AFP [32].
CONCLUSION
AKR1B10 has better diagnostic value than AFP in detection of early stages of HCC as it had good sensitivity (72.7 %) and higher specificity (89.4%). And it has higher levels in the early to moderate stages of HCC (1.2± 0.5 ng/ml) than in the severe late stages (0.6± 0.2 ng/ml). So AKR1B10 can help in early detection of HCC in highly suspicious patients with good diagnostic value.
This study recommended that AKR1B10 can be used as a regular screening laboratory investigation among preneoplastic patients. We also recommend that AKR1B10 together with ultrasonography should be performed every six months for those patients with high-risk of HCC. Further studies with bigger sample size and in other areas of the country should be done to investigate the role of AKR1B10 in the pathogenesis of hepatocellular carcinoma and to generalize our results.
ACKNOWLEDGMENT:
Patients who agreed to take part in this study deserve our deepest gratitude.
Funding: None .
Ethical considerations
Clearance for ethical standards was acquired from the ethics committee of the Faculty of Medicine at Suez Canal University. Every participant provided their written informed permission, which was collected.
References
1- Tang A, Hallouch O, Chernyak V, Kamaya A, Sirlin CB. Epidemiology of hepatocellular carcinoma: target population for surveillance and diagnosis. Abdom Radiol 2018;43(1):13–25.
2-Rashed WM, Kandeil MAM, Mahmoud MO, Ezzat S. Hepatocellular Carcinoma (HCC) in Egypt: A comprehensive overview. J Egypt Natl Canc Inst 2020;32(1):5.
3-Yang JD, Hainaut P, Gores GJ, Amadou A, Plymoth A, Roberts LR. A global view of hepatocellular carcinoma: trends, risk, prevention and management. Nat Rev Gastroenterol Hepatol 2019 Oct;16(10):589–604.
5-Ayuso C, Rimola J, Vilana R, Burrel M, Darnell A, García-Criado Á, et al. Diagnosis and staging of hepatocellular carcinoma (HCC): current guidelines. Eur J Radiol 2018 Apr;101:72–81.
6-Wang T, Zhang K-H. New Blood Biomarkers for the Diagnosis of AFP-Negative Hepatocellular Carcinoma. Front Oncol 2020;10:13–6.
7-Han C, Gao L, Bai H, Dou X. Identification of a role for serum aldo-keto reductase family 1 member B10 in early detection of hepatocellular carcinoma. Oncol Lett 2018 Dec;16(6):7123–30.
8-Forner A, Reig M, Bruix J. Hepatocellular carcinoma. Lancet 2018 Mar;391(10127):1301–14.
9-Luo P, Wu S, Yu Y, Ming X, Li S, Zuo X, et al. Current Status and Perspective Biomarkers in AFP Negative HCC: Towards Screening for and Diagnosing Hepatocellular Carcinoma at an Earlier Stage. Pathol Oncol Res 2020 Apr;26(2):599–603.
10-Huang L, He R, Luo W, Zhu Y-S, Li J, Tan T, et al. Aldo-Keto Reductase Family 1 Member B10 Inhibitors: Potential Drugs for Cancer Treatment. Recent Pat Anticancer Drug Discov 2016 May;11(2):184–96.
11-Dawson B, Trapp RG. Basic and clinical biostatistics. Vol. 192, ALANGE medical book 2004. 141–142 p.
12-Luo DX, Huang MC, Ma J, Gao Z, Liao DF, Cao D. Aldo-keto reductase family 1, member B10 is secreted through a lysosome-mediated non-classical pathway. Biochem J 2011 Aug;438(1):71–80.
13-Matkowskyj KA, Bai H, Liao J, Zhang W, Li H, Rao S, et al. Aldoketoreductase family 1B10 (AKR1B10) as a biomarker to distinguish hepatocellular carcinoma from benign liver lesions. Hum Pathol 2014 Apr;45(4):834–43.
14-Gadallah A-NA-A, Atti EAA, Salman TAH, Hassan A elSamie O, Bedair HM. Predictive Role for Serum Aldo-Keto Reductase Family1 Member B10 for Early Detection of Hepatocellular Carcinoma in Egyptian Patients. Open Access Maced J Med Sci 2022 Jan;10(B):1678–85.
15-Sato S, Genda T, Hirano K, Tsuzura H, Narita Y, Kanemitsu Y, et al. Up-regulated aldo-keto reductase family 1 member B10 in chronic hepatitis C: association with serum alpha-fetoprotein and hepatocellular carcinoma. Liver Int 2012 Oct;32(9):1382–90.
16-Liang J, Zhu J, Wang M, Singal AG, Odewole M, Kagan S, et al. Evaluation of AGP Fucosylation as a Marker for Hepatocellular Carcinoma of Three Different Etiologies. Sci Rep 2019 Aug;9(1):1–13.
17-Tahon AM, El-Ghanam MZ, Zaky S, Emran TM, Bersy AM, El-Raey F, et al. Significance of Glypican-3 in Early Detection of Hepatocellular Carcinoma in Cirrhotic Patients. J Gastrointest Cancer 2019 Sep;50(3):434–41.
18-Kobeisy MA, Morsy KH, Galal M, Sayed SK, Ashmawy MM, Mohammad FM. Clinical significance of elevated alpha-foetoprotein (AFP) in patients with chronic hepatitis C without hepatocellular carcinoma in upper EGYPT. Arab J Gastroenterol 2012 Jun;13(2):49–53.
19-Hsu YC, Wu CY, Lane HY, Chang CY, Tai CM, Tseng CH, et al. Determinants of hepatocellular carcinoma in cirrhotic patients treated with nucleos(t)ide analogues for chronic hepatitis B. J Antimicrob Chemother 2014 Jul;69(7):1920–7.
20-Mori M, Genda T, Ichida T, Murata A, Kamei M, Tsuzura H, et al. Aldo-keto reductase family 1 member B10 is associated with hepatitis B virus-related hepatocellular carcinoma risk. Hepatol Res 2017 Mar;47(3):E85–93.
21-Sato S, Genda T, Ichida T, Murata A, Tsuzura H, Narita Y, et al. Impact of aldo-keto reductase family 1 member B10 on the risk of hepatitis C virus-related hepatocellular carcinoma. J Gastroenterol Hepatol 2016 Jul;31(7):1315–22.
22-Bruden DL, McMahon BJ, Hennessy TW, Christensen CJ, Homan CE, Williams JL, et al. Estimating the date of hepatitis C virus infection from patient interviews and antibody tests on stored sera. Am J Gastroenterol Suppl 2004 Aug;99(8):1517–22.
23-McMahon BJ, Bulkow L, Harpster A, Snowball M, Lanier A, Sacco F, et al. Screening for hepatocellular carcinoma in Alaska natives infected with chronic hepatitis B: A 16-year population-based study. Hepatol 2000;32(4 I):842–6.
24-Gebo KA, Chander G, Jenckes MW, Ghanem KG, Herlong HF, Torbenson MS, et al. Screening tests for hepatocellular carcinoma in patients with chronic hepatitis C: a systematic review. Hepatology 2002 Nov; 36(5 Suppl 1):S84–92.
25-Ye X, Li C, Zu X, Lin M, Liu Q, Liu J, et al. A Large-Scale Multicenter Study Validates Aldo-Keto Reductase Family 1 Member B10 as a Prevalent Serum Marker for Detection of Hepatocellular Carcinoma. Hepatology 2019 Jun;69(6):2489–501.
26-Zhu AX, Kang YK, Yen CJ, Finn RS, Galle PR, Llovet JM, et al. Ramucirumab after sorafenib in patients with advanced hepatocellular carcinoma and increased α-fetoprotein concentrations (REACH-2): a randomised, double-blind, placebo-controlled, phase 3 trial. Lancet Oncol 2019 Feb;20(2):282–96.
27-Jin GZ, Yu WL, Dong H, Zhou WP, Gu YJ, Yu H, et al. SUOX is a promising diagnostic and prognostic biomarker for hepatocellular carcinoma. J Hepatol 2013 Sep;59(3):510–7.
28-Tsuzura H, Genda T, Sato S, Murata A, Kanemitsu Y, Narita Y, et al. Expression of aldo-keto reductase family 1 member b10 in the early stages of human hepatocarcinogenesis. Int J Mol Sci 2014 Apr;15(4):6556–68.
29-Torres-Mena JE, Salazar-Villegas KN, Sánchez-Rodríguez R, López-Gabiño B, Del Pozo-Yauner L, Arellanes-Robledo J, et al. Aldo-Keto Reductases as Early Biomarkers of Hepatocellular Carcinoma: A Comparison Between Animal Models and Human HCC. Dig Dis Sci 2018 Apr;63(4):934–44.
30-Bruce MG, Bruden D, McMahon BJ, Christensen C, Homan C, Sullivan D, et al. Clinical significance of elevated alpha-fetoprotein in Alaskan Native patients with chronic hepatitis C. J Viral Hepat 2008 Mar;15(3):179–87.
31-Kanno M, Kawaguchi K, Honda M, Horii R, Takatori H, Shimakami T, et al. Serum aldo–keto reductase family 1 member B10 predicts advanced liver fibrosis and fatal complications of nonalcoholic steatohepatitis. J Gastroenterol 2019; 54(6):549–57.
32-Muscari F, Maulat C. Preoperative alpha-fetoprotein (AFP) in hepatocellular carcinoma (HCC): is this 50-year biomarker still up-to-date? Transl Gastroenterol Hepatol 2020 Jul;5:1–8.