Non-invasive investigation of early kidney damage in streptozotocin-induced diabetic rats by intravoxel incoherent motion diffusion-weighted (IVIM) MRI

Background

The current study investigated the performance of intravoxel incoherent motion diffusion (IVIM) technology in monitoring early renal injury in streptozotocin rats.

Methods

Forty-eight Sprague-Dawley (SD) rats were divided into a control group and a diabetic mellitus (DM) group. Six rats in each group were randomly selected for MR scans at four different time points (0, 4, 8, and 12 weeks). The IVIM-derived parameters (D, D*, f and ADC values) of the renal cortex (CO), outer and inner stripe of the outer medulla (OS, IS), and internal medulla (IM) were acquired. Changes in each IVIM-derived parameter over time were analyzed, and differences between the two groups at each point were assessed. The associations between the IVIM parameters and IV collagen expression, urine volume (UV), blood urea nitrogen (BUN), and serum creatinine (Scr) were investigated.

Results

The D and D* values of CO and the ADC values of CO, OS, IS and IM displayed significantly different trends between the two groups over time (P<0.05). In addition, significant correlations were discovered between the D* value of CO and UV and BUN (r=0.527, P=0.033; r=0.617, P=0.005), between the ADC value of IM and BUN (r=0.557, P=0.019) and between the f value of IM and BUN (r=0.527, P=0.033). No correlation was found between IVIM parameters and IV collagen expression and Scr.

Conclusions

IVIM is a potential sensitive and noninvasive technology for the simultaneous assessment of early renal cortical and medullary injuries induced by diabetes.

Diabetic nephropathy (DN) is one of the most common systemic microvascular complications of diabetes mellitus (DM) and is considered the leading cause of mortality in patients with DM. However, in the early stage of DN, its clinical diagnosis is not straightforward due to the lack of obvious clinical manifestations of nephropathy. Moreover, traditional blood and urine tests are useless in the early detection of renal dysfunction in patients with DM. Hence, it is urgent to explore an effective method with high sensitivity to identify early kidney injury in DN.

In past decades, DN has long been considered a kind of glomerular disease, and tubular-interstitial damage is regarded as a secondary change [1]. However, in recent years, investigators believe that the impairment of renal tubules precedes the occurrence of glomerular lesions [2,3,4,5], and renal tubulointerstitial abnormalities are more likely to be the early modification of DN [5, 6]. Additionally, Vallon et al. [2] indicated that the glomerular filtration rate was determined by the balance of forces between primary tubular and primary vascular events. Taken together, these findings may have a huge influence on the early diagnosis, effective treatment and prognosis of DN.

As a relatively simple and noninvasive tool, previous studies suggested that renal quantitative diffusion weighted imaging (DWI) could potentially play a role in the diagnosis of DN [7,8,9]. Cakmak et al. [7] revealed that there was a significant correlation between the renal ADC values and clinical stages of DN. Chen et al. [8] speculated that apparent diffusion coefficient (ADC) value may be more sensitive than the urine albuminuria excretion rate in reflecting early-stage kidney injury in DN patients. However, the ADC value based on a single exponential model is approximated as the average diffusion coefficient of various constituent components contained in biological tissue [10], and it does not reflect the true state of dispersion of the renal parenchyma. Le Bihan et al. [11] proposed a two-exponential model of diffusion MRI, named intravoxel incoherent motion (IVIM), to simultaneously estimate tissue diffusivity and microcapillary perfusion. Four parameters, including slow ADC (D, mm²/s), fast ADC (D*, mm²/s), fraction of fast ADC (f, %), and standard ADC (ADC, mm²/s), can be calculated according to the IVIM model.

The limitations of the single exponential model become more apparent due to the complexity of the renal structure and function, including vascular flow, tubular flow and passive diffusion [11, 12]. The application of IVIM has been reported in research articles on diabetic renal injury [9, 13,14,15]. On this basis, our team also conducted a pilot study using IVIM to evaluate the kidneys of patients with early DN [9]. The preliminary results showed that the changes in D, D* and f values were more sensitive than the ADC value in detecting early changes in kidneys in diabetic patients before the occurrence of microalbuminuria (MAU). However, this study lacked pathological evidence to further verify our hypothesis because our participants were human beings.

Derived from the aforementioned literature, we hypothesized that IVIM could help us evaluate the early changes in renal functions in pathologically confirmed DM rats. To achieve our goal, rat models of DM were first established, and then the changes in renal function in DM rats were dynamically monitored using IVIM technology at distinct time points.

Animal model

This study was approved by the Animal Experimental Ethical Inspection committee of our university, and the experimental process abided strictly by the animal ethics regulations. Sixty-six male Sprague-Dawley rats weighing between 240 and 250 g were purchased from Jinan Pengyue (Experimental Animal Breeding Co., Ltd., with license number of SCXK (Yue) 20140007). The rats were housed in a well-ventilated environment maintained at 18–22°C, with a relative humidity of 60–70% and 12 h of light per day. All rats had free access to food and water throughout the study.

All rats were randomly divided into 2 groups, the DM and control groups. After fasting for 8 hours, DM group rats were induced by an intraperitoneal injection of streptozocin (STZ; Sigma) at a dose of 55 mg/kg. Control rats received an equal volume of citrate buffer via intraperitoneal injection. Fasting blood glucose (fasting 12 hours) from tail vein samples was measured at 72 hours after STZ injection. Rats with blood glucose levels greater than 16.7 mmol/L after STZ administration were included in the study.

A total of 26 rats were successfully induced by STZ in the DM group; however, two rats were sacrificed caused by anesthesia during the study. Thus, the final 24 rats were included and then randomly subdivided into 4 subgroups (6 rats in each subgroup): 0 w, 4 w, 8 w, and 12 w, which means 0, 4, 8, 12 weeks after induction of diabetes, respectively (Supplemental Figure 1). Another 24 rats in the control group were also randomly allocated to each subgroup as a control. During the study, at each time point (0, 4, 8 and 12 weeks) after induction of diabetes, the rats in the corresponding subgroups were selected for MRI examination. All rats were placed in metabolic cages for collection of 24-h urine samples before MRI. Body weight and blood glucose levels were also measured before MRI. Other clinical indices, including urine creatinine, urea nitrogen, blood urea nitrogen (BUN) and serum creatinine (Scr), were measured using an automatic biochemistry analyzer (Hitachi Model 7600, Japan). These rats were then euthanized via intraperitoneal injection of 0.3% sodium pentobarbital (10 ml/kg), and the kidneys were excised for histopathological examination.

MR protocol

The anesthetized rats (0.3% sodium pentobarbital, 2 ml/kg intraperitoneally) were scanned using 3T MRI (Discovery MR750, GE Healthcare) with an HD wrist array upper coil. During imaging acquisition, rats were placed in a prone and head advanced position.

MR sequences and parameters were as follows: T2-weighted imaging (T2WI) adopted fast relaxation fast spin echo sequence, repetition time = 3690 ms, echo time = 73 ms, field of view= 7.0 cm×5.6 cm; slice numbers = 7, layer thickness = 1.8 mm, layer interval = 0.2 mm, bandwidth = 15.63 kHz, matrix size = 160×160. IVIM images were acquired in the coronal plane using a spin-echo echo planar imaging sequence, with the following parameters: repetition time = 3500 ms, echo time = 70.4 ms, field of view=8.0 cm×4.8 cm; slice numbers=7, layer thickness = 3.0 mm, layer interval = 0.2 mm, bandwidth = 167 kHz, matrix size = 128×64; and 12 b values (0, 20, 30, 50, 80, 100, 150, 200, 400, 600, 700, 800 s/mm²). The total acquisition time was approximately 2 minutes 10 seconds.

Image postprocessing

IVIM parameter values were calculated using the following equation [10]:

where S₀ and S_b are the signal intensities without and at a given b value, respectively. D is the true water molecule diffusion coefficient; D* is the perfusion coherence diffusion coefficient, i.e., pseudodispersion, which can reflect changes in blood perfusion [16]. D* refers to the irregular movement of the liquid in the irregular lumen. The average capillary length, blood flow velocity and blood vessel shape can affect the D* value. D* may also be affected by renal tubules, mean length of collection tubes, and fluid flow rate in kidney studies. f is the perfusion-related volume fraction, representing the volume ratio of the diffusion caused by the microcirculation perfusion effect in the overall diffusion effect of the voxel. The larger the f value is, the denser the capillary distribution is. In the kidney, the f value is not only related to blood vessels but also affected by renal tubules and collecting ducts. ADC is closely related to the b value and is not accurate and objective.

The IVIM sequence image raw data were transmitted to the functool software and MADC postprocessing software of GE's ADW4.5 workstation for image postprocessing and analysis, and the IVIM parametric images were obtained. The values of IVIM parameters were independently measured by two radiologists with 6 years and 23 years of diagnostic imaging experience. Regions of interest (ROIs) were drawn manually over the right renal cortex (CO), outer stripe of the outer medulla (OS), inner stripe of the outer medulla (IS) and internal medulla (IM), avoiding the renal sinus and blood vessels on the DWI (b=0) images, and transferred to the various IVIM parametric maps (Fig. 1). The IVIM parametric mapping is shown on Fig. 2. Three continuous coronal images at the level of the renal hilum were used for quantification to optimize the signal-to-noise ratio, which refers to previous research [17, 18]. The ROI sizes of each CO, OS IS and IM are approximately 37-43 mm², 27-33 mm², 17-23 mm² and 7-10 mm², respectively.

Placement of regions of interest (ROI) into the b₀ image. CO, cortex; OS, outer stripe of the outer medulla; IS, inner stripe of the outer medulla; and IM, inner medullary

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IVIM parametric maps are shown for rats at 0, 4, 8, and 12 weeks after streptozotocin-induced diabetes (DM Group) and citrate buffer injection (Control Group)

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Pathological analysis

A total of 24 rats in the DM groups were sacrificed with an overdose of anesthesia with 0.3% sodium pentobarbital (10 ml/kg). The weights of the rat kidneys were subsequently measured. The kidneys were then fixed in 10% neutral formalin solution for histological examination. Tissues were embedded in paraffin wax, cut into 3-μm sections and stained with hematoxylin and eosin (H&E). Sections of 3-μm thickness were stained with Sirius Red for collagen quantification, which could be considered a marker of fibrosis. Sections were then analyzed and photographed by a pathologist (B.D., 20 years of pathology experience) who was blind to the MR findings.

Statistical analysis

Statistical analysis was performed using SPSS v. 20.0 software (Chicago, IL). All results are expressed as the mean ± standard deviation (M ± SD), and P < 0.05 was considered to be statistically significant. The values of body weight, kidney weight ratio, urine volume (UV), BUN, Scr and MRI indices in the renal cortex of the rats were compared using independent two-sample t-tests at each time point. To estimate the time and group differences as well as their mixed interactions of the IVIM-derived indices, repeated-measures ANOVA was applied in the current study. Post hoc independent two-sample t-tests were further employed to compare the group differences at distinct time points. The associations between the IVIM-derived parameters and histopathological or biochemical values were quantified using Pearson and Spearman correlation analysis.

Animal and laboratory parameters

After 72 hours of STZ injection, the typical characteristics of the diabetic rats developed gradually, including polyphagia, polydipsia, polyuria, weight loss, apathy and poor fur color. Cataracts were discovered at the 7^th week. In contrast, the rats in the control group displayed a good mental state, a highly sensitive response, and gradually increased body weight and free movement. The body weights of diabetic rats continued to decline over time. The body weights were significantly lower than the body weights of rats in the control group from the 4^th to 12^th weeks. In contrast, the ratios of kidney weight/body weight in diabetic rats tended to increase after the 4^th week (P < 0.05). The UV values of diabetic rats increased significantly at the 4^th and 8^th weeks and decreased at the 12^th week compared with the control group (P < 0.05). Both the serum BUN and Scr values in diabetic rats had an increasing trend over time. Intergroup differences were discovered in serum BUN from the 4^th to 12^th weeks (P < 0.05), but no significant differences were found in serum Scr at any time point between the two groups (Table 1).

Comparisons of IVIM parameters

Twelve out of 16 IVIM parameters in the kidneys of diabetic rats demonstrated alterations over time, except for D_CO, D_OS, D_IM and D*_IM (P₁ values shown in Table 2 and Fig. 3). A total of 6 parameters displayed a significant difference in the difference of the IVIM parametric means between the two groups over time, including D_CO, D*_CO, ADC_CO, ADCos, ADC_IS and ADC_IM (P<0.05, as P₂ values exhibited in Table 2 and Fig. 3). In the DM group, most IVIM parameters showed a trend of rising first and then falling over time. However, the f values of the renal cortex and medulla slowly increased, and the D_IS, D_IM and D*_IM values had a declining trend over time. In contrast, none of the parameters in the controls displayed similar trends.

The ADC, D, D*, and f values of CO, OS, IS, and IM in the DM and control groups at each time point (0, 4, 8, and 12 weeks). CO, cortex; OS, outer stripe of the outer medulla; IS, inner stripe of the outer medulla; and IM, inner medullary. ADC (standard ADC, mm²/s), apparent diffusion coefficient; D (slow ADC, mm²/s), extravascular effects of passive diffusion; D* (fast ADC, mm²/s), pseudodiffusion coefficient; f, (fraction of fast ADC, %), perfusion fraction

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At 4 weeks, the D_CO, D_OS, D_IM, D*_CO, D*_IM, f_IM and ADC_IM values of diabetic rats were greater than the comparable values of the controls, and significant differences were discovered in the D*_CO, D_IM, f_IM, and ADC_IM values between the two groups (P < 0.05) (Table 3 and Fig. 3). The D and f values of CO and the D* value of IM did not change significantly in diabetic rats until the 8^th week. The ADC values of IS showed a significant difference between the two groups at the 12^th week (Table 3 and Fig. 3).

Pathological results

HE stain

At the 4^th week, the renal glomerular volume and extracellular matrix (ECM) increased slightly in diabetic rats. Furthermore, mild mesangial hyperplasia, vacuolated renal tubular epithelial cells, slightly dilated renal tubules and capillary lumen were also observed. Renal tubular abnormalities in the medulla were more prominent in our results (Figs. 4 and 5).

Histological analysis of kidney tissue sections in diabetic rats and controls. Histology of Glomeruli (G) and Renal Tubule (T). All sections were stained with H&E stain. Dilated renal tubules (arrowheads), capillary proliferation (white arrows), renal tubular epithelial necrosis and exfoliation (black arrows) are demonstrated

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Histological analysis of kidney tissue sections in diabetic rats and controls. Histology of glomeruli (G) and renal tubule (T). All sections were stained with podocin stains. Dilated renal tubules (arrowheads), capillary proliferation (white arrows), renal tubular epithelial necrosis and exfoliation (black arrows) are demonstrated

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At the 8^th week, swollen glomerular endothelial cells, moderately increased mesangium and ECM, glomerular wall adhesion, moderate capillary lumen expansion, partial renal tubular epithelial necrosis and exfoliation and interstitial endothelial cell infiltration were demonstrated in diabetic rats (Figs. 4 and 5).

At the 12^th week, thickened basement membranes of glomeruli and renal tubules were discovered. Severe mesangial and ECM hyperplasia, uneven expansion of the glomerular balloon, adhesion of balloon wall and highly dilated capillary lumen were also shown. Furthermore, tubular atrophy, dilated tubules, necrotic and detached tubular epithelial cells and a large amount of interstitial inflammatory cell infiltration were observed (Figs. 4 and 5).

For the controls, the renal glomeruli and tubules were normal over time. There was no inflammatory cell infiltration or dilated and congested blood vessels in the renal interstitium (Figs. 4 and 5).

Collagen IV immunohistochemistry

As shown in the Supplemental Table, the expression of Collagen IV gradually increased in the kidneys of diabetic rats over time. Capillary hyperplasia in the tubulointerstitium gradually became apparent.

Correlation analysis

The statistical results are shown in Table 4. D*_CO, ADC_IM and f_IM showed significant positive correlations with UV (D*_CO: r=0.527, P=0.033) and BUN (D*_CO: r=0.617, P=0.005; ADC_IM: r=0.557, P=0.019; f_IM: r=0.527, P=0.033).

In the current study, we used an IVIM model to evaluate the functional fluctuations of kidneys over time in STZ diabetic rats, and correlations were detected between IVIM-derived parameters and histopathological or biochemical indices. Our results demonstrated three important findings. First, 12 out of 16 renal IVIM parameters displayed significant trends over time in our study. In addition, some IVIM parameters, including D_CO, D*_CO, ADC_CO, ADCos, ADC_IS and ADC_IM, revealed significant changes between the two groups. These results suggested a high sensitivity of IVIM in detecting early renal damage in diabetic rats. Second, there were significant correlations between the cortical D* value and UV or BUN, between the f_IM and BUN and between the ADC_IM and UV, indicating damage to both renal glomeruli and tubules in the early stage of diabetes. Finally, the perfusion (D* and f values) and molecular diffusion (D and ADC value) parameters may be sensitive indicators for the detection of cortical and medullary damage in diabetic rats.

Our study found significantly higher Dco, D_IM and ADC_IM values at the 4^th week as well as ADCco at the 8^th week in diabetic rats, indicative of an increase in water molecule diffusion of CO and IM. The histological results revealed mildly increased renal glomerular volume and vacuolated renal tubular epithelial cells in the inner medulla, which could contribute to expanding the extracellular space and increasing the diameter of the renal tubule, subsequently resulting in higher D and ADC values. Additionally, previous studies showed doubled tubular cell and luminal diameters, increased cell height and a 37% increase in proximal tubule length at the 7^th week, which reflected hyperplasia and hypertrophy of the kidney [19, 20]. In addition, Sigmund et al. [16] demonstrated that reabsorption played a strong role in the increased D value because of the stronger urine output sensitivity of hydration after furosemide administration. This may be another factor for the higher D_IM and ADC_IM values in diabetic rats. The increased ADC value is at least in part the result of an increase in microcirculation due to hyperfiltration and hyperperfusion [12, 16].

Although the kidney has a certain anti-injury and hypoxia reserve capacity [21,22,23], the obvious accumulation of ECM, thickened glomerular and tubular basement membrane, mesangial hyperplasia and interstitial inflammatory cell infiltration become more prominent after the 4^th week with the further development and deterioration of renal function. These changes will contribute to the increased cell density or decreased extracellular space and consequently the restricted diffusion of water molecules [24]. Therefore, the D and ADC values in our study showed a downward trend from the 8^th to 12^th weeks and observably lower ADCco and ADCos at the 12^th week in diabetic rats. Additionally, the decreased D and ADC values could be related to swollen renal tubular epithelial cells and decreased tubular flow and capillaries [25, 26].

Sigmund et al. [16] indicated that the f value is the ratio of the sum of the amount of liquid contained in the renal tubules and capillaries to the total amount of fluid contained in the kidney. A higher f value suggested a denser distribution of capillaries, and thus, the sum of lumen diameters was larger [27, 28]. A significantly higher f_IM at the 4^th week in diabetic rats was demonstrated in this study. Additionally, the UV of the diabetic rats was 5-fold greater than the UV of the controls, indicating renal hyperfiltration. At the early stage of diabetic nephropathy, the kidney is in a state of hyperfiltration and hyperperfusion accompanied by an increase in renal fluid load, especially in areas with dense renal tubules. Hence, the increased f_IM was a good reflection of renal hyperfiltration and hyperperfusion in the early stage of DN. Noticeably, the D* value showed an upward trend of change at the 4^th week, especially the D*co value which may indicate that increased perfusion of the kidney occurred as well.

Interestingly, similar to diffusion parameters, a declining trend was also observed in perfusion parameters from the 8^th to 12^th weeks. The decreased D* and f values might be related to the reduced flow rate due to the swelling of tubular epithelial cells and expansion of the lumen in CO and IM [12, 16]. Moreover, numerous studies have suggested that this decrease may be associated with hypoxia [12, 24, 29]. With the progression of the disease, mesangial hyperplasia compresses the surrounding glomerular capillaries, leading to a decrease in renal perfusion. Subsequently, the reduced flow of renal tubules and collecting ducts was followed by the decreased fluid load of the kidneys, which could be another explanation of the reduced perfusion parameter.Furthermore, our results revealed notably increased UV radiation in diabetic rats from the 4^th week. Coincidently, D*co was remarkably positively correlated with UV. These findings suggest hyperfiltration and hyperperfusion of the renal cortex. From the onset of diabetes, several vascular and tubular factors contribute to a net reduction in afferent arteriolar resistance, thereby increasing renal blood flow [30, 31]. Various cytokines and growth factors lead to an enlarged nephron size and filtration surface area per glomerulus in response to hyperglycemia [32] particularly hypertrophy of the proximal tubule [33, 34]. Correspondingly, the plasma of the renal cortex will be augmented. Meanwhile, obviously higher D_co, D_IM and ADC_IM values were observed at the 4^th week in diabetic rats, indicating that the diffusion parameter was sensitive for displaying early changes in the renal cortex and IM. In addition, out of the serum biochemical indicators, only BUN demonstrated a significant increase in the early stage, indirectly verifying that IVIM parameters could be more sensitive than biochemical indices in the detection of pathological changes in early DN.

This study had some limitations. First, STZ was applied to induce diabetes, which can directly destroy the islet cell function of rats. Thus, this diabetic rat model may be more appropriate for type I diabetes. Second, bowel gas and breathing patterns could cause artifacts in imaging, which will affect the accuracy of measurement. In our study, the scan time was shortened as much as possible using the optimized imaging parameters. Additionally, the prone position was applied to reduce breathing artifacts. Moreover, MRI scans were performed during the nighttime, which is helpful for reducing intestinal peristalsis and intestinal gas. Third, the interval between the two adjacent time points was relatively longer. More time points should be considered in future research. Finally, the sample size was relatively small. The sampling error could be reduced by increasing the sample size in the future. Finally, the hyperfiltration may be an important factor that affects IVIM parameters, thus the absence of a direct evidence of hyperfiltration in DM rats is a limitation for this current study.

In conclusion, our results indicated that IVIM is a potential sensitive and noninvasive technology for the simultaneous assessment of renal cortical and medullary injuries in early DN. Importantly, the current research revealed renal cortex and medulla perfusion abnormalities and molecular diffusion changes in the early stage of diabetes in rats.

The datasets used and/or analyzed during the current study available from the corresponding author on reasonable request.

DN:

Diabetic nephropathy

DM:

Diabetes mellitus

MAU:

Microalbuminuria

IVIM:

Intravoxel Incoherent Motion

D:

Slow ADC

D*:

Fast ADC

f :

Fraction of fast ADC

CO:

Renal cortex

OS:

Outer stripe of the outer medulla

IS:

Inner stripe of the outer medulla

IM:

Internal medulla

UV:

Urine volume

BUN:

Blood urea nitrogen

Scr:

Serum creatinine

ROIs:

Regions of interests

STZ:

Streptozocin

The authors wish to Bin Du and Yanxia Lu for their help in pathological assessment.

This study has received funding by The National Key Research and Development Program of China (grant no. 2016YFC1305703) and Foundation for Young Talents in Higher Education of Guangdong Province (grant no.2019KQNCX005). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

1. You-Zhen Feng, Xiao-Qiao Chen and Zhong-Yuan Cheng are co-first author.

Authors and Affiliations

1. Medical Imaging Center, Jinan University First Affiliated Hospital, No.613 West Huangpu Avenue, Tianhe District, Guangzhou, 510630, Guangdong, China

   You-Zhen Feng, Zhong-Yuan Cheng, Qi-Ting Lin, Ping-Kang Chen, Ding-Kun Si-Tu & Xiang-Ran Cai

2. Medical Imaging Center, The Eighth Affiliated Hospital of Sun Yat-Sen University, Shenzhen, Guangdong, China

   Xiao-Qiao Chen

3. Nephrology Department, Jinan University First Affiliated Hospital, Guangzhou, Guangdong, China

   Rui Cao

4. GE Healthcare, Beijing, China

   Long Qian

5. Department of Biomedical Engineering, Peking University, Beijing, 100871, China

   Long Qian

6. Yingde Base, Institute of Kidney Surgery, Jinan University, Guangzhou, Guangdong, China

   Baoli Heng

7. Department of Urology, Jinan University First Affiliated Hospital, Guangzhou, China

   Baoli Heng

Contributions

All authors have read and approved the manuscript. Guarantors of integrity of entire study, X.R.C. and Z.Y.C; manuscript drafting or manuscript revision for important intellectual content, all authors; approval of final version of submitted manuscript, all authors; literature research, Y.Z.F., X.Q.C and Z.Y.C; clinical studies, Y.Z.F., Q.T.L, Z.Y.C., P.K.C., D.K.S.T, B.L.H and R.C; Acquisition of data: Y.Z.F., Q.T.L, P.K.C, Z.Y.C., D.K.S.T and L.Q. Sequence debugging and data processing Z.Y.C and L.Q.

Corresponding author

Correspondence to Xiang-Ran Cai.

Ethics approval and consent to participate

All animal experiments were conducted in accordance with the revised Animals (Scientific Procedures) Act 1986 and have been reviewed and approved by the Laboratory Animal Ethics Committee of Jinan University, China.

Consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

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