Benefits of D-005, a lipid extract from <i>Acrocomia crispa</i> fruits, in the prevention of acute kidney njury induced by nephrotoxicity in rats

Rodríguez-Salgueiro, Sandra; Ocaña-Nápoles, Leyanis; Oyarzábal-Yera, Ambar; González-Núñez, Lucía; Breña-Betancourt, Giselle; Pérez-Pino, María Flavia; Medina-Pírez, José A.; Jiménez-Despaigne, Sonia; Molina-Cuevas, Vivian

doi:10.1590/2175-8239-JBN-2021-0048

Abstract

Introduction:

Aminoglycoside-induced acute kidney injury (AKI) is a pathology closely linked to oxidative and inflammatory reactions. Taking into account the previous reported antioxidant and anti-inflammatory effects of D-005, a lipid extract obtained from Cuban palm Acrocomia crispa (Arecaceae) fruits, this work aimed to evaluate the effects of D-005 on kanamycin-induced AKI.

Methods:

Male Wistar rats were divided into 7 groups: negative control (vehicle, Tween 65/H2O) and six groups treated with kanamycin to induce AKI: positive control (vehicle), D-005 (25, 100, 200, and 400 mg/kg) and grape seed extract (GSE, 200 mg/kg). D-005, vehicle, and GSE oral treatments were administered once daily for seven days, 1 h before kanamycin (500 mg/kg, i.p.). Serum uric acid and urea concentrations, renal histopathology, and oxidative markers (malondialdehyde (MDA), sulfhydryl (SH) groups, and catalase (CAT) activity) were assessed.

Results:

D-005 significantly reduced uric acid and urea levels, starting from D-005 100 mg/kg. Histopathologically, D-005, at all the tested doses, protected renal parenchyma structures (glomeruli, proximal tubules, and interstitium). These findings were accompanied by a significant reduction of MDA and SH group concentrations as well as restoration of CAT activity. The highest percentages of inhibition were obtained with the dose of 400 mg/kg. GSE, the reference substance, also prevented kanamycin-induced biochemical and histopathological changes, as well as reduced MDA and SH groups and restored CAT activity.

Conclusion:

The administration of repeated oral doses of D-005 significantly protected against kanamycin-induced AKI, which could be associated with the antioxidant and anti-inflammatory effects of this extract.

Keywords:
Acrocomia crispa ; Renal Toxicity; Aminoglycoside Antibiotics; Oxidative Stress; Inflammation

Resumo

Introdução:

Lesão renal aguda induzida por aminoglicosídeos é uma patologia intimamente ligada a reações oxidativas e inflamatórias. Considerando efeitos antioxidantes e anti-inflamatórios relatados anteriormente do D-005, um extrato lipídico de frutos da palmeira cubana Acrocomia crispa (Arecaceae), este trabalho avaliou efeitos do D-005 na LRA induzida por canamicina.

Métodos:

Dividiu-se ratos Wistar machos em 7 grupos: controle negativo (veículo, Tween 65/H2O) e seis grupos tratados com canamicina para induzir LRA: controle positivo (veículo), D-005 (25, 100, 200, 400 mg/kg) e extrato de semente de uva (ESU, 200 mg/kg). D-005, veículo, e tratamentos orais com ESU foram administrados uma vez por dia durante sete dias, 1 h antes da canamicina (500 mg/kg, i.p.). Avaliou-se concentrações séricas de ácido úrico e ureia, histopatologia renal e marcadores oxidativos (malondialdeído (MDA), grupos sulfidrila (SH), atividade de catalase (CAT)).

Resultados:

D-005 reduziu significativamente níveis de ácido úrico e ureia, partindo de D-005 100 mg/kg. Histopatologicamente, D-005, em todas as doses testadas, protegeu estruturas do parênquima renal (glomérulos, túbulos proximais e interstício). Estes achados foram acompanhados por uma redução significativa das concentrações de MDA e grupo SH, e pela restauração da atividade CAT. As maiores porcentagens de inibição foram obtidas com a dose de 400 mg/kg. ESU, a substância de referência, também evitou alterações bioquímicas e histopatológicas induzidas por canamicina, reduziu MDA e grupos SH e restaurou atividade CAT.

Conclusão:

A administração de doses orais repetidas de D-005 protegeu significativamente contra LRA induzida por canamicina, que pode estar associada aos efeitos antioxidantes e anti-inflamatórios deste extrato.

Descritores:
Acrocomia crispa ; Toxicidade; Renal; Antibióticos Aminoglicosídeos; Estresse oxidativo; Inflamação

Introduction

Acute kidney injury (AKI) is a clinical syndrome of varied etiology characterized by a sudden decrease in kidney function, accumulation of waste metabolites, water-mineral imbalance, and systemic symptoms. It is a common problem in intensive care medicine since a moderate AKI increases the risk of death by approximately five times¹1 Nie S, Tang L, Zhang W, Feng Z, Chen X. Are there modifiable risk factors to improve AKI?. BioMed Res Int. 2017;2017:5605634.^,²2 Santos RPD, Carvalho ARDS, Peres LAB, Delfino VDA, Grion CMC. Non-recovery of renal function is a strong independent risk factor associated with mortality in AKI patients. Braz J Nephrol. 2020;42(3):290-9..

Several drugs usually used in the clinical setting, including aminoglycoside antibiotics (AMGs), contribute to AKI due to their nephrotoxic side effects. AKI induced by AMG treatment has a worldwide incidence of 5 to 15 %, appearing 7 to 10 days after starting the administration of the AMG. The immediate clinical manifestations are: oliguria with dysfunction of renal excretion and increased serum creatinine, urea, and other metabolic products³3 Khalili H, Bairami S, Kargar M. Antibiotics induced acute kidney injury: incidence, risk factors, onset time and outcome. Acta Med Iran. 2013;51(12):871-8..

The accumulation of AMG in the tubular epithelium triggers the initial phase of AKI leading to a complex interrelation of vascular and tubular processes causing kidney dysfunction. Tubular toxicity by AMG is mainly characterized by several pathological changes in tubular epithelial cells in the proximal segment, associated with an important inflammatory component followed by non-lethal functional alterations of key components involved in the transport of water and solutes⁴4 Lopez-Novoa JM, Quiros Y, Vicente L, Morales AI, Lopez-Hernandez FJ. New insights into the mechanism of aminoglycoside nephrotoxicity: an integrative point of view. Kidney Int. 2011 Jan;79(1):33-45.^,⁵5 Karasawa T, Steyger PS. Intracellular mechanisms of aminoglycoside-induced cytotoxicity. Integrat Biol (Camb). 2011 Sep;3(9):879-86..

As a consequence of AMG-induced tubular cell damage, some epithelial cells detach leading to formation of casts, composed of cells and proteins, into tubular lumens. The casts obstruct tubular lumens, causing an increase in intratubular pressure, which reduces the excretory function of affected nephrons and elevates the hydrostatic pressure in the Bowman's capsule, thus decreasing glomerular filtration rate. Furthermore, higher intratubular pressure promotes the leakage of filtrate into the interstitial space and peritubular capillaries and lowers the excretion of the filtered products⁴4 Lopez-Novoa JM, Quiros Y, Vicente L, Morales AI, Lopez-Hernandez FJ. New insights into the mechanism of aminoglycoside nephrotoxicity: an integrative point of view. Kidney Int. 2011 Jan;79(1):33-45..

Renal vasculature and glomerular filtration function are also affected by AMGs through stimulation of mesangial cell contraction, proliferation, and apoptosis. These processes are mediated by the elevation of cytosolic calcium, oxidative stress, inflammation, and vasoconstrictor release. Moreover, reduced blood flow and glomerular filtration rate may contribute to aggravate AMG-induced tubular damage by probably limiting the availability of oxygen and nutrients, and at the same time, facilitating oxidative stress, similar to ischemic AKI⁴4 Lopez-Novoa JM, Quiros Y, Vicente L, Morales AI, Lopez-Hernandez FJ. New insights into the mechanism of aminoglycoside nephrotoxicity: an integrative point of view. Kidney Int. 2011 Jan;79(1):33-45..

AMG-induced AKI is fatal in some cases. However, patients can survive due to the regenerative capability of tubular cells, which allows them to recover as soon as AMG treatment is stopped⁶6 Alexandridis G, Liberopoulos E, Elisaf M. Aminoglycoside-induced reversible tubular dysfunction. Pharmacology. 2013 Mar;67(3):118-20.. However, even though AKI may be reversible, some patients do not completely recover and usually develop a chronic kidney disease⁷7 Venkatachalam MA, Weinberg JM, Kriz W, Bidani AK. Failed tubule recovery, AKI-CKD transition, and kidney disease progression. J Am Soc Nephrol. 2015 Aug;26(8):1765-76..

Up to now, there is no effective therapeutic alternative to prevent AMG renal toxicity in clinical practice and current treatments are not able to prevent the progression of AKI towards chronic kidney disease. In this context, it is necessary to search for new alternatives contributing to accelerate the regeneration of renal tubular cells and prevent AKI.

Diverse natural and synthetic substances have displayed beneficial actions on AKI induced by AMGs. Antioxidant agents are among the best candidates due to their efficacy in preventing the generation of reactive oxygen species⁸8 Vicente-Vicente L, Casanova AG, Hernández-Sánchez MT, Pescador M, López-Hernández FJ, Morales AI. A systematic meta-analysis on the efficacy of pre-clinically tested nephroprotectants at preventing aminoglycoside nephrotoxicity. Toxicology. 2017 Feb;377:14-24.

9 Mahi-Birjand M, Yaghoubi S, Abdollahpour-Alitappeh M, Keshtkaran Z, Bagheri N, Pirouzi A, et al. Protective effects of pharmacological agents against aminoglycoside-induced nephrotoxicity: a systematic review. Expert Opin Drug Saf. 2020 Feb;19(2):167-86.^-¹⁰10 Casanova AG, Vicente-Vicente L, Hernández-Sánchez MT, Pescador M, Prieto M, Martínez-Salgado C, et al. Key role of oxidative stress in animal models of aminoglycoside nephrotoxicity revealed by a systematic analysis of the antioxidant-to-nephroprotective correlation. Toxicology. 2017 Jun;385:10-7.. According to this approach, extracts obtained from plants belonging to Arecaceae family, such as Cocos nucifera and Phoenix dactylifera, have prevented gentamicin-induced AKI in rats¹¹11 Jose SP, Asha S, Krishnakumar IM, Ratheesh M, Savitha S, Sandya S, et al. Nephro-protective effect of a novel formulation of unopened coconut inflorescence sap powder on gentamicin induced renal damage by modulating oxidative stress and inflammatory markers. Biomed Pharmacother. 2017 Jan;85:128-35.^,¹²12 Celik OY, Irak K. Protective effect of date extract on rat nephrotoxicity induced by gentamicin, clinical, histological and antioxidant evidences. Cell Mol Biol (Noisy-le-Grand). 2018 Nov;64(14):108-13..

D-005, a saponified lipid extract obtained from the fruit of Acrocomia crispa, endemic palm of Cuba of the Arecaceae family, contains a reproducible mixture of fatty acids, mainly oleic, palmitic, lauric, and myristic while palmitoleic, caprylic, capric, and stearic acids are found in lower concentrations¹³13 González VL, Sierra R, Mas R, Pérez Y, Oyarzábal A, Rodríguez E, et al; inventor. Centro Nacional de Investigaciones Cientificas (CNIC); assignee. Compounds from the fruits of Acrocomia crispa and Acrocomia aculeata for use against oxidative stress and inflammation. Patent CU WO2013/189467 A2. 2015 Mar 16.^,¹⁴14 Sierra-Pérez RC, González-Canavaciolo VL, Rodríguez-Leyes EA, Marrero-Delange D, Vicente-Murillo R, Morales-Rico CL. Estudio fitoquímico de los frutos de Acrocomia crispa, palma endémica cubana. Rev CENIC Cienc Quím. 2014;45:41-7..

Recently, D-005 has shown to prevent pathological changes induced by kidney ischemia/reperfusion in rats, by diminishing serum concentrations of creatinine, uric acid, and urea and lessening tubular histopathological changes in kidney cortex. This was linked to D-005 antioxidant effects, since it decreased the concentrations of malondialdehyde (MDA) and sulfhydryl (SH) groups in plasma and kidney homogenate, as well as it has restored catalase (CAT) enzymatic activity in the kidney¹⁵15 Oyarzábal-Yera A, Rodríguez-Salgueiro S, Merino-García N, Ocaña-Nápoles L, González-Núñez L, Mena-Valdés L, et al. Protective effects of D-005, a lipid extract from Acrocomia crispa fruits, against ischemia/reperfusion-induced acute kidney injury in rats. Kidney Res Clin Pract. 2019;38(4):462-71..

In addition, previous studies revealed that D-005 exerts anti-inflammatory effects in vitro and in vivo by inhibiting the enzymes 5-lipooxygenase (5-LOX) and cyclooxygenase type 2 (COX-2) and preventing inflammatory infiltration during acute lung damage in mice¹⁶16 Pérez Y, Oyarzábal A, Sierra R, Mas R, Molina V, Jiménez S, et al. Inhibition of cyclooxygenase (COX) and 5-lipoxygenase (5-LOX) by D-005 (a lipid extract of Acrocomia crispa fruits). Bol Latinoam Caribe Plant Med Aromat. 2017;16(3):319-28.^,¹⁷17 Mena L, Sierra R, Valle M, Molina V, Rodriguez S, Merino N, et al. Acrocomia crispa fruits lipid extract prevents LPS-induced acute lung injury in mice. Bol Latinoam Caribe Plant Med Aromat. 2019;18(1):16-26..

Taking into account the crucial role played by oxidative stress and inflammation in the pathophysiology of AMG-induced AKI, as well as the previous antioxidant and anti-inflammatory effects of D-005, this work aimed to evaluate the effects of D-005 on kanamycin-induced AKI.

Materials and Methods

Preparation of extracts

D-005 was obtained from previously authenticated Acrocomia crispa ripe fruits (No. 1982-1031, National Botanical Garden, Havana, Cuba) at Laboratory of Pharmaceutical Chemistry, Natural Products Center (CPN) belonging to the National Center for Scientific Research (CNIC), Havana, Cuba. In brief, the fruits were air-dried, milled at 2.36 mm, and extracted with n-hexane at room temperature. Then, solvent was removed at 60 °C under vacuum, in a rotary evaporator, and the resulting oil was saponified at reflux with a hydro alcoholic potassium hydroxide solution (0.5 mol/L). Next, the fatty acids were released with HCl (10 %) until pH 1-2, and the organic phase was washed with water and dried under vacuum at 110 °C¹³13 González VL, Sierra R, Mas R, Pérez Y, Oyarzábal A, Rodríguez E, et al; inventor. Centro Nacional de Investigaciones Cientificas (CNIC); assignee. Compounds from the fruits of Acrocomia crispa and Acrocomia aculeata for use against oxidative stress and inflammation. Patent CU WO2013/189467 A2. 2015 Mar 16.^,¹⁴14 Sierra-Pérez RC, González-Canavaciolo VL, Rodríguez-Leyes EA, Marrero-Delange D, Vicente-Murillo R, Morales-Rico CL. Estudio fitoquímico de los frutos de Acrocomia crispa, palma endémica cubana. Rev CENIC Cienc Quím. 2014;45:41-7..

D-005 batch thus obtained (Batch S-291215) was characterized by gas chromatography, being its fatty acid composition: lauric (41.77 %), oleic (28.10 %), myristic (12.57 %), palmitic (7.83 %), stearic (2.93 %), capric (3.33 %), caprylic (1.73 %), and palmitoleic (0.05%) acids, for a total content of fatty acids of 98.30 %. D-005 was suspended in Tween 65/H₂O (2 %) just before using.

Grape seed extract (GSE) was used as a reference substance (95 % proanthocyanidin), Batch: R3992407, from Blackmores (Sydney, Australia). GSE was dissolved in acacia gum/H₂O (1 %) prior to rat administration.

Animals and experimental protocol

Male Wistar rats (250-300 g) from the National Center for the Production of Laboratory Animals (CENPALAB, Havana, Cuba) were used. Rats were acclimated for 7 days to controlled laboratory conditions (25 ± 2 °C temperature, 60 ± 5 % relative humidity, and 12 hours light/dark cycle) and free access to food and water (standard feed for rodents from CENPALAB). After this period, they were classified as suitable for experimental use. The handling of the animals was carried out according to the Cuban Guidelines for Animal Handling and the Cuban Code of Good Laboratory Practices. The independent ethical board of CPN approved the animal use and study protocols (approval number 007/2018 signed on November 29, 2018).

Rats were randomized into 7 groups (10 rats/group): a negative control (treated with vehicle, Tween 65/H₂O) and six groups which were administered kanamycin to induce AKI: a positive control group treated with Tween 65/H₂O, four groups treated with D-005 (25, 100, 200, and 400 mg/kg) and one group treated with GSE (200 mg/kg). The dosage schedule of D-005 was based on its antioxidant and anti-inflammatory previous effects¹⁵15 Oyarzábal-Yera A, Rodríguez-Salgueiro S, Merino-García N, Ocaña-Nápoles L, González-Núñez L, Mena-Valdés L, et al. Protective effects of D-005, a lipid extract from Acrocomia crispa fruits, against ischemia/reperfusion-induced acute kidney injury in rats. Kidney Res Clin Pract. 2019;38(4):462-71.. The chosen dose of GSE has shown antioxidant effects in previous studies and it falls within the range of doses previously used in nephrotoxicity models¹⁸18 Yera AO, Cuevas VM, Ferreiro RM, Despaigne SJ, Sánchez DC. Effects of D-002, a grape seed extract and their combined therapy on oxidative markers in rats. REDVET - Rev Electrônica Vet. 2012;13:1-13.

19 Abdel-Hafez SMN, Rifaai RA, Elzaher WYA. Mechanism of grape seeds extract protection against paracetamol renal cortical damage in male Albino rats. Bratisl Med J. 2017;118(4):233-42.^-²⁰20 Gao Z, Liu G, Hu Z, Li X, Yang X, Jiang BEI, et al. Grape seed proanthocyanidin extract protects from cisplatin-induced nephrotoxicity by inhibiting endoplasmic reticulum stress-induced apoptosis. Molecular Med Rep. 2014;9(3):801-7.. D-005, the vehicle, and GSE were administered orally by intragastric gavage in order to guarantee that rats receive the exact dose and according to previous studies¹⁵15 Oyarzábal-Yera A, Rodríguez-Salgueiro S, Merino-García N, Ocaña-Nápoles L, González-Núñez L, Mena-Valdés L, et al. Protective effects of D-005, a lipid extract from Acrocomia crispa fruits, against ischemia/reperfusion-induced acute kidney injury in rats. Kidney Res Clin Pract. 2019;38(4):462-71.^,²¹21 Salem NA, Salem EA. Renoprotective effect of grape seed extract against oxidative stress induced by gentamicin and hypercholesterolemia in rats. Renal Fail. 2011;33(8):824-32.. All treatments were administered once daily for seven days.

AKI was induced by daily injections with kanamycin (kanamycin sulfate, 500 mg/kg, i.p.) during seven days concurrently with the course of D-005, vehicle, and GSE treatments, 1 h after receiving the treatments with D-005, vehicle, and GSE. Twenty-four hours after the last treatment (day 8^th, rats were anesthetized using sodium thiopental (30 mg/kg) and blood samples were taken from the abdominal aorta for blood biochemistry (serum concentrations of uric acid and urea) and determination of oxidation parameters (concentrations of MDA and SH groups as well as CAT activity). Immediately, both kidneys were removed; the left one was used for histopathological analysis and the right one was used for the determination of the oxidation parameters. Kidneys used for biochemical analysis were homogenized using a blade homogenizer (Ultra-Turrax) in an ice bath and a suitable buffered solution according to the technique to be performed. The homogenized samples were stored at -20 °C.

Blood biochemistry determinations

Uric acid and urea concentrations were measured in serum samples using Spinreact Signature reagent kits in an UV-Genesys 10S Spectrophotometer. The uric acid readings were made at 520 nm and reported as µmol/L, whereas urea readings were made at 340 nm and reported as mg/dL.

Histopathological processing and analysis

Kidneys were sectioned through the hilum following the sagittal plane and immediately immersed in 4 % buffered formalin. Subsequently, samples were subjected to ethanol, xylol and paraffin passes. Then, they were embedded in paraffin blocks and 3 µm-thick sections were obtained using a Sakura microtome. Two histological slides per animal were prepared: one slide was stained with hematoxylin and eosin, and the second one with periodic Schiff's acid (PAS) ²²22 Salama AD, Cook HT. The renal biopsy. In: Taal MW, Chertow GM, Marsden PA, Sckorecki K, Yu A SL, eds. Brenner and rector's the kidney. 9th ed. Philadelphia: Saunders; 2011. p. 2962..

Histopathological analysis was performed from the upper to the lower pole of each kidney hemi-section. Morphology of glomeruli and proximal tubules, as well as the condition of the interstitium, were studied by means of a Zeiss Primo Star light microscope. The following variables were assessed:

Glomerular damage: evaluated using the following 0-2 scores: 0: normal appearance; 1: mesangial expansion (wide, strongly stained areas in the mesangium) and/or mesangial hypercellularity (presence of more than three nuclei in the mesangium); 2: glomerular tuft retraction with increased Bowman's space.
Tubular damage: assessed using the following 0-4 scores: 0: normal structure; 1: some tubules with damaged or necrotic cells; 2: isolated areas of tubular necrosis; 3: frequent areas of tubular necrosis; 4: widespread or diffuse necrosis.
Interstitial damage: evaluate by the presence or absence of inflammatory cells in the interstitium using the following scores (0-2): 0: absence of inflammatory cells; 1: scarce inflammatory cells (1-5 cells per field); 2: abundant inflammatory cells (more than 5 cells/field).
Global renal damage: calculated from the sum of the values of glomerular damage, tubular damage, and interstitial damage assigned to each animal.

Determination of the mda concentration

The determination of thiobarbituric acid reactive substances (TBARS) was carried out according to a previous described technique²³23 Ohkawa O, Ohishi I, Yagi K. Assay of lipid peroxides in animal tissues by the thiobarbituric acid reaction. Anal Biochem. 1979 Jun;95(2):351-8.. Briefly, the reaction mixture (plasma or kidney homogenate) was treated with 0.2 mL sodium dodecyl sulfate (SDS) (8.1 %), 1.5 mL of acetic acid (20 %, pH 3.5), and 1.5 mL of an aqueous solution of thiobarbituric acid (0.8 %) and then heated at 95 °C. In order to avoid the production of additional peroxidation that could constitute an error in the determination during the heating process, butylated hydroxytoluene (1 mmol/L) was added to the medium. Samples were cooled and 5 mL of an n-butanol-pyridine mixture (15:1 v/v) was added to each one. They were then vigorously shaken using a vortex, centrifuged at 4,000 rpm for 20 min. The organic layer was removed and its absorbance was read at 534 nm in a spectrophotometer. For calculations of TBARS levels, a standard curve with MDA bis(dimethyl acetal) was plotted. MDA values were reported as nmol MDA/mg of protein. Protein concentrations were obtained by the modified Lowry method²⁴24 Markwell MAK, Haas SM, Bieber LL, Tolbert N. A modification of the Lowry procedure to simplify protein determination in membrane and lipoprotein samples. Analytic Biochem. 1978 Jun;87(1):206-10..

Determination of sh group concentration

In brief, 600 µL tris-ethylenediamine tetraacetic acid buffer (20 mmol/L), pH 8.2, 40 µL 5,5-dithiobis-(2-nitrobenzoic acid) (DTNB) (10 mmol/L), and 3.16 mL ethanol (100 %) were added to an aliquot of 200 µL of the sample (plasma or kidney homogenate). The mixture was incubated during 15-20 min at room temperature and subsequently centrifuged at 3,000 rpm for 10 min. The supernatant absorbance was read at 412 nm. A blank was prepared with DTNB, and total concentration of SH was calculated using 13,600 cm-1M-1 absorptivity and reported in mmol/L²⁵25 Hu ML. Measurement of protein thiol groups and glutatione in plasma. Methods Enzymol. 1994;233:380-2..

Assessments of cat activity

Firstly, H₂O₂ removal was controlled at 240 nm for 5 min in a spectrophotometer. To 10 µL of sample (plasma or kidney homogenate), 2.89 mL potassium phosphate buffer (50 mmol/L, pH 7.4) was added. The reaction started by adding 0.1 mL H₂O₂ to a final volume of 3 mL at 25 °C. CAT activity was calculated by the molar extinction coefficient (43.6 × 10^-3 and was expressed in IU/min mg of protein × 10^-1 ²⁶26 Aebi H. Catalase. In: Bergmeyer HU, ed. Methods of enzymatic analysis. New York: Academic Press; 1974. p. 673-80..

The inhibition percentages of D-005 and GSE groups for the variables uric acid, urea, global kidney damage, MDA, and SH groups were calculated using the following formula:

I = 100 - \frac{(T - NC) x 100}{PC - NC}

wherein: I is inhibition, T is treated group mean, NC is Negative control mean, and PC is Positive control mean.

For CAT activity, the restoration percentages of D-005 and GSE groups were calculated using the following formula:

R = 100 - \frac{(NC - T) x 100}{NC - PC}

wherein: R is restoration, T is treated group mean, NC is Negative control mean, PC: Positive control mean.

Statistical analysis

Comparisons between groups was performed using the non-parametric Mann Whitney U test. Differences were considered statistically significant at a value of p<0.05. Statistical analyses were performed using the Prism 5.0 software for Windows (Graphpad Software Inc., San Diego, CA, USA). Dose/effect relationship analyses were based on the linear regression and correlation method using Origin software version 5.0, Microcal Software, Inc. 1991-1997.

Results

Effects of D-005 on aki biomarkers

Kanamycin caused a marked and significant increase on uric acid and urea serum levels in the positive control group compared to the negative control group. GSE, used as a reference substance, markedly and significantly decreased the concentrations of uric acid and urea, compared to the positive control, reaching 93.0 and 64.3 % inhibition, respectively (Table 1).

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Table 1
Effects of D-005 on serum creatinine and uric acid concentrations in rats with kanamycin-induced acute kidney injury

D-005 significantly diminished in a dose-dependent way the increase in uric acid (p = 0.023, r = 0.976) and urea (p = 0.039, r = 0.960) serum levels, starting from the dose of 100 mg/kg and reaching the highest percentages of inhibition at 400 mg/kg (96.6 % in uric acid and 70.3 % in urea) (Table 1).

Effects of D-005 on renal histopathology

The normal structure of the kidney parenchyma was observed in the rats of the negative control group, showing prominent PAS-positive brush borders in proximal tubules (Figure 1A). Rats belonging to the positive control group presented an increased glomerular mesangium, mesangial hypercellularity, and on occasions, retraction of glomerular tuft with enlarged Bowman's space, loss of brush borders and frequent tubular necrosis, as well as peritubular inflammatory infiltrate in the middle zone of kidney cortex (Figure 1B).

Figure 1
Renal cortex of rats with PAS staining. A representative image of each experimental group is shown. A) Negative control, B) Positive control (Kanamycin), C) Grape seed extract (200 mg/kg) + Kanamycin, D) D-005 25 mg/kg + Kanamycin, E) D-005 400 mg/kg + Kanamycin. Bars- 100 µm. G: glomeruli; TP: proximal tubules; *tubular necrosis; rectangle in B encloses peritubular inflammatory infiltrate (insert at higher magnification in the upper right corner).

Additionally, the positive control group displayed marked and significant increase in histopathological scores of glomerular, tubular, and interstitial damage, as well as global kidney damage, which was obtained by the contribution of these three variables (Tables 2 and 3).

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Table 2
Effects of D-005 on renal histopathological scores of glomerular, tubular and interstitial damages in rats with kanamycin-induced acute kidney injury

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Table 3
Effects of D-005 on global renal damage in rats with kanamycin-induced acute kidney injury

GSE, the reference substance in this study, partially prevented kanamycin-induced histopathological changes in kidney structures, showing numerous proximal tubules with well-preserved brush borders (Figure 1C). GSE was also found to significantly prevent increased glomerular, tubular, and interstitial damage scores, as well as kanamycin-induced global kidney damage (Tables 2 and 3).

Treatments with D-005, from the lowest dose evaluated, protected kidney parenchyma structures (glomeruli, proximal tubules, and interstitium) from the injury induced by kanamycin (Figure 1D, E) and caused a significant decrease of the histopathological variables: glomerular, tubular, and interstitial damage, as well as global kidney damage. The effects of D-005 over interstitial and global kidney damages were dose-dependent (p = 0.020, r = 0.980 and p = 0.057, r = 0.942, respectively). The highest percentages of inhibition were obtained with the dose of 400 mg/kg of D-005 in both variables (Tables 2 and 3).

Effects of d-005 on oxidative stress markers

Rats in the positive control group, treated with kanamycin, achieved significantly higher values of MDA and SH groups, as well as a depletion of CAT activity compared to the negative control, both in plasma and kidney homogenate (Tables 4 and 5).

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Table 4
Effects of D-005 on plasma MDA and SH group concentrations and CAT activity in rats with kanamycin-induced acute kidney injury

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Table 5
Effects of D-005 on MDA and SH groups concentrations and CAT activity in kidney homogenate in rats with kanamycin-induced acute kidney injury injury

The reference substance (GSE) significantly decreased MDA and SH group concentrations and partially restored CAT activity in plasma and kidney homogenate (Tables 4 and 5).

D-005 at all the tested doses (25, 100, 200, and 400 mg/kg) significantly diminished the increase in MDA concentration in both plasma and kidney homogenate, reaching highest percentages of inhibition at doses of 400 mg/kg in plasma and 200 mg/kg in tissue sample (76.5 and 100 % respectively) (Tables 4 and 5).

In addition, D-005 significantly decreased SH groups in a dose-dependent manner both in plasma (p = 0.012, r = 0.987) and kidney homogenate (p = 0.025, r = 0.975), being the highest percentage of inhibition at the dose of 400 mg/kg (88.5 % in plasma and 99.01 % in kidney homogenate) (Tables 4 and 5).

The effects of D-005 (25-400 mg/kg) on CAT activity in plasma and kidney homogenate are also shown in Tables 4 and 5. D-005, from the lowest dose tested, restored CAT activity in a significant and dose-dependent manner (p = 0.039, r = 0.960 in plasma and p = 0.019, r = 0.981 in kidney homogenate), reaching the highest recovery percentage at the dose of 400 mg/kg (97.02 % in plasma and 69.6 % in kidney homogenate).

Discussion

The results of this study demonstrate the protective effect of repeated oral doses of D-005 on kanamycin-induced AKI.

The biochemical and histopathological changes in the positive control group (kanamycin-treated rats) is in accordance to those described by other authors under similar conditions²⁷27 Kilany OE, Abdou RH, El-Beltagy MA, Mohammad HM. Protective effects of Tribulus terrestris against gentamicin mediated nephrotoxicity, oxidative damage and apoptosis in male rats. Egyptian Academic J Biol Sci B. Zool. 2020;12(1):41-58.^,²⁸28 González-Núñez L, Rodríguez-Salgueiro S, Ocaña-Nápoles L, Oyarzábal-Yera A, Medina-Pírez JA, Pentón-Rodríguez O, et al. Histopathological changes in two models of acute kidney injury. Microsc Microanal. 2020 Apr;26(Suppl 1):S73-S4.. The increase in serum concentrations of uric acid and urea in this group indicates a decrease in the glomerular filtration rate, which constitutes a hallmark of AKI²⁹29 Kaushik M, Choo JCJ. Serum uric acid and AKI: is it time?. Clin Kidney J. 2016 Feb;9(1):48-50.

30 Chawla LS, Bellomo R, Bihorac A, Goldstein SL, Siew ED, Bagshaw SM, et al. Acute kidney disease and renal recovery: consensus report of the Acute disease quality initiative (ADQI) 16 Workgroup. Nature Rev Nephrol. 2017 Feb;13:241-57.^-³¹31 Bao YW, Yuan Y, Chen JH, Lin WQ. Kidney disease models: tools to identify mechanisms and potential therapeutic targets. Zool Res. 2018 Mar;39(2):72-86., being the increase of urea in the Positive control group in agreement with values reported in diverse animal models of aminoglycoside-induced AKI⁸8 Vicente-Vicente L, Casanova AG, Hernández-Sánchez MT, Pescador M, López-Hernández FJ, Morales AI. A systematic meta-analysis on the efficacy of pre-clinically tested nephroprotectants at preventing aminoglycoside nephrotoxicity. Toxicology. 2017 Feb;377:14-24..

Moreover, although the serum creatinine-concentration quantification constitutes the gold standard in the clinical diagnosis of AKI, in the model of aminoglycoside-induced nephrotoxicity diagnosis is better established by the increase in urea concentration -sometimes expressed as BUN - since urea increases 60 times more than creatinine in this type of experimental damage⁸8 Vicente-Vicente L, Casanova AG, Hernández-Sánchez MT, Pescador M, López-Hernández FJ, Morales AI. A systematic meta-analysis on the efficacy of pre-clinically tested nephroprotectants at preventing aminoglycoside nephrotoxicity. Toxicology. 2017 Feb;377:14-24.^,¹⁰10 Casanova AG, Vicente-Vicente L, Hernández-Sánchez MT, Pescador M, Prieto M, Martínez-Salgado C, et al. Key role of oxidative stress in animal models of aminoglycoside nephrotoxicity revealed by a systematic analysis of the antioxidant-to-nephroprotective correlation. Toxicology. 2017 Jun;385:10-7.. Therefore, not having quantified the creatinine concentration cannot be considered a limitation of this study.

Regarding our histopathological findings, the nephrotoxic treatment impaired the morphology of renal cortex parenchyma, which showed glomerular alterations, tubular necrosis, and inflammatory infiltrate close to necrotic tubules. These results resemble those of previous outcomes based on gentamicin nephrotoxicity models, where the death of tubular cells has been recognized as the primary event due to the entry of AMG therein, whereas the infiltration of inflammatory cells and glomerular changes are considered secondary events promoted by tubular dysfunction³²32 Randjelovic P, Veljkovic S, Stojiljkovic N, Sokolovic D, Ilic I. Gentamicin nephrotoxicity in animals: current knowledge and future perspectives. EXCLI J. 2017;16:388-99.^,³³33 Yang X, Zhong H, Xu C, Xu G. Spotlights on antibiotic-induced acute kidney injury: the evidence to date. Iran J Kidney Dis. 2019 Jan;13(1):10-20..

As expected, GSE, used as a reference substance, markedly and significantly prevented the rise of uric acid and urea serum concentrations induced by kanamycin. Likewise, GSE significantly decreased the histopathological damage of kidney structures, compared to the positive control group, in agreement with previous reports³⁴34 El-Ashmawy IM, El-Nahas AF, Salama OM. Grape seed extract prevents gentamicin-induced nephrotoxicity and genotoxicity in bone marrow cells of mice. Basic Clin Pharmacol Toxicol. 2006;99(3):230-6..

Taking into account the increase in biochemical parameters and histopathological alterations of kidney structures found in the positive control group, which are both typical of AKI, and that GSE, used as a reference substance, prevented the changes induced by kanamycin, the rat model used and the results obtained in our experimental conditions are validated.

In the present work, it was shown that D-005 partially restored glomerular filtration rate, since it decreased serum concentrations of uric acid and urea. The minimum effective dose of D-005 in both parameters was 100 mg/kg. The protection of renal function was accompanied by the preservation of renal parenchyma structures observed in the histopathological study, although the morphological protection was evidenced from the minimum D-005 dose (25 mg/kg).

Nephrotoxic treatment with gentamicin has been shown to cause an increase in COX-2 in rats and mice, which can be reversed after administration of anti-inflammatory agents such as hesperidin, alpha linolenic acid, and an extract of Hypericum perforatum³⁵35 Subramanian P, Anandan R, Jayapalan JJ, Hashim OH. Hesperidin protects gentamicin-induced nephrotoxicity via Nrf2/HO-1 signaling and inhibits inflammation mediated by NF-κB in rats. J Funct Foods. 2015;13:89-99.

36 Kaplan HM, Izol V, Aridogan IA, Olgan E, Yegani AA, Pazarci P, et al. Protective effect of alpha-linolenic acid on gentamicin induced nephrotoxicity in mice. Int J Pharmacol. 2016;12(5):562-66.^-³⁷37 Kaplan HM, Izol V, Aridogan IA, Olgan E, Yegani AA, Pazarci P, et al. Protective effect of Hypericum perforatum extract on gentamicin induced nephrotoxicity in mice. Int J Pharmacol. 2016;12:663-8.. Further studies will elucidate if the anti-inflammatory effect of D-005, histopathologically proven in this study by decreasing the infiltration of inflammatory cells in the renal parenchyma is associated, at least partially, to its dual inhibitory capacity on 5- LOX and COX-2 enzymes, similar to flavocoxid¹⁶16 Pérez Y, Oyarzábal A, Sierra R, Mas R, Molina V, Jiménez S, et al. Inhibition of cyclooxygenase (COX) and 5-lipoxygenase (5-LOX) by D-005 (a lipid extract of Acrocomia crispa fruits). Bol Latinoam Caribe Plant Med Aromat. 2017;16(3):319-28.^,³⁸38 El-Kashef DH, El-Kenawi AE, Suddek GM, Salem HA. Flavocoxid attenuates gentamicin-induced nephrotoxicity in rats. Naunyn Schmiedebergs Arch Pharmacol. 2015 Dec;388(12):1305-15..

The renal accumulation of AMGs, like kanamycin, causes direct toxic effects on tubular cells, accompanied by microvascular inflammation and ischemia, which promote ROS generation. Furthermore, the biotransformation of these drugs in the kidney is carried out by kidney enzymes such as cytochrome P-450, which also induces the generation of ROS. Accordingly, AMGs induce lipid peroxidation and renal dysfunction mediated by increased ROS, as well as iron release from the mitochondria of cortical tubular cells³⁹39 Dennis JM, Witting PK. Protective role for antioxidants in acute kidney disease. Nutrients. 2017 Jul;9(7):718.. This explains the results obtained in the present study in terms of increased concentrations of MDA and SH groups, as well as depleted CAT activity in both plasma and kidney homogenate in the positive control group.

GSE protected from kanamycin-induced oxidative damage by decreasing MDA and SH group concentrations and partially restoring CAT activity, both in plasma and kidney homogenate. The nephroprotective effects of GSE have been proven before in models of nephrotoxicity induced by other AMGs, such as amikacin and gentamicin, in relation to its anti-apoptotic and antioxidant properties³⁴34 El-Ashmawy IM, El-Nahas AF, Salama OM. Grape seed extract prevents gentamicin-induced nephrotoxicity and genotoxicity in bone marrow cells of mice. Basic Clin Pharmacol Toxicol. 2006;99(3):230-6.^,⁴⁰40 Ulusoy S, Ozkan G, Ersoz S, Orem A, Alkanat M, Yucesan FB, et al. The effect of grape seed proanthocyanidin extract in preventing amikacin-induced nephropathy. Renal Fail. 2012 Jan;34(2):227-34.. The usefulness of GSE as a reference substance is proved herein using the model of kanamycin-induced AKI.

Antioxidants are the most studied protective agents in animal models of nephrotoxicity and have been shown to be the most valuable preventive strategy against AMG-induced AKI. In this sense, the best protection results have been obtained with antioxidant extracts from plants, being administered concomitantly with the AMG, either simultaneously or as a pre-treatment on the same day¹⁰10 Casanova AG, Vicente-Vicente L, Hernández-Sánchez MT, Pescador M, Prieto M, Martínez-Salgado C, et al. Key role of oxidative stress in animal models of aminoglycoside nephrotoxicity revealed by a systematic analysis of the antioxidant-to-nephroprotective correlation. Toxicology. 2017 Jun;385:10-7.. Examples of this are the antioxidant extracts from two species of Arecaceae (Cocos nucifera and Phoenix dactylifera) exhibiting protective effects against AKI, which were administered concomitantly with gentamicin¹¹11 Jose SP, Asha S, Krishnakumar IM, Ratheesh M, Savitha S, Sandya S, et al. Nephro-protective effect of a novel formulation of unopened coconut inflorescence sap powder on gentamicin induced renal damage by modulating oxidative stress and inflammatory markers. Biomed Pharmacother. 2017 Jan;85:128-35.^,¹²12 Celik OY, Irak K. Protective effect of date extract on rat nephrotoxicity induced by gentamicin, clinical, histological and antioxidant evidences. Cell Mol Biol (Noisy-le-Grand). 2018 Nov;64(14):108-13..

Therefore, the protective effects of D-005 on AKI verified in this study could also be attributed, at least partially, to its antioxidant properties, which is supported by the decrease of lipid peroxidation and protein oxidation, showed with reduction of MDA and SH groups respectively, and the enhancement of endogenous antioxidants, by restoring CAT activity.

The antioxidant and anti-inflammatory effects of D-005 could be attributed to its content of fatty acids as lauric acid, oleic acid, and myristic acid, which have shown these effects previously⁴¹41 Marineli RS, Marques AC, Furlan CPB, Maróstica MR. Antioxidant effects of the combination of conjugated linoleic acid and phytosterol supplementation in Sprague-Dawley rats. Food Res Int. 2012;49(1):487-93.^,⁴²42 Morais SM, Nascimento JET, Silva AAS, Junior JERH, Pinheiro DCSN, Oliveira RV. Fatty acid profile and anti-inflammatory activity of fixed plant oils. Acta Sci Vet. 2017;45:1-8.. In addition, myristic acid has revealed a nephroprotective effect by reducing tubular necrosis in an experimental model of AKI⁴³43 Monserrat AJ, Cutrin JC, Coll C. Protective effect of myristic acid on renal necrosis occurring in rats fed a methyl-deficient diet. Res Exp Med (Berl). 2000 Feb;199(4):195-206.. Finally, the fact that extracts obtained from Cocos nucifera and Phoenix dactylifera, palms with fatty acid compositions similar to D-005, have demonstrated protection against gentamicin-induced nephrotoxicity supports our hypothesis¹¹11 Jose SP, Asha S, Krishnakumar IM, Ratheesh M, Savitha S, Sandya S, et al. Nephro-protective effect of a novel formulation of unopened coconut inflorescence sap powder on gentamicin induced renal damage by modulating oxidative stress and inflammatory markers. Biomed Pharmacother. 2017 Jan;85:128-35.^,¹²12 Celik OY, Irak K. Protective effect of date extract on rat nephrotoxicity induced by gentamicin, clinical, histological and antioxidant evidences. Cell Mol Biol (Noisy-le-Grand). 2018 Nov;64(14):108-13..

In this context, this study constitutes the first evidence of the nephroprotective efficacy of this mixture of fatty acids obtained from Cuban Acrocomia crispa on aminoglycosides-induced renal damage. Moreover, it was in accordance with previous results in preventing ischemia-reperfusion-induced renal damage¹⁵15 Oyarzábal-Yera A, Rodríguez-Salgueiro S, Merino-García N, Ocaña-Nápoles L, González-Núñez L, Mena-Valdés L, et al. Protective effects of D-005, a lipid extract from Acrocomia crispa fruits, against ischemia/reperfusion-induced acute kidney injury in rats. Kidney Res Clin Pract. 2019;38(4):462-71., and further studies will clarify the mechanisms by which D-005 exerts its nephroprotective effect in both models of AKI.

Overall, we can suggest that D-005 is a new substance with considerable potential benefit on AKI, either as an antioxidant supplement or as a treatment for this pathology.

In conclusion, the administration of repeated oral doses of D-005, concomitant with kanamycin, significantly protected rats from AKI, which could be related to the antioxidant and anti-inflammatory actions of this plant extract.

References

¹
Nie S, Tang L, Zhang W, Feng Z, Chen X. Are there modifiable risk factors to improve AKI?. BioMed Res Int. 2017;2017:5605634.
²
Santos RPD, Carvalho ARDS, Peres LAB, Delfino VDA, Grion CMC. Non-recovery of renal function is a strong independent risk factor associated with mortality in AKI patients. Braz J Nephrol. 2020;42(3):290-9.
³
Khalili H, Bairami S, Kargar M. Antibiotics induced acute kidney injury: incidence, risk factors, onset time and outcome. Acta Med Iran. 2013;51(12):871-8.
⁴
Lopez-Novoa JM, Quiros Y, Vicente L, Morales AI, Lopez-Hernandez FJ. New insights into the mechanism of aminoglycoside nephrotoxicity: an integrative point of view. Kidney Int. 2011 Jan;79(1):33-45.
⁵
Karasawa T, Steyger PS. Intracellular mechanisms of aminoglycoside-induced cytotoxicity. Integrat Biol (Camb). 2011 Sep;3(9):879-86.
⁶
Alexandridis G, Liberopoulos E, Elisaf M. Aminoglycoside-induced reversible tubular dysfunction. Pharmacology. 2013 Mar;67(3):118-20.
⁷
Venkatachalam MA, Weinberg JM, Kriz W, Bidani AK. Failed tubule recovery, AKI-CKD transition, and kidney disease progression. J Am Soc Nephrol. 2015 Aug;26(8):1765-76.
⁸
Vicente-Vicente L, Casanova AG, Hernández-Sánchez MT, Pescador M, López-Hernández FJ, Morales AI. A systematic meta-analysis on the efficacy of pre-clinically tested nephroprotectants at preventing aminoglycoside nephrotoxicity. Toxicology. 2017 Feb;377:14-24.
⁹
Mahi-Birjand M, Yaghoubi S, Abdollahpour-Alitappeh M, Keshtkaran Z, Bagheri N, Pirouzi A, et al. Protective effects of pharmacological agents against aminoglycoside-induced nephrotoxicity: a systematic review. Expert Opin Drug Saf. 2020 Feb;19(2):167-86.
¹⁰
Casanova AG, Vicente-Vicente L, Hernández-Sánchez MT, Pescador M, Prieto M, Martínez-Salgado C, et al. Key role of oxidative stress in animal models of aminoglycoside nephrotoxicity revealed by a systematic analysis of the antioxidant-to-nephroprotective correlation. Toxicology. 2017 Jun;385:10-7.
¹¹
Jose SP, Asha S, Krishnakumar IM, Ratheesh M, Savitha S, Sandya S, et al. Nephro-protective effect of a novel formulation of unopened coconut inflorescence sap powder on gentamicin induced renal damage by modulating oxidative stress and inflammatory markers. Biomed Pharmacother. 2017 Jan;85:128-35.
¹²
Celik OY, Irak K. Protective effect of date extract on rat nephrotoxicity induced by gentamicin, clinical, histological and antioxidant evidences. Cell Mol Biol (Noisy-le-Grand). 2018 Nov;64(14):108-13.
¹³
González VL, Sierra R, Mas R, Pérez Y, Oyarzábal A, Rodríguez E, et al; inventor. Centro Nacional de Investigaciones Cientificas (CNIC); assignee. Compounds from the fruits of Acrocomia crispa and Acrocomia aculeata for use against oxidative stress and inflammation. Patent CU WO2013/189467 A2. 2015 Mar 16.
¹⁴
Sierra-Pérez RC, González-Canavaciolo VL, Rodríguez-Leyes EA, Marrero-Delange D, Vicente-Murillo R, Morales-Rico CL. Estudio fitoquímico de los frutos de Acrocomia crispa, palma endémica cubana. Rev CENIC Cienc Quím. 2014;45:41-7.
¹⁵
Oyarzábal-Yera A, Rodríguez-Salgueiro S, Merino-García N, Ocaña-Nápoles L, González-Núñez L, Mena-Valdés L, et al. Protective effects of D-005, a lipid extract from Acrocomia crispa fruits, against ischemia/reperfusion-induced acute kidney injury in rats. Kidney Res Clin Pract. 2019;38(4):462-71.
¹⁶
Pérez Y, Oyarzábal A, Sierra R, Mas R, Molina V, Jiménez S, et al. Inhibition of cyclooxygenase (COX) and 5-lipoxygenase (5-LOX) by D-005 (a lipid extract of Acrocomia crispa fruits). Bol Latinoam Caribe Plant Med Aromat. 2017;16(3):319-28.
¹⁷
Mena L, Sierra R, Valle M, Molina V, Rodriguez S, Merino N, et al. Acrocomia crispa fruits lipid extract prevents LPS-induced acute lung injury in mice. Bol Latinoam Caribe Plant Med Aromat. 2019;18(1):16-26.
¹⁸
Yera AO, Cuevas VM, Ferreiro RM, Despaigne SJ, Sánchez DC. Effects of D-002, a grape seed extract and their combined therapy on oxidative markers in rats. REDVET - Rev Electrônica Vet. 2012;13:1-13.
¹⁹
Abdel-Hafez SMN, Rifaai RA, Elzaher WYA. Mechanism of grape seeds extract protection against paracetamol renal cortical damage in male Albino rats. Bratisl Med J. 2017;118(4):233-42.
²⁰
Gao Z, Liu G, Hu Z, Li X, Yang X, Jiang BEI, et al. Grape seed proanthocyanidin extract protects from cisplatin-induced nephrotoxicity by inhibiting endoplasmic reticulum stress-induced apoptosis. Molecular Med Rep. 2014;9(3):801-7.
²¹
Salem NA, Salem EA. Renoprotective effect of grape seed extract against oxidative stress induced by gentamicin and hypercholesterolemia in rats. Renal Fail. 2011;33(8):824-32.
²²
Salama AD, Cook HT. The renal biopsy. In: Taal MW, Chertow GM, Marsden PA, Sckorecki K, Yu A SL, eds. Brenner and rector's the kidney. 9th ed. Philadelphia: Saunders; 2011. p. 2962.
²³
Ohkawa O, Ohishi I, Yagi K. Assay of lipid peroxides in animal tissues by the thiobarbituric acid reaction. Anal Biochem. 1979 Jun;95(2):351-8.
²⁴
Markwell MAK, Haas SM, Bieber LL, Tolbert N. A modification of the Lowry procedure to simplify protein determination in membrane and lipoprotein samples. Analytic Biochem. 1978 Jun;87(1):206-10.
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²⁶
Aebi H. Catalase. In: Bergmeyer HU, ed. Methods of enzymatic analysis. New York: Academic Press; 1974. p. 673-80.
²⁷
Kilany OE, Abdou RH, El-Beltagy MA, Mohammad HM. Protective effects of Tribulus terrestris against gentamicin mediated nephrotoxicity, oxidative damage and apoptosis in male rats. Egyptian Academic J Biol Sci B. Zool. 2020;12(1):41-58.
²⁸
González-Núñez L, Rodríguez-Salgueiro S, Ocaña-Nápoles L, Oyarzábal-Yera A, Medina-Pírez JA, Pentón-Rodríguez O, et al. Histopathological changes in two models of acute kidney injury. Microsc Microanal. 2020 Apr;26(Suppl 1):S73-S4.
²⁹
Kaushik M, Choo JCJ. Serum uric acid and AKI: is it time?. Clin Kidney J. 2016 Feb;9(1):48-50.
³⁰
Chawla LS, Bellomo R, Bihorac A, Goldstein SL, Siew ED, Bagshaw SM, et al. Acute kidney disease and renal recovery: consensus report of the Acute disease quality initiative (ADQI) 16 Workgroup. Nature Rev Nephrol. 2017 Feb;13:241-57.
³¹
Bao YW, Yuan Y, Chen JH, Lin WQ. Kidney disease models: tools to identify mechanisms and potential therapeutic targets. Zool Res. 2018 Mar;39(2):72-86.
³²
Randjelovic P, Veljkovic S, Stojiljkovic N, Sokolovic D, Ilic I. Gentamicin nephrotoxicity in animals: current knowledge and future perspectives. EXCLI J. 2017;16:388-99.
³³
Yang X, Zhong H, Xu C, Xu G. Spotlights on antibiotic-induced acute kidney injury: the evidence to date. Iran J Kidney Dis. 2019 Jan;13(1):10-20.
³⁴
El-Ashmawy IM, El-Nahas AF, Salama OM. Grape seed extract prevents gentamicin-induced nephrotoxicity and genotoxicity in bone marrow cells of mice. Basic Clin Pharmacol Toxicol. 2006;99(3):230-6.
³⁵
Subramanian P, Anandan R, Jayapalan JJ, Hashim OH. Hesperidin protects gentamicin-induced nephrotoxicity via Nrf2/HO-1 signaling and inhibits inflammation mediated by NF-κB in rats. J Funct Foods. 2015;13:89-99.
³⁶
Kaplan HM, Izol V, Aridogan IA, Olgan E, Yegani AA, Pazarci P, et al. Protective effect of alpha-linolenic acid on gentamicin induced nephrotoxicity in mice. Int J Pharmacol. 2016;12(5):562-66.
³⁷
Kaplan HM, Izol V, Aridogan IA, Olgan E, Yegani AA, Pazarci P, et al. Protective effect of Hypericum perforatum extract on gentamicin induced nephrotoxicity in mice. Int J Pharmacol. 2016;12:663-8.
³⁸
El-Kashef DH, El-Kenawi AE, Suddek GM, Salem HA. Flavocoxid attenuates gentamicin-induced nephrotoxicity in rats. Naunyn Schmiedebergs Arch Pharmacol. 2015 Dec;388(12):1305-15.
³⁹
Dennis JM, Witting PK. Protective role for antioxidants in acute kidney disease. Nutrients. 2017 Jul;9(7):718.
⁴⁰
Ulusoy S, Ozkan G, Ersoz S, Orem A, Alkanat M, Yucesan FB, et al. The effect of grape seed proanthocyanidin extract in preventing amikacin-induced nephropathy. Renal Fail. 2012 Jan;34(2):227-34.
⁴¹
Marineli RS, Marques AC, Furlan CPB, Maróstica MR. Antioxidant effects of the combination of conjugated linoleic acid and phytosterol supplementation in Sprague-Dawley rats. Food Res Int. 2012;49(1):487-93.
⁴²
Morais SM, Nascimento JET, Silva AAS, Junior JERH, Pinheiro DCSN, Oliveira RV. Fatty acid profile and anti-inflammatory activity of fixed plant oils. Acta Sci Vet. 2017;45:1-8.
⁴³
Monserrat AJ, Cutrin JC, Coll C. Protective effect of myristic acid on renal necrosis occurring in rats fed a methyl-deficient diet. Res Exp Med (Berl). 2000 Feb;199(4):195-206.

Publication Dates

Publication in this collection
21 July 2021
Date of issue
Jan-Mar 2022

History

Received
01 Mar 2021
Accepted
12 May 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Nie S, Tang L, Zhang W, Feng Z, Chen X. Are there modifiable risk factors to improve AKI?. BioMed Res Int. 2017;2017:5605634.

[2] ²
Santos RPD, Carvalho ARDS, Peres LAB, Delfino VDA, Grion CMC. Non-recovery of renal function is a strong independent risk factor associated with mortality in AKI patients. Braz J Nephrol. 2020;42(3):290-9.

[3] ³
Khalili H, Bairami S, Kargar M. Antibiotics induced acute kidney injury: incidence, risk factors, onset time and outcome. Acta Med Iran. 2013;51(12):871-8.

[4] ⁴
Lopez-Novoa JM, Quiros Y, Vicente L, Morales AI, Lopez-Hernandez FJ. New insights into the mechanism of aminoglycoside nephrotoxicity: an integrative point of view. Kidney Int. 2011 Jan;79(1):33-45.

[5] ⁵
Karasawa T, Steyger PS. Intracellular mechanisms of aminoglycoside-induced cytotoxicity. Integrat Biol (Camb). 2011 Sep;3(9):879-86.

[6] ⁶
Alexandridis G, Liberopoulos E, Elisaf M. Aminoglycoside-induced reversible tubular dysfunction. Pharmacology. 2013 Mar;67(3):118-20.

[7] ⁷
Venkatachalam MA, Weinberg JM, Kriz W, Bidani AK. Failed tubule recovery, AKI-CKD transition, and kidney disease progression. J Am Soc Nephrol. 2015 Aug;26(8):1765-76.

[8] ⁸
Vicente-Vicente L, Casanova AG, Hernández-Sánchez MT, Pescador M, López-Hernández FJ, Morales AI. A systematic meta-analysis on the efficacy of pre-clinically tested nephroprotectants at preventing aminoglycoside nephrotoxicity. Toxicology. 2017 Feb;377:14-24.

[9] ⁹
Mahi-Birjand M, Yaghoubi S, Abdollahpour-Alitappeh M, Keshtkaran Z, Bagheri N, Pirouzi A, et al. Protective effects of pharmacological agents against aminoglycoside-induced nephrotoxicity: a systematic review. Expert Opin Drug Saf. 2020 Feb;19(2):167-86.

[10] ¹⁰
Casanova AG, Vicente-Vicente L, Hernández-Sánchez MT, Pescador M, Prieto M, Martínez-Salgado C, et al. Key role of oxidative stress in animal models of aminoglycoside nephrotoxicity revealed by a systematic analysis of the antioxidant-to-nephroprotective correlation. Toxicology. 2017 Jun;385:10-7.

[11] ¹¹
Jose SP, Asha S, Krishnakumar IM, Ratheesh M, Savitha S, Sandya S, et al. Nephro-protective effect of a novel formulation of unopened coconut inflorescence sap powder on gentamicin induced renal damage by modulating oxidative stress and inflammatory markers. Biomed Pharmacother. 2017 Jan;85:128-35.

[12] ¹²
Celik OY, Irak K. Protective effect of date extract on rat nephrotoxicity induced by gentamicin, clinical, histological and antioxidant evidences. Cell Mol Biol (Noisy-le-Grand). 2018 Nov;64(14):108-13.

[13] ¹³
González VL, Sierra R, Mas R, Pérez Y, Oyarzábal A, Rodríguez E, et al; inventor. Centro Nacional de Investigaciones Cientificas (CNIC); assignee. Compounds from the fruits of Acrocomia crispa and Acrocomia aculeata for use against oxidative stress and inflammation. Patent CU WO2013/189467 A2. 2015 Mar 16.

[14] ¹⁴
Sierra-Pérez RC, González-Canavaciolo VL, Rodríguez-Leyes EA, Marrero-Delange D, Vicente-Murillo R, Morales-Rico CL. Estudio fitoquímico de los frutos de Acrocomia crispa, palma endémica cubana. Rev CENIC Cienc Quím. 2014;45:41-7.

[15] ¹⁵
Oyarzábal-Yera A, Rodríguez-Salgueiro S, Merino-García N, Ocaña-Nápoles L, González-Núñez L, Mena-Valdés L, et al. Protective effects of D-005, a lipid extract from Acrocomia crispa fruits, against ischemia/reperfusion-induced acute kidney injury in rats. Kidney Res Clin Pract. 2019;38(4):462-71.

[16] ¹⁶
Pérez Y, Oyarzábal A, Sierra R, Mas R, Molina V, Jiménez S, et al. Inhibition of cyclooxygenase (COX) and 5-lipoxygenase (5-LOX) by D-005 (a lipid extract of Acrocomia crispa fruits). Bol Latinoam Caribe Plant Med Aromat. 2017;16(3):319-28.

[17] ¹⁷
Mena L, Sierra R, Valle M, Molina V, Rodriguez S, Merino N, et al. Acrocomia crispa fruits lipid extract prevents LPS-induced acute lung injury in mice. Bol Latinoam Caribe Plant Med Aromat. 2019;18(1):16-26.

[18] ¹⁸
Yera AO, Cuevas VM, Ferreiro RM, Despaigne SJ, Sánchez DC. Effects of D-002, a grape seed extract and their combined therapy on oxidative markers in rats. REDVET - Rev Electrônica Vet. 2012;13:1-13.

[19] ¹⁹
Abdel-Hafez SMN, Rifaai RA, Elzaher WYA. Mechanism of grape seeds extract protection against paracetamol renal cortical damage in male Albino rats. Bratisl Med J. 2017;118(4):233-42.

[20] ²⁰
Gao Z, Liu G, Hu Z, Li X, Yang X, Jiang BEI, et al. Grape seed proanthocyanidin extract protects from cisplatin-induced nephrotoxicity by inhibiting endoplasmic reticulum stress-induced apoptosis. Molecular Med Rep. 2014;9(3):801-7.

[21] ²¹
Salem NA, Salem EA. Renoprotective effect of grape seed extract against oxidative stress induced by gentamicin and hypercholesterolemia in rats. Renal Fail. 2011;33(8):824-32.

[22] ²²
Salama AD, Cook HT. The renal biopsy. In: Taal MW, Chertow GM, Marsden PA, Sckorecki K, Yu A SL, eds. Brenner and rector's the kidney. 9th ed. Philadelphia: Saunders; 2011. p. 2962.

[23] ²³
Ohkawa O, Ohishi I, Yagi K. Assay of lipid peroxides in animal tissues by the thiobarbituric acid reaction. Anal Biochem. 1979 Jun;95(2):351-8.

[24] ²⁴
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Treatment	Uric acid (µmol/L )	I (%)	Urea (mg/dL)	I (%)
Negative control (vehicle)	66.23 ± 7.17 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney-U test.	-	81.31 ± 4.08 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney-U test.	-
Positive control (vehicle + kanamycin)	119.48 ± 8.49	-	192.90 ± 22.47	-
D-005 (25 mg/kg) + kanamycin	104.52 ± 11.2	28.1	170.11± 22.96	20.4
D-005 (100 mg/kg) + kanamycin	83.35 ± 8.51 ^* * p<0.05;	67.8	129.20 ± 13.24 ^* * p<0.05;	57.1
D-005 (200 mg/kg) + kanamycin	69.14 ± 7.11 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney-U test.	94.5	116.01 ± 10.12 ^ p<0.01;	68.9
D-005 (400 mg/kg) + kanamycin	68.06 ± 6.51 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney-U test.	96.6	114.45 ± 9.66 ^ p<0.01;	70.3
GSE (200 mg/kg) + kanamycin	69.95 ± 4.98 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney-U test.	93.0	121.13 ± 14.37 ^* * p<0.05;	64.3

Treatment	Glomerular damage (score)	I (%)	tubular damage (score)	I (%)	Interstitialdamage (score)	I (%)
Negative control (vehicle)	0.80 ± 0.13 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	-	0.10 ± 0.10 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	-	0.0 ± 0.0 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	-
Positive control (vehicle + kanamycin)	1.90 ± 0.10	-	2.84 ± 0.23	-	1.90 ± 0.10	-
D-005 (25 mg/kg) + kanamycin	1.24 ± 0.25 ^* * p<0.05;	59.6	1.80 ± 0.29 ^* * p<0.05;	37.9	1.40 ± 0.16 ^* * p<0.05;	26.3
D-005 (100 mg/kg) + kanamycin	1.22 ± 0.25 ^* * p<0.05;	61.4	1.78 ± 0.33 ^* * p<0.05;	38.7	1.20 ± 0.29 ^* * p<0.05;	36.8
D-005 (200 mg/kg) + kanamycin	1.12 ± 0.18 ^ p<0.01;	70.6	1.71 ± 0.25^ p<0.01;	41.2	1.13 ± 0.18 ^ p<0.01;	40.5
D-005 (400 mg/kg) + kanamycin	1.10 ± 0.10 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	72.5	1.64 ± 0.12^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	43.8	1.10 ± 0.10 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	42.1
GSE (200 mg/kg) + kanamycin	1.10 ± 0.23 ^ p<0.01;	72.5	1.60 ± 0.34 ^* * p<0.05;	43.9	1.40 ± 0.16^* * p<0.05;	26.3

Treatment	Global renal damage (score)	I (%)
Negative control (vehicle)	0.90 ± 0.10 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	-
Positive control (vehicle + kanamycin)	6.54 ± 0.36	-
D-005 (25 mg/kg) + kanamycin	4.88 ± 0.38 ^* * p<0.05;	29.4
D-005 (100 mg/kg) + kanamycin	4.01 ± 0.63 ^* * p<0.05;	44.9
D-005 (200 mg/kg) + kanamycin	3.96 ± 0.35 ^ p<0.01;	45.7
D-005 (400 mg/kg) + kanamycin	3.92 ± 0.14^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	48.2
GSE (200 mg/kg) + kanamycin	4.2 ± 0.35 ^ p<0.01;	41.5

Treatment	MDA (nmol/mg of pt)	I (%)	Grupos SH (mmol/L)	I (%)	CAT (UI/min/mg of pt)	R (%)
Negative control (vehicle)	1.41 ± 0.13 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	-	0.49 ± 0.02 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	-	4.14 ± 0.40 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	-
Positive control (vehicle + kanamycin)	4.50 ± 0.24	-	0.80 ± 0.06	-	1.02 ± 0.19	-
D-005 (25 mg/kg) + kanamycin	2.99 ± 0.18 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	48.7	0.63 ± 0.04 ^* * p<0.05;	53.4	3.27 ± 0.24 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	72.2
D-005 (100 mg/kg) + kanamycin	2.85 ± 0.22 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	53.5	0.56 ± 0.03 ^ p<0.01;	75.9	3.52 ± 0.35 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	80.2
D-005 (200 mg/kg) + kanamycin	2.38 ± 0.31 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	68.5	0.54 ± 0.04 ^ p<0.01;	82.3	3.97 ± 0.18 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	94.7
D-005 (400 mg/kg) + kanamycin	2.14 ± 0.29 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	76.5	0.52 ± 0.03 ^ p<0.01;	88.5	4.04 ± 0.26 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	97.0
GSE (200 mg/kg) + kanamycin	2.22 ± 0.28 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	73.7	0.60 ± 0.02 ^ p<0.01;	64.8	3.53 ± 0.26 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U test.	80.7

Treatment	MDA (nmol/mg de pt)	I (%)	Grupos SH (mmol/L)	I (%)	CAT (UI/min/mg de pt)	R (%)
Negative control (vehicle)	1.98 ± 0.40 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	-	0.67 ± 0.02 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	-	2.13 ± 0.20 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	-
Positive control (vehicle + kanamycin)	5.69 ± 0.21	-	1.14 ± 0.06	-	0.55 ± 0.06	-
D-005 (25 mg/kg) + kanamycin	2.58 ± 0.4 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	83.7	0.89 ± 0.04 ^ p<0.01;	52.8	1.03 ± 0.10 ^ p<0.01;	30.5
D-005 (100 mg/kg) + kanamycin	2.02 ± 0.23 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	98.8	0.74 ± 0.04 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	85.5	1.42 ± 0.22 ^ p<0.01;	55.4
D-005 (200 mg/kg) + kanamycin	1.93 ± 0.21 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	100	0.71 ± 0.06 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	90.9	1.60 ± 0.24 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	66.4
D-005 (400 mg/kg) + kanamycin	1.93 ± 0.30 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	100	0.67 ± 0.05 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	99.0	1.65 ± 0.45 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	69.6
GSE (200 mg/kg) + kanamycin	2.42 ± 0.51 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	88.1	0.72 ± 0.04 ^* ***** p<0.001; Comparison with the positive control group. Mann Whitney U Test.	90.1	1.40 ± 0.30 ^ p<0.01;	53.4

Brasil

Brasil

Benefits of D-005, a lipid extract from Acrocomia crispa fruits, in the prevention of acute kidney njury induced by nephrotoxicity in rats

Abstract

Introduction:

Methods:

Results:

Conclusion:

Resumo

Introdução:

Métodos:

Resultados:

Conclusão:

Introduction

Materials and Methods

Preparation of extracts

Animals and experimental protocol

Blood biochemistry determinations

Histopathological processing and analysis

Determination of the mda concentration

Determination of sh group concentration

Assessments of cat activity

Statistical analysis

Results

Effects of D-005 on aki biomarkers

Effects of D-005 on renal histopathology

Effects of d-005 on oxidative stress markers

Discussion

References

Publication Dates

History