Commentary

The KDIGO guidelines are widely recognised and used for defining and staging CKD. They allow better communication among physicians and facilitate intervention at different stages of the disease.

Commentary

The KDIGO guidelines for AKI definition and staging constitute a combination and a compromise between different previous definitions such as the AKIN and RIFLE [15,16]. This allows better communication among physicians and facilitates intervention at different stages of the disease.

Commentary

The terms CI-AKI and CIN assume that ICM is the cause of AKI, which currently seems to occur rarely, if ever. The adjective ‘associated’ in CA-AKI makes the distinction that AKI cannot be directly attributed to ICM. In the text below, we will use the term PC-AKI, which, in our opinion, best reflects chronology and not causation.

Commentary

To adequately assess the risk of PC-AKI, it is necessary to adequately assess baseline kidney function. We recommend the assessment of the estimated glomerular filtration rate (eGFR) rather than serum creatinine or urea because it is more sensitive in addressing actual kidney function. The tools most commonly used for this purpose are the MDRD (modification of diet in renal diseases) and CKD-EPI (chronic kidney disease epidemiology) formulas. The MDRD formula is a widely used method that calculates GFR based on serum creatinine concentrations, age, gender, and ethnic origin [17]. It has been widely used, making it a familiar tool for healthcare professionals. Its main drawback is the risk of underestimating the GFR, especially in individuals with high muscle mass. Additio-nally, it is less accurate within the normal and near-normal GFR range [18]. The CKD-EPI formula takes into account the same variables as MDRD [19]. It has been shown to demonstrate a steeper relationship curve between eGFR and creatinine concentration for higher creatinine values but gentler for lower creatinine values. This characteristic makes the formula more accurate, especially for higher eGFR values.

Commentary

This recommendation follows other international guidelines, especially those issued by the European Society of Urogenital Radiology (ESUR) [20], as well as the previous recommendations of the Polish Society of Nephrology [5]. Given the lack of scientific data on the validity period of GFR assessment, they appear reasonable and should aid in correctly identifying patients at risk.

Commentary

Data on the relationship between IV ICM administration and the occurrence of AKI can still be regarded as inconclusive. Some studies suggest that the risk of PC-AKI increases with creatinine levels above 1.5 mg/dl [21] and GFR lower than 30 ml/min/1.73 m² [22]. The vast majority of recent controlled retrospective studies of PC-AKI, with the use of modern ICM, reported no excess risk of AKI among patients who underwent contrast-enhanced procedures, as compared to controls, even in patients with baseline eGFR < 30 ml/min/1.73 m² [23-29]. The ESUR guidelines assert that the risk of PC-AKI in patients with eGFR ≥ 30 ml/min/1.73 m² after IV ICM is very low [20]. Due to the lack of properly controlled prospective studies on PC-AKI from IV ICM, and the inconclusive results of retrospective studies in patients with eGFR < 30 ml/min, the thesis that the administration of ICM is associated with kidney damage in these subjects cannot be definitively rejected. In our opinion, patients with GFR ≥ 30 ml/min/1.73m² should be considered safe from PC-AKI.

Commentary

The ESUR guidelines suggest IV rehydration for patients in the at-risk group [20]. Administering 1.4% sodium bicarbonate is recommended at a dose of 3 ml/kg one hour before the administration of ICM or 0.9% saline at a dose of 1 ml/kg/h 3-4 hours before and 4-6 hours after ICM administration. However, this recommendation is based on studies with patients receiving intraarterial contrast for coronary procedures [30,31]. These will be addressed below. Regarding IV ICM, IV hydration has not been shown to be more effective than oral rehydration in patients with GFR > 30 ml per min/1.73 m² [32]. There was no significant benefit from IV hydration both in patients with eGFR of 30-59 ml/min/1.73 m² [33,34] or in patients with GFR < 30 ml/min/1.73 m² [35]. Intravenous hydration did not reduce the risk of PC-AKI, dialysis, or in-hospital morta-lity. Similarly, studies that compared isotonic saline with sodium bicarbonate did not produce decisive results. In theory, sodium bicarbonate might prevent PC-AKI by alkalising tubular fluid and reducing the production of free oxygen radicals. However, clinical studies have not confirmed its advantage over saline [36]. A similar position is presented by the Canadian Association of Radio-logists in its guidelines issued in 2022 [37]. In general, hydration should be considered depending on the clinical situation of the patient. It will be recommended in cases of clinically diagnosed dehydration, but contraindicated in overhydrated anuric AKI patients.

Commentary

Many substances, such as N-acetylcysteine, have been studied for the prevention of PC-AKI. In the case of N-acetylcysteine, a large systematic review with meta-analysis did not show its effectiveness [38].

Chronic use of statins could be effective in reducing the risk of PC-AKI in patients with renal failure and ischaemic heart disease before PCI procedures [39,40]. The mechanism of this phenomenon is not yet known but is probably related to their pleiotropic antithrombotic, anti-inflammatory, and antioxidant effects [41]. There is no evidence either for the effectiveness of high-dose statin administration shortly before contrast agent administration.

Results of recent clinical studies summarised in a metaanalysis of 13 trials including over 90,000 patients documented that chronic sodium-glucose cotransporter 2 inhibitor (SGLT2i) treatment reduced the risk of AKI both in patients with and without diabetes [42]. Results of recent observational studies suggest that chronic use of SGLT2i reduces the risk of PC-AKI [43,44]. Results of an experimental study suggest that the mechanism of this phenomenon is related to the improvement of tubular cell metabolism related to decreased oxygen consumption in renal proximal tubular cells [44]. As in the case of statins, there is no evidence for the effectiveness of SGLT2i administration shortly before contrast agent administration. Such clinical studies are undoubtedly needed.

Commentary

It should be noted that metformin has no proven effect on the development of PC-AKI, but it increases the risk of lactic acidosis. According to the latest KIDGO and American Diabetes Association (ADA) consensus, metformin is not recommended for use in patients with GFR < 30 ml/min/1.73 m², and in patients with eGFR 30-44 ml/min/1.73 m² the dose should be reduced to 1000 mg per day [45]. There is no need to stop metformin before ICM administration in this group of patients. Patients with shock and AKI have a significantly higher risk of lactic acidosis associated with metformin [46].

Although some small studies and meta-analyses have shown an association between the use of RAAS inhibitors and the risk of PC-AKI, these were based on small groups [47-49]. A meta-analysis of 12 studies indicated that discontinuation of RAAS inhibitors in patients with CKD was associated with a lower risk of PC-AKI, but a direct analysis of use vs. absence of use of RAAS inhibitors showed no significant differences [50]. Another meta-analysis based only on randomised trials did not confirm the association between RAAS inhibitors and PC-AKI [51]. It should be remembered that high doses of NSAIDs, as well as diuretics, could, in some specific circumstances (elderly patients, dehydration), accelerate the progression of CKD [52] and increase the risk of AKI [53]. However, as yet there is insufficient evidence to recommend withholding potentially nephrotoxic drugs such as NSAIDs, diuretics, antimicrobial agents, or chemotherapeutic agents before ICM administration [54].

Commentary

If, following ICM administration, any deterioration of kidney function appears, it usually occurs during the first 2-3 days following the procedure involving ICM [4]. Therefore, in at-risk in-hospital patients, it seems optimal to screen for a decrease in eGFR at this time interval. In outpatient patients, acute clinical events, such as a decrease in urine output, dyspnoea, etc., should warrant eGFR control. Patients should be informed that in such cases, they should contact the family physician or emergency department. It is recommended that prepared written information for the patients is given after a radiological procedure with ICM use.

Commentary

Intravascular contrast media can be broadly classified into 3 groups according to their osmolality, defined as the number of particles dissolved in one kilogram of water. High-osmolar-contrast media (HOCM) are 5 to 8 times the osmolality of blood (1500 to over 2000 mOsm/kg H₂O) and are no longer used in clinical practice. Newer agents, although called low-osmolar-contrast media (LOCM), have an osmolality of around 900 mOsm/kg H₂O, which is more than 3 times the osmolality of blood. Finally, iso-osmolar contrast media (IOCM), according to their name, are characterised by an osmolality of around 290 mOsm/kg H₂O. Comparisons between LOCM and IOCM in terms of their potential nephrotoxicity have produced mixed results. Some studies show that particular LOCM (as iohexol and ioxaglate) could be associated with a higher risk of PC-AKI, in comparison to IOCM (iodixanol) and some other LOCMs (ioversol, iomeprol, iopromide, iopomidol) [55-57]. However, in a large meta-analysis completed in 2017 in patients with impaired kidney function undergoing coronary angiography, the use of IOCM did not show a general difference in the incidence of PC-AKI compared to LOCM [58].

The contrast agent dose from the IOCM or LOCM group varies between 1 and 1.5 ml/kg body weight. For CT scans performed in children, the dose of contrast agent increases to 2-3 ml/kg body weight up to a maximum of 50 ml. The type, amount, and dose of contrast agent should be decided by the radiologist to achieve a reliable examination result.

Commentary

The pharmacokinetics of ICM should determine the waiting intervals between successive CT or MRI examinations [59]. In patients with normal or moderately impaired renal function (eGFR > 30 ml/min/1.73 m²), 75% of ICM is excreted within 4 hours of administration. An interval of 4 hours between ICM administrations should be maintained. Patients with severe renal impairment (eGFR < 30 ml/min/1.73 m²) should have a consecutive dose of ICM delayed by 48 hours. Iodine contrast agents and gadolinium contrast agents can be administered on the same day for routine examinations if patients have normal or moderately impaired renal function. Gadolinium contrast agents attenuate X-rays. When excreted into the urinary tract, they can cause interpretive errors in urinary CT studies. For abdominal examinations, a contrast-enhanced CT examination should be performed before a contrast-enhanced MR examination. Otherwise, for patients with advanced kidney insufficiency (eGFR < 30 ml/min/1.73m²), the interval between the administration of contrast agents of gadolinium and iodine should not be shorter than 7 days. For chest and brain examinations, the order of CT and MR examinations does not matter.

Commentary

Contrast agents used in magnetic resonance imaging are gadolinium based. They are classified according to their biochemical structure into linear and macrocyclic and further subdivided according to their charge as ionic or non-ionic character. Macrocyclic chelates are more stable than linear ones, and ionic linear chelates are more stable than non-ionic linear chelates [60]. Stability refers to the ability of the ligand to retain the Gd³⁺ ion within the complex. The free gadolinium ligand is toxic; thus, stability is the most important factor for gadolinium toxicity. Renal function has been considered a crucial determinant of gadolinium toxicity, and so-called nephrogenic systemic fibrosis (NSF) has been associated with exposure to gadolinium-based contrast agents. Nephrogenic systemic fibrosis results from impaired gadolinium-based contrast media excretion in patients with severe renal insufficiency, allowing gadolinium chelates of lower stability to dissociate, releasing free gadolinium. The condition is characterised by progressive tissue fibrosis that features thickening and hardening of the skin. In some patients, fibrosis of deeper structures can occur, within muscle, fascia, lungs, and heart [61]. The risk of NSF was found to increase in patients with CKD 4 and 5, in patients on dialysis, and in patients with AKI [62]. However, this risk differs significantly with the use of various agents, being as high as 3-11% after linear gadodiamide exposure, and practically negligible after macrocyclic gadopentetate dimeglumine [62].

Linear agents presenting with the highest risk of NSF (Gadodiamide Omniscan®, Gadopentetate dimeglumine Magnevist®) have been suspended by the European Medicines Agency (EMA) and are no longer in use. Gadoversetamide Optimark® was also withdrawn from the European market. Since this restrictive policy on the use of gadolinium-based contrast media was introduced, the reports of NSF have significantly decreased. In a systematic review of 16 studies analysing the risk of NSF in gadolinium-based contrast media with high affinity, Gd³⁺ binding (lowest-risk group) was less than 0.07% [63].

This means that contrast-enhanced MRI with low-risk gadolinium-based agents should not be avoided in patients with kidney dysfunction, because the risk of complications, including NSG, is marginal. In patients in whom an intermediate-risk agent is planned, eGFR should be assessed, and in patients with impaired renal function, such media can be used only for hepatobiliary imaging. The lowest-risk agents can be used for all MRI examinations irrespective of kidney function (Table 2). The measurement of eGFR before examination is not mandatory. The amount of contrast agent administered should guarantee good-quality imaging, irrespective of kidney function.

Commentary

To understand the potential nephrotoxicity of ICM in intraarterial administration, it is important to differentiate between first-pass and a second-pass renal exposure [20]. First-pass renal exposure indicates that ICM reaches the kidneys directly, in a relatively undiluted form. This occurs when injection is performed into the thoracic aorta or the suprarenal abdominal aorta. In clinical practice, the most common first-pass administration is associated with coronary angiography. The second pass renal exposure occurs when the contrast agent flows through the pulmonary circulation and then reaches the renal arteries. This situation most frequently occurs in interventional radiology. Obviously, first-pass renal exposure results also in second-pass renal exposure. There is solid evidence, based on randomised trials, that the risk of PC-AKI after intraarterial ICM administration with first-pass renal exposure is increased as compared to the administration of IV ICM [64,65]. The potential pathophysiological mechanisms include the multiplicity of ICM injections during an intraarterial procedure versus a single injection for a typical IV procedure, and/or the ICM volume, which is typically higher in intraarterial interventions. However, it might also be that the increased risk of AKI following intraarterial ICM is not caused by the ICM itself. Instead, other factors might be involved, such as co-morbidities and/or cholesterol microembolisation associated with catheter insertion.

In the present statement, we agree with previous guidelines from other national societies [20,37]. For procedures with an intraarterial ICM with a second-pass renal exposure, we advocate proceeding as in an IV ICM procedure. In patients, in whom an intraarterial ICM with first-pass renal exposure is administered, preventive measures are recommended for patients already with eGFR < 45 ml/min/1.73m². These include considering IV fluids, depending on the patient’s hydration status, as described above, temporal withdrawal of metformin, and a follow-up of kidney function 48 to 72 hours after exposure. Hydration is recommended in patients undergoing coronary angiography and angioplasty, where the benefits of hydration with isotonic fluids before the procedure have been proven [66,67]. A lower risk of PC-AKI was observed in patients with serum creatinine > 1.5 mg/dl rehydrated with 0.45% saline undergoing percutaneous coronary intervention [30]. In clinical practice, many interventional cardiologists use a so-called Mehran score, which takes into account the acknowledged risk factors for deterioration of kidney function: hypotension, intra-aortic balloon pump, congestive heart failure, chronic kidney disease, diabetes, age > 75 years, anaemia, and volume of contrast [68]. It is a practical tool because it not only defines high-risk groups but also indicates with good accuracy the highest contrast media volume that may be safely administered. Its applicability has been challenged recently [69], but it remains useful for everyday practice.

Commentary

Patients with AKI might be more susceptible to contrast-induced kidney damage than those without AKI, although no controlled studies report on this risk. However, in this group of patients, the risk of worsening kidney function should always be weighed against the risk derived from delayed or missed diagnoses due to the avoidance of ICM [70]. Prophylactic dialysis is not needed before or after the contrast procedure.

Commentary

The risk of PC-AKI in people with a single kidney should be classified according to overall kidney function (eGFR) and clinical circumstances. The presence of a solitary functioning kidney should not affect decision-making about the risk of PC-AKI [71].

Commentary

Based on a systematic review of 9 studies, we have learned that there is little or no effect of ICM on residual renal function in dialysis patients [72]. Therefore, the presence or absence of residual urine output should not influence the decision to use ICM in dialysis patients.