Frequently Asked Questions: Iodinated Contrast Agents

doi:10.1148/rg.24si045519

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Frequently Asked Questions: Iodinated Contrast Agents¹

Michael A. Bettmann, MD

¹ From the Department of Radiology, New York Methodist Hospital, Brooklyn, NY. Received June 3, 2004; revision requested June 23 and received July 23; accepted July 26. The author has received grant support from GE Healthcare Group and Guerbet, and has been a consultant for Bracco Diagnostics and Berlex Imaging. Address correspondence to the author, 453 Sixth St, Brooklyn, NY 11215 (e-mail: mab9099@nyp.org).

Abstract

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Abstract
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Although iodinated contrast agents are safe and widely used,adverse events occur and questions remain about their use, safety,and interactions. Some questions are easily answered and othersstill require extensive investigation. For one frequent question—isinformed consent necessary before all contrast media injections—thesimple answer is no. Another question concerns use of contrastmedia in patients with prior reactions or allergies. Contrastagents can be safely used in such patients, but special caremust be taken to be aware of what the previous reaction wasand to be ready to treat any reaction. The protective role ofpre-treatment with steroids is well established for minor reactions,but they may not prevent major reactions. It is important torealize that even life-threatening, anaphylactoid reactionsare not the result of a true allergy to contrast media. Manyquestions arise about contrast agent–induced nephropathy.Baseline serum creatinine values should be obtained in patientswho are at risk, not all patients. The incidence and naturalhistory of contrast agent–induced nephropathy remain unclear.It occurs only in patients with compromised renal function beforecontrast agent injection, but even patients with normal serumcreatinine levels can have renal dysfunction. Calculated creatinineclearance is a better way to determine risk and to follow thiscomplication. The outcome in almost all patients is benign,with progression to end-stage renal disease being rare. Themajor risk factors, in addition to renal dysfunction, are long-standingdiabetes mellitus, dehydration, and use of other nephrotoxicmedications. Recent work in preventing and ameliorating contrastagent–induced nephropathy with N-acetyl cysteine, substitutionof an isosmolal nonionic contrast agent, and various hydrationregimens has been promising. Another common concern is use ofiodinated contrast agents in pregnant or breast-feeding women.In both cases, there is no evidence of harm to the fetus orinfant, but it is prudent to weigh the theoretical risks andbenefits and avoid contrast agent administration unless it istruly necessary.

Index Terms: Contrast media • Radiology and radiologists, socioeconomic issues

Introduction

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Abstract
Introduction
Summary
References

Every radiologist is intimately familiar with contrast agents,and, with the increasing use of computed tomography (CT), thenumber of patients receiving these medications continues toincrease. This widespread use has helped engender improved understandingof contrast agents, but many questions and misunderstandingsremain. The intent of this article is to pragmatically addresssome of the main concerns that arise with the day-to-day useof iodinated contrast agents. These include the need for informedconsent and for measurement of renal function, definition ofrisk factors that may predict adverse events, how to deal withpatients who have had a prior reaction, and how to assess forand deal with contrast nephrotoxicity.

Do I Have to Obtain Consent before Contrast Material Injection?
The simple answer is no, but that is probably too simple. Ifthere were no risks associated with injection of contrast agents,or if the risks were vanishingly small, there would be no needfor consent. Conversely, if there were high risk, perhaps riskof death in one of 100 or even one of 1,000 exposures, informedconsent would be mandatory. The actual risk of death, however,is very low, less than one in 130,000 at most (1,2). The riskof other severe adverse events, such as renal failure or stroke,is also very low. An additional major consideration is thatit is becoming almost physically impossible for a physicianto obtain consent for every contrast agent injection, giventhe increasing number of CT examinations being performed.

If a lawyer were asked the above question, the answer wouldalmost invariably be yes. The definition of malpractice, however,is based on usual and customary practice, and clearly many radiologists,probably a majority, do not obtain formal informed consent.As with many areas in the practice of medicine, there are noabsolute guidelines that pertain. The compromise that is oftenused is an "information sheet" (3). It is important to rememberthat informed consent is a process, one that is intended toprovide information to both the patient and the physician. Tothis end, most such information sheets ask the patient to answercertain questions that help define a patient’s risk, suchas diabetic and renal function status, prior reaction to contrastagents (if any had been administered previously), and historyof allergies. The questions are followed by a short paragraphthat explains the risks that may be associated with contrastagent injection, including the very small risk of death or cerebrovascularaccident. The patient is also informed that if he or she hasany questions related to contrast agent use, a radiologist willbe made available to provide further information.

In summary, the injection of an iodinated contrast agent isvery safe, particularly in comparison to other situations inwhich consent is usually obtained, such as surgery or angiography."Usual and customary practice"—the practice of at leasta reasonable minority of responsible radiologists—is tonot obtain informed consent. The purpose of consent is to gatherand impart relevant information to allow the procedure to beas safe and comfortable as possible. A straightforward, one-pageinformation sheet is a practical, reasonable, and widely usedapproach.

How Should I Deal with a Patient Who Is "Allergic" to Contrast Agents?
First, although typical adverse reactions encountered afterthe administration of an iodinated contrast agent resemble allergicreactions, with signs ranging from urticaria to an anaphylactoidprocess, such reactions are not allergies. Contrast agent moleculesare small, with a molecular weight of about 850 kD, and areprobably too small to be able to act as antigens. Second, despiteextensive investigations, no antibodies to contrast agents havebeen reliably identified in patients who have had systemic,allergylike reactions. Finally, there is extensive experienceindicating that a patient who had an allergylike adverse eventafter contrast agent injection is unlikely to experience a similaror more severe reaction if contrast agent were injected again(1). In fact, although a prior reaction remains the best predictorof a future adverse event, the likelihood of a recurrent reactionis in the range of 8%–25% (1). If the previous reactionwere caused by a true allergy, the risk would approach 100%.

If the Patient Had a Prior Reaction to a Contrast Agent, Should I Ignore It, Begin a Pre-Treatment Regimen, or Avoid Any Further Contrast Agent Injection?
There is no simple answer. Many different approaches have beensuggested. It is not necessary to avoid any further contrastagent injection in most cases. A very small number of patients,anecdotally, have recurrent reactions, which seem to occur aftervarious types of contrast agents and which are not preventablewith a pre-treatment regimen. In most cases, these adverse effectsare delayed cutaneous reactions (discussed later) that may besevere but are not life threatening. Very rarely, recurrentlife-threatening reactions are reported to occur, but thesecases are both rare and poorly documented.

Use of a different contrast agent is a reasonable approach,although it is often impossible to define either the specificsof a prior reaction or the specific contrast agent used. Obtaininga careful patient history is helpful in this regard. If thepatient’s reaction occurred in the United States before1985, a nonionic, low-osmolality agent could not have been used,so one could be used now. If the reaction occurred before 1997,iodixanol, the nonionic isotonic dimer, was not available, soit could be substituted. Regardless, the two crucial factorsare the awareness of a prior reaction and the ready availabilityof equipment and expertise to treat any reaction that may occur.

The use of a pre-treatment regimen, including administrationof corticosteroids with or without antihistamines or other medications,has been proved safe (4,5). It has also been proved effective,but with the major caveat that it is effective in preventingonly minor adverse events. Prospective studies of pre-treatmenthave been too small to be able to determine whether pre-treatmentwith steroids prevents the life-threatening reactions (4,6).There is evidence from a large prospective registry, however,that they do not (1). If pre-treatment is to be used, the crucialpoints to remember are that it almost certainly won’thurt, that steroid use must begin about 12 hours before contrastagent injection to prevent even minor adverse events (4), andthat the attending radiologist and other personnel must stillbe ready to treat a reaction.

In summary, unless the patient has a clearly documented historyof multiple significant prior reactions—and this is veryrare—there is no need to refrain from injecting iodinatedcontrast media in a patient who has had a prior reaction. Pre-treatmentwith steroids almost certainly won’t harm the patient,but it will delay the procedure at least 12 hours, and it isunlikely to prevent a severe reaction. Use of a contrast agentthat the patient has not been exposed to previously may help,but being ready and able to treat a life-threatening reactionis the crucial element (7).

If a Patient Has Other Allergies or Asthma, Does It Predict an Increased Risk of an Adverse Event?
It does, but minimally. The presence of a history of multiplesevere allergies does increase the risk of a reaction followingcontrast agent injection, but only by a very small percent (1).Further, most such reactions will be minor, as are most reactionsin general. A strong history of allergies should increase awarenessof the possible risks of a reaction, but there is no need toavoid injection of contrast media. A history of asthma has alsobeen thought to be a good predictor of increased risk. Empirically,asthma appears to increase the risk only of bronchospasm, notother adverse events. The risk, again empirically, seems tobe particularly high in patients with active asthma. Fortunately,such patients are generally familiar with the use of ß-agonistinhalers and have one with them. Nevertheless, such inhalersshould always be available where contrast media are being administered.

In the past, many thought that an allergy to shellfish was apredictor of an increased risk of a reaction to a contrast agent,presumably because both shellfish and contrast agents containiodine. Such a relationship is clearly not true. Organic iodideas found in shellfish is an essential element, so individualscannot be allergic to it.

Should I Obtain Serum Urea Nitrogen and Creatinine Values for Every Patient before I Inject Contrast Media?
Not every patient is at risk of developing contrast agent–inducednephropathy, so recent values of serum urea nitrogen (ie, BUN)and creatinine are not needed in every patient. As will be discussed,the risk is confined to patients with underlying compromiseof normal renal function (8). If a patient has known renal dysfunction,it is important to have recent measurements of serum urea nitrogenand creatinine (eg, within the preceding month) to make surethat the patient’s renal function is stable. For all otherpatients, it is important to find out if they have risk factorsfor renal problems. These factors include diabetes mellitus;history of recurrent renal stones or recurrent urinary tractinfections; history of bladder outlet obstruction (eg, benignprostatic hypertrophy or bladder prolapse); recent history ofan event known to cause a risk of renal damage, such as majorsurgery, dehydration, or cardiogenic shock; and use of nephrotoxicmedications such as gentamycin, high-dose nonsteroidal anti-inflammatorydrugs, or certain chemotherapeutic drugs. It is not clear whetherthe risk related to diabetes mellitus is different for types1 and 2. The risk is probably more a function of the durationof the diabetes and the ongoing control of blood sugar level.In general, it is better to err on the side of caution and obtaina serum urea nitrogen value (as a rough guide to the level ofhydration) and a creatinine value (as an indicator of whetherthere is true renal dysfunction). The frequency with which contrastagent–enhanced examinations must be delayed because thisinformation is missing clearly depends on the patient population,the usual approach of the referring doctors, and the protocolsof the radiology department. If patients are well screened andif referring physicians are properly informed, contrast-enhancedimaging studies most likely will need to be delayed infrequently.

What about Patients Who Take Metformin?
Patients who take metformin or metformin-containing medicationspresent a different challenge for radiologists. If a patient’sblood levels of metformin are high, the patient has a risk ofdeveloping lactic acidosis, which has been reported to be fatalin about 50% of cases (9). Metformin is excreted unchanged bythe kidney; therefore, people with compromised renal functionwill have higher than expected serum levels and are at riskof developing lactic acidosis. In addition, individuals withvery poor cardiac function or acute hepatic compromise haveincreased lactate production or impaired lactate breakdown andalso are at risk of developing lactic acidosis. For all suchpatients, the use of metformin is contraindicated.

Because contrast agents are associated with nephrotoxicity,it was postulated that the concomitant use of metformin andan iodinated contrast agent could lead to an increased riskof lactic acidosis. This hypothesis has been disproved empirically,and the package insert approved by the U.S. Food and Drug Administrationhas been altered accordingly. Although the package insert isperhaps overly cautious, it states that metformin use shouldbe stopped at the time an iodinated contrast agent is administeredand that the patient should wait 48 hours before resuming useof metformin. There is no mandate to measure serum creatininelevels at that time. Rather, the patient should be reevaluatedclinically, and a creatinine value should be obtained if thereare any other reasons that the patient’s renal functionmay have been compromised, such as major surgery or cardiogenicshock (7). The major point to remember is that metformin iscontraindicated in patients with any compromise in renal function.It is surprising how often patients who take metformin and whohave elevated serum creatinine levels are referred for a contrastagent study. In these patients, the imaging study should bedelayed and the referring physician should be notified.

How Should I Deal with a Woman Who Is Pregnant or Breast-Feeding?
These concerns have been addressed by the American College ofRadiology in its recently released fifth edition of the Manualon Contrast Media (10). Because contrast media are small moleculesthat are rapidly distributed throughout the extracellular space,they must be assumed to readily cross the placental barrier.Further, contrast media molecules are most likely present inbreast milk shortly after parenteral administration to a breast-feedingpatient. There is no evidence suggesting that iodinated contrastagents are teratogenic in humans. On the other hand, the experienceis too limited to conclude that they are safe. It is, therefore,wise to avoid administering them in women who are pregnant (particularlyin the first trimester) when possible. It is appropriate, however,to use contrast agents when the procedure requiring them isthought to be essential. That is, the risks, as always, mustbe balanced against the possible benefits. Overall, the theoreticalrisks of radiation exposure are most likely greater than thoseincurred from contrast agents.

In breast-feeding women as well, the risks to the patient andto her infant must be weighed against any possible benefits.If an iodinated contrast agent is administered, the infant islikely to receive a small amount orally and then to absorb asmall amount. There is no real evidence of contrast agent–inducedtoxicity in newborns, but on the other hand there is littleconcrete information confirming the safety of these medicationsin infants. A further concern regarding the use of iodinatedcontrast agents in both pregnant and breast-feeding women isthe theoretical effect of these agents on the fetal or neonatalthyroid. Although in theory all of the iodine in contrast agentsis organically bound rather than free, it is not clear thatno free iodide is present or to what extent there is thyroiduptake in the fetus or newborn and what the effect on thyroidfunction might be. The consensus recommendation is that a breast-feedingmother should use a pump to remove breast milk before contrastagent administration, and then afterward, she should use thepump and discard breast milk for 12–24 hours before resumingnormal breast-feeding. Since the biologic half-life of iodinatedcontrast agents is less that 60 minutes, the amount remainingin the mother (assuming her renal function is normal) after12 hours is essentially undetectable.

What Is Contrast Agent– induced Nephropathy? How Is It Defined and How Often Does It Occur?
In the most general terms, contrast agent–induced nephropathyis the occurrence of renal failure, as indicated by an increasein serum creatinine level or a fall in calculated creatinineclearance, after the administration of an iodinated contrastagent. For several reasons, there is no widely accepted definitionof contrast agent–induced nephropathy. First, such nephropathyoccurs essentially only in those patients who have abnormalrenal function before contrast agent injection. Second, theparameters used clinically are imprecise. That is, serum creatininelevels vary with age, muscle mass, and gender. A serum creatininevalue of 1.2 mg/dL in a healthy 20-year-old man or woman isnormal and indicates that the glomerular filtration rate isin the normal range of 60–120 mL/min, most likely closeto or above 100 mL/min. The same serum creatinine value in a50-kg, 80-year-old woman, however, likely correlates with asignificantly decreased glomerular filtration rate, perhapseven less than 40 mL/min. This difference is because glomerularfiltration rate decreases with increasing age, and creatinineproduction, a function of muscle mass, also decreases. In short,the serum creatinine value is a reasonable screening parameter,since it is inexpensive and readily available, but it is notparticularly accurate. It is not practical to measure true creatinineclearance, but it is helpful to use a formula, such as thatof Cockcroft and Gault (11) or Levey et al (12), to calculatecreatinine clearance. In fact, some institutional laboratoriesroutinely report calculated creatinine clearance with serumcreatinine levels.

Most studies of contrast agent–induced nephropathy haveused serum creatinine values, at baseline and after contrastagent administration. Because of the limitations of serum creatinine,these studies have shown widely varying results. Contrast agentshave been cited as one of the most frequent causes of in-hospitalrenal failure (13,14), which is probably a valid impression,but many other factors must be considered. These factors includenot only real glomerular filtration rate, but also concomitantrisk factors such as dehydration, surgery, and use of additionalnephrotoxins (eg, gentamycin, nonsteroidal anti-inflammatorydrugs, certain chemotherapeutic drugs). At this time, it isimpossible to define the true incidence of contrast agent–inducednephropathy.

What Are the Risk Factors for Contrast Agent–induced Nephropathy?
As previously implied, the major risk factor is underlying renaldysfunction. Contrast agent–induced nephropathy essentiallynever occurs if a patient’s renal function is truly normal.The presence of diabetes, particularly if long standing, isprobably not an independent risk factor, but it is a major contributingfactor in the presence of renal dysfunction (8,15). Additionalconcerns, as noted, are dehydration, poor renal perfusion (asoccurs with severe congestive heart failure), and the presenceof other factors that may be nephrotoxic, such as certain medicationsor major surgery. The volume of contrast agent administeredis another dependent risk factor: If renal function is trulynormal (the 20-year-old healthy patient with a serum creatininelevel of 1.2 mg/dL), then a high volume of contrast agent willnot lead to nephropathy. If the patient has underlying renaldysfunction, however, increasing the volume of contrast agentinjected will increase the likelihood of worsening renal function(16).

What Is the Natural History of Contrast Agent–induced Nephropathy?
In the vast majority of cases, contrast agent–inducednephropathy will be manifest by a transient increase in serumcreatinine level, which usually peaks at 4–7 days andgradually returns to baseline. A persistent elevation of serumcreatinine level is unusual, as is progression to end-stagerenal disease (8,17). The risk of either of these endpointsincreases as a direct function of the severity of a patient’sunderlying renal failure; that is, most patients who requiredialysis after contrast agent injection had very poor renalfunction at baseline. In one study of over 600 patients withelevated serum creatinine levels who underwent cardiac catheterization,only seven patients required dialysis, and permanent dialysiswas necessary in only three of these (8).

How Can Contrast Agent– induced Nephropathy Be Prevented?
First, nephropathy is not really a worry in patients with trulynormal renal function, regardless of the volume of contrastagent injected. For patients at risk, the first step in preventingnephropathy is adequate hydration (18). In practical terms,adequate hydration is usually achieved by instructing patientsto drink several liters of fluid over 12–24 hours beforecontrast agent injection. When such hydration isn’t possiblebecause an imaging study is urgent, because the patient cannottake oral fluids, or because sedation or anesthesia will beneeded and thus oral fluids are contraindicated, intravenoushydration can be given and may actually be more effective. Intravenoushydration should consist of at least 1 mL of normal saline perkilogram of body weight per hour, beginning 12 hours beforecontrast agent injection and continuing for 12 hours afterward.It is also important to remember that, invariably, patientsdo not adequately hydrate themselves; thus, for patients atrisk of nephropathy and if it is feasible, intravenous hydrationshould be used, beginning at least 12 hours before contrastagent injection (19). There is evidence that normal saline ismore effective than is half-normal saline (20). Recently, theuse of sodium bicarbonate for hydration, as compared with sodiumchloride (normal saline), has been reported as being effectivein decreasing the incidence of contrast agent–inducednephropathy (21). This approach is appealing because of itslow cost and relative ease of use, but further proof of efficacyis necessary. One concern with the Merten et al study (21) isthat hydration consisted of a 7-hour infusion begun 1 hour beforecontrast agent injection. Other studies have shown that hydrationwith an infusion of normal saline that begins at least 12 hoursbefore contrast agent injection is more effective than eithershort infusions or random oral hydration (19).

Many other approaches for preventing contrast agent–inducednephropathy have been investigated. It is logical to think thatadministration of either a diuretic such as furosemide or dialysisduring or immediately after contrast agent injection would help.Furosemide has been shown to be not helpful (18). Results ofstudies with dialysis do not agree, but most suggest that dialysisalso is not helpful (22,23). Use of fenoldapam mesylate, a selectivedopamine ${alpha}$ ₁-receptor agonist (thus a post–glomerular renalvasodilator), has been advocated, but the bulk of the evidencesuggests it does not have any protective or ameliorating effect(24), and its use requires close monitoring. Various other vasoactiveagents have been investigated, mainly in small clinical studies,without any real proof of efficacy. Two agents that have beenconsidered promising, although neither has been conclusivelyproved to be effective, are N-acetyl cysteine (n-AC) and iodixanol(Visipaque; GE Healthcare Group, Princeton, NJ), the only availablenonionic, isosmolal, iodinated contrast agent. N-AC acts asboth a vasodilator and as a free radical scavenger. Contrastagent nephrotoxicity was believed to be caused by a prolongeddecrease in glomerular flow, so enhancing flow (as with n-ACor fenoldapam) might be protective. These hemodynamic changeshave been demonstrated repeatedly in animal studies, but inhumans, injection of contrast agent does not lead to a significantdecrease in renal blood flow. It is well known, however, thatthe renal medulla is poorly oxygenated and is close to hypoxicunder normal conditions. If hypoxia occurs, reactive oxygenspecies that are toxic to cells are produced. In theory, then,n-AC may be effective because it is a free radical scavenger(25). The studies performed to date and analyses of them reachconflicting conclusions (26–28). Most but not all studiesthat used either oral administration with four doses twice dailystarting on the day before contrast agent injection or intravenousadministration starting 30 minutes before injection have showna protective effect. In addition, n-AC is safe, readily available,and inexpensive.

Iodixanol has been shown to have a protective effect in tworelatively small studies (29,30) and in other empiric reports.The reason why iodixanol should be effective is not entirelyclear. To step back a step, or a generation of contrast agents,the bulk of the evidence suggests that there is a difference,probably minor, in the incidence of contrast agent–inducednephropathy when high-osmolality versus low-osmolality contrastagents are used, but no difference between them in the needfor dialysis (8). It may be that the same holds true for iodixanol:The likelihood of a rise in serum creatinine level may be decreased,but the outcome for patients may not be different. Thus, iodixanolis promising, but further studies are needed to prove that itis effective in preventing or limiting contrast agent–inducednephropathy. Many additional approaches have been used to preventor at least to minimize the incidence and severity of nephropathy,and other larger studies are necessary to answer the persistentand clinically important questions that remain.

Is There a Level of Serum Creatinine above Which a Patient Should Not Receive an Iodinated Contrast Agent?
The short answer is no. In all patients, regardless of whetherrenal function is normal, the potential risks must be balancedagainst the possible benefits. A serum creatinine level of 2.0mg/dL, or 3.0 or 1.8, does not by itself indicate what the glomerularfiltration rate is, although it is clearly reduced, nor doesit accurately predict the risk of increased morbidity or mortalityafter injection of iodinated contrast media.

From a practical point of view, the radiologist should firstcalculate the creatinine clearance and then determine whetherthe relevant diagnostic question can be as adequately answeredwith another examination that does not require injection ofan iodinated contrast agent. For example, if a patient is stronglysuspected of having pulmonary embolism and has a mildly elevatedcreatinine level, but cannot undergo magnetic resonance angiographybecause of a pacemaker, what is the risk of performing CT angiography,which is likely to yield definitive results, versus a ventilationperfusion lung scan? If the patient is stable and at low riskfor anticoagulation, it is reasonable to do a ventilation perfusionscan, at least initially. If, however, a rapid and definitiveanswer is needed (eg, if the patient is hemodynamically compromised),CT pulmonary angiography should be performed. It is likely tocause no more than a transient increase in creatinine levelwhile providing a definitive answer. In such a situation, itis probably better to start hydration (with normal saline orperhaps with sodium bicarbonate), start intravenous n-AC, andperform CT angiography. Remember, the risks related to contrastagent–induced nephropathy primarily depend on the baselinerenal function and concomitant factors that place the patientat risk, such as dehydration, congestive heart failure, andrecent major surgery. In most cases in which the patient hasan elevated serum creatinine level (even if it is fairly markedlyelevated), his or her renal function, as reflected in serumcreatinine values, will likely worsen but then return to baseline.

What about Delayed Reactions to Contrast Agents?
Delayed reactions have been reported, with a low frequency,for many years (31,32). The reports have increased with theuse of nonionic dimeric contrast media (33). Such reactionsare almost invariably cutaneous, with a maculopapular, erythematouseruption occurring 12–48 hours after contrast agent administration.Although the rash is usually self-limited and only mildly symptomatic,it can be very uncomfortable and can spread over the entirebody over the course of a few days. If the rash is localizedand mildly pruritic, a topical steroid can be used. If it continuesto spread and is more bothersome, the patient should be referredto a dermatologist. Such reactions have been reported to recur,even when a different contrast agent is used (34), but usuallythey do not. They also do not appear to presage other contrastagent reactions.

Summary

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Abstract
Introduction
Summary
References

Contrast agents continue to cause concern among patients, referringphysicians, and radiologists because of their widespread useand the rare but potentially important adverse events associatedwith them. The questions that arise concerning contrast agentshave changed over time, with changes in the formulations andconsequent improvement in safety. Mortality still occurs afterinjection of contrast agents of all types, but it is very rare.The major questions associated with use of contrast media currentlyconcern practical matters, such as how to appropriately informpatients about the risks and benefits of contrast agent use,how to deal with patients who have particular risk factors foran adverse event (eg, prior reaction, strong history of allergies,compromised renal function, diabetes mellitus), and how to dealwith concerns of nephrotoxicity. Obtaining formal informed consentis both impractical and unnecessary, but it is imperative thatradiologists get information from patients before contrast agentinjection and supply information to them regarding the natureof the contrast media. Anaphylactoid reactions are not trueallergies and are fortunately rare, but unfortunately can occurunpredictably. The crucial factor in dealing with them is tobe prepared to treat them whenever and wherever they occur.Such preparation requires the presence of appropriate resuscitationequipment and medications and the availability of fully trainedpersonnel. Contrast agent nephrotoxicity is a topic of interestcurrently because of the aging population, the associated increasein the number of patients with compromised renal function, andthe increasing use of contrast-enhanced examinations. It isencouraging that there are several promising approaches to decreasingthe incidence and severity of this problem, although neitherthe efficacy of these treatments nor the natural history ofcontrast agent–induced nephropathy is yet clear. The mostimportant measure currently is ensuring that hydration is adequate.At this time, the approach that is best documented as effectiveis intravenous normal saline infused at 1 mL/kg/hr for 12 hoursbefore and 12 hours after contrast agent injection. A 7-hourinfusion of sodium bicarbonate beginning 1 hour before injectionis promising, but the method has not yet been conclusively provedto be effective. It is encouraging that contrast agents havebecome safer and more thoroughly understood over the past fewyears, but many questions and concerns remain.

Footnotes

Abbreviation: n-AC = N-acetyl cysteine.

References

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