Iodinated contrast explained

Iodinated contrast is a form of water-soluble, intravenous radiocontrast agent containing iodine, which enhances the visibility of vascular structures and organs during radiographic procedures. Some pathologies, such as cancer, have particularly improved visibility with iodinated contrast.

The radiodensity of iodinated contrast is 25–30 Hounsfield units (HU) per milligram of iodine per milliliter at a tube voltage of 100–120 kVp.[1]

Types

Iodine-based contrast media are usually classified as ionic or nonionic. Both types are used most commonly in radiology due to their relatively harmless interaction with the body and their solubility. Contrast media are primarily used to visualize vessels and changes in tissues on radiography and CT (computerized tomography). Contrast media can also be used for tests of the urinary tract, uterus and fallopian tubes. It may cause the patient to feel as if they have had urinary incontinence. It also puts a metallic taste in the mouth of the patient.

The iodine may be bound either in an organic (nonionic) compound or an ionic compound. Ionic agents were developed first and are still in widespread use depending on the requirements but may result in additional complications due to the high concentration of ions (hyperosmolality). Organic agents which covalently bind the iodine have fewer side effects as they do not dissociate into component molecules. Many of the side effects are due to the hyperosmolar solution being injected. i.e. they deliver more iodine atoms per molecule. The more iodine, the more "dense" the X-ray effect.

Organic iodine molecules used for contrast include iohexol, iodixanol, and ioversol.Iodine-based contrast media used nowadays are water-soluble. These contrast agents are sold as clear, colorless water solutions, with the concentration usually expressed as mg I/ml. Modern iodinated contrast agents can be used almost anywhere in the body. Most often they are used intravenously, but for various purposes they can also be used intra-arterially, intrathecally (as in diskography of the spine) and intra-abdominally – just about any body cavity or potential space.

Heating non-ionic contrast agent to human body temperature reduces its viscosity.[2]

The amount of iodine administered in children in the United States in 2010 was 272 to 740 mg/kg for CT scan.[3]

Iodine contrast agents are used for the following:

Commonly used ionic iodinated contrast agents
NameTypeIodine contentOsmolality
diatrizoate (Hypaque 50/ Gastrografin)Monomer300 mgI/ml1550High
metrizoate (Isopaque 370)Monomer370 mgI/ml2100High
iothalamate (Conray)Monomer600-2400High
ioxaglate (Hexabrix)Dimer320 mgI/ml580Low
Commonly used nonionic contrast agents
NameTypeIodine contentOsmolality
iopamidol (Isovue 370)Monomer370 mgI/ml796Low
iohexol (Omnipaque 350)Monomer350 mgI/ml884Low
ioxilan (Oxilan 350)Monomer350 mgI/ml695Low
iopromide (Ultravist 370)Monomer370 mgI/ml774Low
iodixanol (Visipaque 320)Dimer320 mgI/ml290Low
iobitridol (Xenetix 300)Monomer300 mgI/ml695Low
ioversolMonomer

Adverse effects

Iodinated contrast agents may cause allergic reactions, contrast-induced nephropathy, hyperthyroidism and possibly metformin accumulation. However, there are no absolute contraindications to iodinated contrast, so the benefits needs to be weighted against the risks.[4]

Hypersensitivity towards iodinated contrast agent is associated with increase in histamine and tryptase concentration in blood.[5] Diphenhydramine (Benadryl) 50 mg orally or intravenously one hour before contrast administration can reduce the risk of urticaria, angioedema, and respiratory symptoms.[6]

An observational study conducted across 133,331 patients concluded that iodinated contrast injected through veins has more hypersensitivity reactions than when injected through arteries. However, the cause for this phenomenon is unknown.[7]

In people with myasthenia gravis, older forms of iodinated contrast have caused an increased risk of exacerbation of the disease, but modern (low-osmolar) forms have no immediate increased risk.[8]

Hypersensitivity reactions

Anaphylactoid reactions occur rarely,[9] [10] [11] but can occur in response to injected as well as oral and rectal contrast and even retrograde pyelography.They are similar in presentation to anaphylactic reactions, but are not caused by an IgE-mediated immune response. Patients with a history of contrast reactions, however, are at increased risk of anaphylactoid reactions.[12] [13] Pretreatment with corticosteroids has been shown to decrease the incidence of adverse reactions.[14] [15]

Anaphylactoid reactions range from urticaria and itching, to bronchospasm and facial and laryngeal edema. For simple cases of urticaria and itching, an oral or intravenous antihistamine such as diphenhydramine is appropriate. For more severe reactions, including bronchospasm and facial or neck edema, albuterol inhaler, or subcutaneous or IV epinephrine, plus diphenhydramine may be needed. If respiration is compromised, an airway must be established prior to medical management.

Anaphylaxis to ionic (high osmolar) contrast agent injections occurred in two clusters of reactions on two occasions (1983 and 1987) in a single radiology clinic in London, Ontario. On each occasion, these anaphylactic reactions were associated with contamination of the injection by natural rubber components (disposable plastic syringes in the first case and rubber ampoule seals in the second case). The allergenic-toxic rubber leachate was MBT (mercaptobenzothiazole). This is a known allergen that becomes bound to plasma proteins, creating a hapten-protein complex – a signature mechanism in true IgE drug allergy and true anaphylactic reactions (not "anaphylactoid" reactions).

A Japanese syringe manufacturer, Terumo, implicated in syringe-related toxic laboratory cell culture effects in Australia in 1981, was instrumental in pro-actively making Japanese disposable syringes and ampoule seals free of natural rubber. Katayama's 1990 article in Radiology showed that a new type of nonionic (low osmolar) contrast agent was associated with significantly fewer severe life-threatening reactions than the older ionic (high osmolar) contrast agents.[16] By merchandizing the Katayama series reprints, manufacturers persuaded users worldwide to switch to the almost exclusive use of the expensive nonionic agents.

What was unknown to the Katayama researchers was that the ampoule seals of the "safer" nonionic contrast agents were made from artificial rubber, whereas the ionic agents were sealed with natural rubber. In 1987, it was the leaching of allergenic MBT from the rubber seals of ionic ampoules that caused a series of allergic reactions (including anaphylaxis) in a radiology office in Canada.[17] The worldwide hazard of MBT contamination of injections was unknown then and, as the World Health Organization reported it remains as an unknown hazard still – after three decades.[18]

The most significant study, proving that injections of ionic (high osmolar) agents are at least as safe as the newer, very expensive nonionic agents was published in Radiology in 1997.[19] Lasser did not comment that the marked drop in the incidence of severe reactions with ionic agents was related to the removal of natural rubber contamination from ionic ampoule seals.

Contribution of seafood and other allergies

The term "iodine allergy" should be omitted because this kind of allergy does not exist.[20] Seafood "allergy" is not a contraindication for the use of iodinated contrast materials, because in seafood allergy the immune system is directed against the muscle protein tropomyosin. While iodine levels in seafood are higher than in non-seafood items, the consumption of the latter exceeds that of the former by far and there is no evidence that the iodine content of seafood is related to reactions to seafood.[21] Available data suggest that seafood allergy increases the risk of a contrast-mediated reaction by approximately the same amount as allergies to fruits or those with asthma. In addition, those with an intolerance to alcohol should avoid use of this product due to chemical breakdown similar to ethyl alcohol. Studies show that B.A.C. has been shown to increase exponentially for up to 72 hours after contrast is administered, resulting in altered results of urine, blood, and breath alcohol screens.[22] Those with history of severe contrast reaction will have six-fold increase risk of adverse reaction. Those with history of asthma will have six-fold increased risk to low-osmolar contrast media and 10-fold increased risk to high-osmolar contrast media.[23]

Over 85% of patients with seafood allergies will not have an adverse reaction to iodinated contrast.[21] Finally, there is no evidence that adverse skin reactions to iodine-containing topical antiseptics (e.g., povidone-iodine) are of any specific relevance to administration of I.V. contrast material.[21] [24]

IL-2 medication poses no risk for the acquisition of adverse events by radiocontrast agents.[25]

Contrast-induced nephropathy

See main article: Contrast-induced nephropathy. Contrast-induced nephropathy is defined as either a greater than 25% increase of serum creatinine or an absolute increase in serum creatinine of 0.5 mg/dL.[26] Iodinated contrast may be toxic to the kidneys, especially when given via the arteries prior to studies such as catheter coronary angiography. Nonionic contrast agents, which are almost exclusively used in CT scans, have not been shown to cause CIN when given intravenously at doses needed for CT studies.[27]

Effects on thyroid function

Iodinated contrast media exposure can potentially cause incident hyperthyroidism and incident overt hypothyroidism."[28] [29] Hyperthyroidism is the effect of iodine being a substrate of thyroid hormones, and is then called the Jod-Basedow phenomenon. The risk is higher in those with an underlying thyroid disease, such as toxic multinodular goiter, Graves' disease, or Hashimoto's thyroiditis, where thyroid monitoring is indicated.[30] Otherwise, for the general population, routine screening with thyroid function tests is generally not feasible.[30]

Drug interactions

It has been recommended that metformin, an oral antidiabetic agent, be stopped for 48 hours following the intravascular administration of contrast media and that the use of metformin not be resumed until kidney function has been shown to be normal. The reasoning is that if the contrast medium causes kidney failure (as happens rarely) and the person continues to take metformin (which is normally excreted by the kidneys), there may be a toxic accumulation of metformin, increasing the risk of lactic acidosis, a dangerous complication.[31]

However, guidelines published by the American College of Radiologists suggest this is not as important for patients who have normal kidney function and no evidence of acute kidney injury. If kidney impairment is found before administration of the contrast, metformin should be withheld for 48 hours following the procedure and until kidney function has returned to normal.[32]

Contrast exposure may interfere with subsequent radioiodine treatment, causing unwanted delays in the management of thyroid cancer.[30]

Previously, beta blockers have been assumed as risk factor for the acquisition of contrast medium-induced adverse reactions/hypersensitivity reactions. Due to recent investigations it became clear that beta blockers do not increase the frequency of adverse reactions in concert with radiocontrast agents.[33]

Pregnancy

Iodinated contrast in medical imaging in pregnancy, when orally administered, is harmless.[34] Intravenous administration of iodinated radiocontrast agents can cross the placenta and enter the fetal circulation, but animal studies have reported no teratogenic or mutagenic effects from its use. There have been theoretical concerns about potential harm of free iodide on the fetal thyroid gland,[34] but multiple studies have shown that a single dose of intravenously administered iodinated contrast medium to a pregnant mother has no effect on neonatal thyroid function.[35] Nevertheless, it generally is recommended that radiocontrast only be used if absolutely required to obtain additional diagnostic information that will improve the care of the fetus or mother.[34]

Breastfeeding

American College of Radiology (ACR) guidelines state that iodinated contrast administration to a breastfeeding mother is considered safe for both the mother and child.[36] Still, mothers who remain concerned about any potential adverse effects to the child are recommended to have the option of abstaining from breastfeeding for 24 hours, with continued milk extraction such as by a breast pump during that period.[36] Mothers that opt for this for non-emergent exams may also use a breast pump to obtain milk before the exam in order to feed the child during the 24-hour abstinence period.[36] [37]

See also

Further reading

Notes and References

  1. Bae. Kyongtae T.. Intravenous Contrast Medium Administration and Scan Timing at CT: Considerations and Approaches. Radiology. 256. 1. 2010. 32–61. 0033-8419. 10.1148/radiol.10090908. 20574084.
  2. Zhang. Bin. Liu. Jing. Dong. Yuhao. Guo. Baoliang. Lian. Zhouyang. Yu. Hui. Luo. Xiaoning. Mo. Xiaokai. Zhang. Lu. Huang. Wenhui. Ouyang. Fusheng. 2018-11-01. Extrinsic warming of low-osmolality iodinated contrast media to 37°C reduced the rate of allergic-like reaction. Allergy and Asthma Proceedings. 39. 6. e55–e63. 10.2500/aap.2018.39.4160. 6212634. 30401329.
  3. Trout AT, Dillman JR, Ellis JH, Cohan RH, Strouse PJ . Patterns of intravenous contrast material use and corticosteroid premedication in children--a survey of Society of Chairs of Radiology in Children's Hospitals (SCORCH) member institutions . Pediatric Radiology . 41 . 10 . 1272–83 . October 2011 . 21594547 . 10.1007/s00247-011-2112-5 . 20149224 .
  4. Web site: Iodine-containing contrast medium. Stacy Goergen. InsideRadiology - The Royal Australian and New Zealand College of Radiologists. 2019-02-22. 2016-09-13. Page last modified on 26/7/2017
  5. Clement O, Dewachter P, Mouton-Faivre C, Nevoret C, Guilloux L, Bloch Morot E, Katsahian S, Laroche D, Audebert M, Benabes-Jezraoui B, Benoit Y, Beot S, Berard F, Berthezene Y, Bertrand P, Bouffard J, Bourrain JL, Boyer B, Carette MF, Caron-Poitreau C, Cavestri B, Cercueil JP, Charpin DA, Collet E, Crombe-Ternamian A, Dalmas J, Decoux E, Defrance MF, Delaval Y, Demoly P, Depriester C, Depriester P, Didier A, Drouet M, Dupas B, Dupre-Goetchebeur D, Dzviga C, Fabre C, Ferretti G, Fourre-Jullian C, Girardin P, Giron J, Gouitaa M, Grenier N, Guenard Bilbault L, Guez S, Gunera-Saad N, Heautot JF, Herbin D, Hoarau C, Jacquot C, Julien C, Laborie L, Lambert C, Larroche P, Leclerc X, Lemaitre L, Leynadier F, Lillo-Le-Louet A, Louvel JP, Louvier N, Lucas MM, Meites G, Mennesson N, Metge L, Meunier Y, Monnier-Cholley L, Musacchio M, Nicolie B, Occelli G, Oesterle H, Paisant-Thouveny F, Panuel M, Railhac N, Rety-Jacob F, Rochefort-Morel C, Roy C, Sarlieve P, Sesay M, Sgro C, Taourel P, Terrier P, Theissen O, Topenot I, Valfrey J, Veillon F, Vergnaud MC, Veyret C, Vincent D, Wallaert B, Wessel F, Zins M . Immediate Hypersensitivity to Contrast Agents: The French 5-year CIRTACI Study . eClinicalMedicine . 1 . 51–61 . July 2018 . 31193689 . 6537532 . 10.1016/j.eclinm.2018.07.002 .
  6. Book: ACR Committee on Drugs and Contrast Media . ACR Manual on Contrast Media . 2021 . American College of Radiology . 9781559030120 . 9 . 12 March 2022 . https://web.archive.org/web/20220308132731/https://www.acr.org/-/media/ACR/Files/Clinical-Resources/Contrast_Media.pdf . 8 March 2022.
  7. Endrikat J, Michel A, Kölbach R, Lengsfeld P, Vogtländer K . Risk of Hypersensitivity Reactions to Iopromide After Intra-Arterial Versus Intravenous Administration: A Nested Case-Control Analysis of 133,331 Patients . Investigative Radiology . 55 . 1 . 38–44 . January 2020 . 31524764 . 6903317 . 10.1097/RLI.0000000000000611 .
  8. Mehrizi. Mehyar. Pascuzzi. Robert M.. Complications of radiologic contrast in patients with myasthenia gravis. Muscle & Nerve. 50. 3. 2014. 443–444. 0148-639X. 10.1002/mus.24254. 24677227. 206295540.
  9. Karnegis JN, Heinz J . The risk of diagnostic cardiovascular catheterization . Am Heart J . 1979 . 291–7 . 97 . 3 . 420067 . 10.1016/0002-8703(79)90427-7.
  10. 10.1056/NEJM198710013171401 . Lasser EC, Berry CC, Talner LB, Santini LC, Lang EK, Gerber FH, Stolberg HO . Pretreatment with corticosteroids to alleviate reactions to intravenous contrast material . N Engl J Med . 1987 . 845–9 . 317 . 14 . 3627208.
  11. Greenberger PA, Patterson R, Tapio CM . Prophylaxis against repeated radiocontrast media reactions in 857 cases. Adverse experience with cimetidine and safety of beta-adrenergic antagonists . Arch Intern Med . 1985 . 2197–200 . 145 . 12 . 2866755 . 10.1001/archinte.145.12.2197.
  12. Greenberger PA, Patterson R . Adverse reactions to radiocontrast media . Prog Cardiovasc Dis . 1988 . 239–48 . 31 . 3 . 3055068 . 10.1016/0033-0620(88)90017-5.
  13. Lang DM, Alpern MB, Visintainer PF, Smith ST . Elevated risk of anaphylactoid reaction from radiographic contrast media is associated with both beta-blocker exposure and cardiovascular disorders . Arch Intern Med . 1993 . 2033–40 . 153 . 17 . 8102844 . 10.1001/archinte.153.17.2033.
  14. Lasser EC, Berry CC, Talner LB, Santini LC, Lang EK, Gerber FH, Stolberg HO . Protective effects of corticosteroids in contrast material anaphylaxis . Invest Radiol . 1988 . S193–4 . 23 Suppl 1 . 3058630 . 10.1097/00004424-198809001-00035.
  15. Wittbrodt ET, Spinler SA . Prevention of anaphylactoid reactions in high-risk patients receiving radiographic contrast media . Ann Pharmacother . 1994 . 236–41 . 28 . 2 . 8173143 . 10.1177/106002809402800215. 25654677 .
  16. Katayama H . Yamaguchi K. . Kozuka T. . 1990 . Adverse Reactions to Ionic and Nonionic Contrast Media. A Report from the Japanese Committee on the Safety of Contrast Media . Radiology . 175 . 3. 621–28 . 10.1148/radiology.175.3.2343107. 2343107 . etal.
  17. Hamilton Gavin . 1990 . Medical Rubber Anaphylaxis . 10.1016/0140-6736(90)93165-l . 1978917 . Lancet . 336 . 8728. 1453–1454. 42580307 .
  18. Book review "The Nurses are Innocent," Lethal, odd and 'new' in pharmacovigilance. Uppsala Reports 61 - April 2013: Page 10–11.
  19. Lasser E.C. . Lyon G.L. . Berry C.C. . 1997 . Reports on Contrast Media Reactions: Analysis of Data from Reports to the U.S. Food and Drug Administration . Radiology . 203 . 3. 605–10 . 10.1148/radiology.203.3.9169676 . 9169676.
  20. "Iodine Allergy" – The Neverending Story. 10.1055/s-0042-110102 . 27459005 . Fortschr Röntgenstr. 2016. I. . Böhm. P. S. . Hasembank Keller. J. T.. Heverhagen. 188. 8. 733–734. 36715998 .
  21. Coakley F, Panicek D . Iodine allergy: an oyster without a pearl? . AJR Am J Roentgenol . 169 . 4 . 951–2 . 1997 . 9308442 . 10.2214/ajr.169.4.9308442.
  22. Shehadi W . Adverse reactions to intravascularly administered contrast media. A comprehensive study based on a prospective survey . Am J Roentgenol Radium Ther Nucl Med . 124 . 1 . 145–52 . 1975 . 1170768 . 10.2214/ajr.124.1.145.
  23. Iyer RS, Schopp JG, Swanson JO, Thapa MM, Phillips GS . Safety essentials: acute reactions to iodinated contrast media . Canadian Association of Radiologists Journal . 64 . 3 . 193–9 . August 2013 . 22560565 . 10.1016/j.carj.2011.12.014 . 33278435 .
  24. van Ketel W, van den Berg W . Sensitization to povidone-iodine . Dermatol Clin . 8 . 1 . 107–9 . 1990 . 2302848. 10.1016/S0733-8635(18)30531-X .
  25. Boehm I. Is interleukin-2 (still) a risk factor for adverse reactions in concert with radiographic contrast medium injection? Acta Radiol 2009; 50(7) 752-3
  26. Barrett BJ, Parfrey PS . Clinical practice. Preventing nephropathy induced by contrast medium . N. Engl. J. Med. . 354 . 4 . 379–86 . 2006 . 16436769 . 10.1056/NEJMcp050801.
  27. McDonald . Robert . McDonald . Jennifer S. . Carter . Rickey E. . Hartman . Robert P. . Katzberg . Richard W. . Kallmes . David F. . Williamson . Eric E. . December 2014 . Intravenous Contrast Material Exposure Is Not an Independent Risk Factor for Dialysis or Mortality . Radiology . 273 . 3 . 714–725 . 25203000 . 10.1148/radiol.14132418 .
  28. https://jamanetwork.com/journals/jamainternalmedicine/fullarticle/1108674 Association Between Iodinated Contrast Media Exposure and Incident Hyperthyroidism and Hypothyroidism
  29. Web site: Iodide Heart Scans Linked to Thyroid Disease. New York Times. live. limited. https://web.archive.org/web/20120125193250/https://well.blogs.nytimes.com/2012/01/23/iodide-heart-scans-linked-to-thyroid-disease/. 25 January 2012. Anahad. O'Connor. 23 January 2012.
  30. Yıldız. Sema. Kuşkonmaz. Şerife Mehlika. Effect of iodinated contrast media on thyroid: a brief review. Journal of Health Sciences. 6. 1. 2016. 12. 1986-8049. 10.17532/jhsci.2016.278. free.
  31. Rasuli P, Hammond DI . Metformin and contrast media: where is the conflict? . Can Assoc Radiol J . 49 . 3 . 161–6 . 1998 . 9640281.
  32. Web site: ACR Manual on Contrast Media. American College of Radiology. 2016. 46. 6 January 2017.
  33. Boehm I, Morelli J, Nairz K, Silva Hasembank Keller P, Heverhagen JT . Beta blockers and intravenous roentgen contrast materials; which risks do exist? . Eur J Intern Med . 35 . November . e17–e18 . 2016 . 27531627 . 10.1016/j.ejim.2016.08.003.
  34. Web site: Guidelines for Diagnostic Imaging During Pregnancy and Lactation. American Congress of Obstetricians and Gynecologists. February 2016
  35. Web site: ACR Manual on Contrast Media. Version 10.3. 2017. American College of Radiology. American College of Radiology Committee on Drugs and Contrast Media. 2017-07-30. 2017-09-24. https://web.archive.org/web/20170924210816/https://www.acr.org/~/media/37D84428BF1D4E1B9A3A2918DA9E27A3.pdf. dead.
  36. Web site: Diagnostic Radiology Procedures on Breastfeeding Patients. Yale School of Medicine. 2019-07-08.
  37. Boehm I, Hungerbühler M . Excretion of iodinated contrast media in human breast milk: surprising results . Eur J Radiol . 128 . 7 . 109045 . 2020 . 32416551 . 10.1016/j.ejrad.2020.109045.