Comparative effectiveness of intravenous

immunoglobulin from different manufacturing

processes on Kawasaki disease

Ming-Chih Lin

Taiwan, China

Author Affiliations: Division of Pediatric Cardiology, Department of Pediatrics, Taichung Veterans General Hospital, Taichung, Taiwan, China (Lin MC); Department of Pediatrics and Institute of Clinical Medicine, National Yang-Ming University, Taipei, Taiwan, China (Lin MC)

Corresponding Author: Ming-Chih Lin, MD, PhD, 1650 Taiwan Boulevard Sect. 4, Taichung, Taiwan 40705, China (Tel: +886-4-23592525 ext. 8190; Fax: +886-4-23741359; Email: mingclin@gmail.com)

doi: 10.1007/s12519-014-0479-8

Background: The comparative effectiveness of intravenous immunoglobulin (IVIG) for Kawasaki disease was regarded as inconclusive in the international guidelines. However, several new evidences have been published in recent years.

Data sources: A literature search of PubMed was conducted using key words of "Kawasaki disease or mucocutaneous lymph node syndrome" and "immunoglobulin" in combination. Only original articles published after 2004 were selected. A total of 813 papers were found in PubMed. These papers were screened manually by their titles and abstracts.

Results: Patients treated with IVIG prepared by beta-propiolactonation might have worse outcome (a higher non-responsive rate in one report and a higher rate of coronary aneurysm in two reports). Storage of IVIG in acidic solution might be correlated with a higher rate of coronary aneurysm (two reports).

Conclusions: Different processes of preparation and conditions of preservation of IVIG may have profound effects on its clinical effectiveness. Randomized controlled studies are needed to further elucidate this issue.

Key words: coronary aneurysm; immunoglobulin; Kawasaki disease; treatment outcome

World J Pediatr 2014;10(2):114-118

Introduction

Kawasaki disease was first described by Dr. Tomisaku Kawasaki in Japan in 1967.^[1-4] Now, the disease is widely reported in young children of different ethnic populations.^[3] It is also the most common cause of acquired heart disease among children in most industrialized countries.^[5-13] It is capable of inducing carditis and vasculitis, which result in long-term sequelae involving the coronary arteries. Thus, it is currently the subject attracting the attention of researchers.

For the management of Kawasaki disease, most physicians follow the guidelines of the American Academy of Pediatrics (AAP) and American Heart Association (AHA) published in 2004, which include the rapid infusion of high-dose intravenous immunoglobulin (IVIG) (2 gm/kg) in 12 hours, together with oral aspirin.^[3] As such, IVIG is regarded as the most important medication for the treatment of Kawasaki disease in the acute stage.^[14] Although the influence of different manufacturing processes on differences in IVIG effectiveness was briefly described in the AAP and AHA guidelines, the guidelines concluded that "potentially important product-manufacturing differences exist. But the results of clinical studies....conflicted".

Almost 10 years have passed since the publication of these guidelines and several interesting studies have been published since then. This article aimed to review new evidences regarding this issue. PubMed was searched for articles by using the key words "Kawasaki disease or mucocutaneous lymph node syndrome" and "immunoglobulin" in combination. Only original articles published after the year 2004 were selected. A total of 813 articles were found in PubMed. These articles were screened manually by their titles and abstracts.

The mechanisms of immunoglobulin therapy in Kawasaki disease

Because Kawasaki disease is recognized as vasculitis of the coronary artery, it is almost impossible to obtain a human sample except for a few autopsy cases. Related literature on the pathology of Kawasaki disease is also quite limited^[15-20] and most of the reports focus on vasculitis of the coronary artery. Such inflammatory process can trigger further remodeling of blood vessels, which can last for years.^[15,19,20] This may somehow explain why Kawasaki disease induces long-term sequelae on the coronary artery. Meanwhile, some studies found that vasculitis not only occurs in the coronary artery but also in all medium-sized arteries.^[16-19]

The mechanism of IVIG in the treatment of Kawasaki disease is still obscure. Researchers found that part of the effectiveness comes from an immuno-modulatory effect on the host immune system by binding the constant region (Fc portion) of host immunoglobulins.^[3] IVIG can significantly inhibit the release of interleikin-1 by monocytes in peripheral blood but does not decrease cytotoxic anti-endothelial antibodies.^[21] It may also reduce the release of interleukin-1 of macrophages via interaction with their Fc receptors.^[22]

In short, IVIG may decrease the interleukin release of host immune cells via interaction with the Fc portion of host immunoglobulins. Thus, the inflammatory storm of Kawasaki disease is subsequently suppressed.

Differences in the effectiveness among immunoglobulins

Although IVIG is undoubtedly the major medication for acute-stage Kawasaki disease.^[14] It is extracted from blood of many donors. The World Health Organization have established standards for the manufacture of immunoglobulins (at least 1000 donors, 90% of IgG preserved, the sub-categories consistent with normal population, and screening for hepatitis viruses B, hepatitis viruses C, and human immunodeficiency virus).^[23] However, among different manufacturers of IVIG, there are still differences in the manufacturing processes, purification, IgA concentration, and conditions of preservation (Table 1).^[23-29] Minor differences may cause side effects and complications, for instance, slightly higher concentrations of IgA or IgM induce severe anaphylactic reactions.^[27,30] Moreover, hepatitis transmission results in defects in the manufacturing process.^[31,32]

With regard to efficacy, a retrospective case control study (n=45) conducted in the United States of America comparing the efficacy of two brands, Venoglobulin I and Iveegam, has been published in 1995. This study found that Iveegam shortened febrile days and had less side effects,^[33] but did not infer the practical reasons for the results. Unfortunately, the retrospective design and limited case numbers limited the value of this study. But the study was cited by the AHA and AAP guidelines in 2004.

After the publication of the guidelines, Tsai et al^[26] compared the effectiveness of four brands of IVIG, including Venoglobulin S, Gamimune, Intraglobin F, and SNBTSPF Center CBSF in 2006. They found that Intraglobin F had a higher non-responsive rate and more coronary aneurysms in the convalescent phase, which was attributed to beta-propiolactonation during IVIG purification. Beta-propiolactonation might change the Fc portion of IVIG, thereby interfering with its binding with the host macrophages. This subsequently decreased the ability of IVIG to inhibit interleukin-1 release. At last, the immuno-modulatory effect of high-dose IVIG was weakened.^[26] This study collected certain case numbers, but the patients came from only one institution and the four groups of patients were not collected in the same period. Moreover, the significantly different numbers in each groups and the lack of long-term follow-up became the weak points of the study.

In 2007, Kuo et al^[34,35] found no differences in brands of IVIG, using data from a single hospital. However, they used a surrogate endpoint, eosinophil counts, instead of real clinical outcomes. The statistical power was also not enough because of limited case numbers, which make the results less persuasive.

In 2010, Manlhiot et al^[28] compared two brands of IVIG, Iveegam (non-acidified) and Gamimune (acidified) and found that Gamimune was associated with a lower non-responsive rate and a shorter hospital stay, but a higher incidence of coronary artery aneurysms. They inferred that this phenomenon of Gamimune, which was preserved in acidic solution, could damage the elastin protein, especially when coronary arteries were involved in an inflammatory process, subsequently causing more coronary aneurysms. On the other hand, the lower non-responsive rate was attributed to differences of concentration. Gamimune was prepared in a higher concentration (10%) compared to Iveegam (5%). This would allow physicians to have an easier delivery of high-dose IVIG in 12 hours. Although the cases came from several hospitals, the case distributions were significantly unequal. Care quality and outcome definition may vary from hospital to hospital. Moreover, the results only reached borderline statistical significance even after propensity score adjusting. Long-term follow-up data were also lacking.^[36-38]

Our research team published a nationwide cohort study in 2013.^[29] We found that beta-propiolactonation increased the IVIG non-responsive rate during the acute phase. Acidified IVIG might increase the rate of coronary aneurysm but it decreased the IVIG non-responsive rate. The long-term results (need for medication after 6 months) were correlated with IVIG non-responsiveness in the acute stage. The observed higher non-responsive rate of beta-propiolactonation IVIG was consistent with the results of Tsai et al.^[26] Although the increased rate of acute aneurysm and decreased refractory rate of acidified IVIG were similar to the observations by Manlhiot et al,^[28] the concentration differences in Canada were not noted in Taiwan. The authors also did not explain why acidified IVIG was more effective. With regard to the effectiveness of IVIG, this study had the largest case numbers to date. It was also the first study to provide long-term follow-up data. However, the study had certain weak points stemming from the fact that the data were for insurance claims data. No validation could be provided in consideration of patient privacy. Moreover, the claims data of the Taiwan National Health Insurance lacked laboratory results and imaging reports.^[39,40]

Some patients with Kawasaki disease developed hyponatremia during the acute phase. The pathogenesis was considered to be correlated with syndrome of inappropriate antidiuretic hormone secretion and cytokine release.^[41,42] Hyponatremia was also recognized as an index of disease severity and a predictor of coronary complications.^[41,43] Immunoglobulin therapy was found to effectively reverse hyponatremia in Kawasaki disease.^[42] Although immunoglobulins without sodium were reported to have an adverse effect on hyponatremia in patients with Kawasaki disease, their clinical efficacy was equivalent to that of those with a high sodium concentration.^[44]

The four studies are summarized in Table 2. It might be better to perform a meta-analysis to confirm the different effectiveness by different manufacturing processes. However, it is not possible at present because of few papers published and lack of randomized controlled trials.

Conclusions

The immuno-modulatory effect of IVIG plays an important role in suppressing the inflammatory storm of Kawasaki disease. Different preparation processes (beta-propiolactonation or cold-ethanol-PEG precipitation) and conditions of preservation (acidified or not) of IVIG may exert profound effects on its clinical effectiveness. Randomized controlled studies are needed to elucidate this issue.

Funding: None.

Ethical approval: Not needed.

Competing interest: No benefits in any form have been received or will be received from any commercial party related directly or indirectly to the subject of this article.

Contributors: Lin MC proposed the study and wrote the draft.

References

1  Kawasaki T. Acute febrile mucocutaneous syndrome with lymphoid involvement with specific desquamation of the fingers and toes in children. Arerugi 1967;16:178-222.

2  Burns JC, Glodé MP. Kawasaki syndrome. Lancet 2004;364: 533-544.

3  Newburger JW, Takahashi M, Gerber MA, Gewitz MH, Tani LY, Burns JC, et al. Diagnosis, treatment, and long-term management of Kawasaki disease: a statement for health professionals from the Committee on Rheumatic Fever, Endocarditis, and Kawasaki Disease, Council on Cardiovascular Disease in the Young, American Heart Association. Pediatrics 2004;114:1708-1733.

4  Harnden A, Takahashi M, Burgner D. Kawasaki disease. BMJ 2009;338:b1514.

5  Du ZD, Zhao D, Du J, Zhang YL, Lin Y, Liu C, et al. Epidemiologic study on Kawasaki disease in Beijing from 2000 through 2004. Pediatr Infect Dis J 2007;26:449-451.

6  Fischer TK, Holman RC, Yorita KL, Belay ED, Melbye M, Koch A. Kawasaki syndrome in Denmark. Pediatr Infect Dis J 2007;26:411-415.

7  Heaton P, Wilson N, Nicholson R, Doran J, Parsons A, Aiken G. Kawasaki disease in New Zealand. J Paediatr Child Health 2006;42:184-190.

8  Holman RC, Belay ED, Christensen KY, Folkema AM, Steiner CA, Schonberger LB. Hospitalizations for Kawasaki syndrome among children in the United States, 1997-2007. Pediatr Infect Dis J 2010;29:483-488.

9  Huang WC, Huang LM, Chang IS, Chang LY, Chiang BL, Chen PJ, et al. Epidemiologic features of Kawasaki disease in Taiwan, 2003-2006. Pediatrics 2009;123:e401-405.

10         Lynch M, Holman RC, Mulligan A, Belay ED, Schonberger LB. Kawasaki syndrome hospitalizations in Ireland, 1996 through 2000. Pediatr Infect Dis J 2003;22:959-963.

11         Ng YM, Sung RY, So LY, Fong NC, Ho MH, Cheng YW, et al. Kawasaki disease in Hong Kong, 1994 to 2000. Hong Kong Med J 2005;11:331-335.

12         Park YW, Han JW, Park IS, Kim CH, Cha SH, Ma JS, et al. Kawasaki disease in Korea, 2003-2005. Pediatr Infect Dis J 2007;26:821-823.

13         Yanagawa H, Nakamura Y, Yashiro M, Uehara R, Oki I, Kayaba K. Incidence of Kawasaki disease in Japan: the nationwide surveys of 1999-2002. Pediatr Int 2006;48:356-361.

14         Hsieh KS, Weng KP, Lin CC, Huang TC, Lee CL, Huang SM. Treatment of acute Kawasaki disease: aspirin's role in the febrile stage revisited. Pediatrics 2004;114:e689-693.

15         Suzuki A, Miyagawa-Tomita S, Komatsu K, Nishikawa T, Sakomura Y, Horie T, et al. Active remodeling of the coronary arterial lesions in the late phase of Kawasaki disease: immunohistochemical study. Circulation 2000;101:2935-2941.

16         Rowley AH, Shulman ST, Mask CA, Finn LS, Terai M, Baker SC, et al. IgA plasma cell infiltration of proximal respiratory tract, pancreas, kidney, and coronary artery in acute Kawasaki disease. J Infect Dis 2000;182:1183-1191.

17         Naoe S, Takahashi K, Masuda H, Tanaka N. Kawasaki disease. With particular emphasis on arterial lesions. Acta Pathol Jpn 1991;41:785-797.

18         Nagata S, Yamashiro Y, Maeda M, Ohtsuka Y, Yabuta K. Immunohistochemical studies on small intestinal mucosa in Kawasaki disease. Pediatr Res 1993;33:557-563.

19         Gavin PJ, Crawford SE, Shulman ST, Garcia FL, Rowley AH. Systemic arterial expression of matrix metalloproteinases 2 and 9 in acute Kawasaki disease. Arterioscler Thromb Vasc Biol 2003;23:576-581.

20         Brown TJ, Crawford SE, Cornwall ML, Garcia F, Shulman ST, Rowley AH. CD8 T lymphocytes and macrophages infiltrate coronary artery aneurysms in acute Kawasaki disease. J Infect Dis 2001;184:940-943.

21         Leung DY, Cotran RS, Kurt-Jones E, Burns JC, Newburger JW, Pober JS. Endothelial cell activation and high interleukin-1 secretion in the pathogenesis of acute Kawasaki disease. Lancet 1989;2:1298-1302.

22         Iwata M, Shimozato T, Tokiwa H, Tsubura E. Antipyretic activity of a human immunoglobulin preparation for intravenous use in an experimental model of fever in rabbits. Infect Immun 1987;55:547-554.

23         Bonilla F, Geha R. Intravenous immunoglobulin therapy. In: Austen KF, eds. Therapeutic immunology, 2nd ed. Malden, Mass.: Blackwell Science, 2001: 264-286.

24         Gelfand EW. Differences between IGIV products: impact on clinical outcome. Int Immunopharmacol 2006;6:592-599.

25         Stiehm ER. Lessons from Kawasaki disease: all brands of IVIG are not equal. J Pediatr 2006;148:6-8.

26         Tsai MH, Huang YC, Yen MH, Li CC, Chiu CH, Lin PY, et al. Clinical responses of patients with Kawasaki disease to different brands of intravenous immunoglobulin. J Pediatr 2006;148:38-43.

27         Manlhiot C, Tyrrell PN, Liang L, Atkinson AR, Lau W, Feldman BM. Safety of intravenous immunoglobulin in the treatment of juvenile dermatomyositis: adverse reactions are associated with immunoglobulin A content. Pediatrics 2008;121:e626-630.

28         Manlhiot C, Yeung RS, Chahal N, McCrindle BW. Intravenous immunoglobulin preparation type: association with outcomes for patients with acute Kawasaki disease. Pediatr Allergy Immunol 2010;21:515-521.

29         Lin MC, Fu YC, Jan SL, Lai MS. Comparative effectiveness of intravenous immunoglobulin for children with kawasaki disease: a nationwide cohort study. PLoS One 2013;8:e63399.

30         Rieben R, Roos A, Muizert Y, Tinguely C, Gerritsen AF, Daha MR. Immunoglobulin M-enriched human intravenous immunoglobulin prevents complement activation in vitro and in vivo in a rat model of acute inflammation. Blood 1999;93:942-951.

31         Greenbaum BH. Differences in immunoglobulin preparations for intravenous use: a comparison of six products. Am J Pediatr Hematol Oncol 1990;12:490-496.

32         Centers for Disease Control and Prevention (CDC). -Outbreak of hepatitis C associated with intravenous immunoglobulin administration--United States, October 1993-June 1994. MMWR Morb Mortal Wkly Rep 1994;43:505-509.

33         Rosenfeld EA, Shulman ST, Corydon KE, Mason W, Takahashi M, Kuroda C. Comparative safety and efficacy of two immune globulin products in Kawasaki disease. J Pediatr 1995;126:1000-1003.

34         Khan S, Doré PC, Sewell WA. Both patient characteristics and IVIG product-specific mechanisms may affect eosinophils in immunoglobulin-treated Kawasaki disease. Pediatr Allergy Immunol 2008;19:186-187.

35         Kuo HC, Wang CL, Wang L, Yu HR, Yang KD. Patient characteristics and intravenous immunoglobulin product may affect eosinophils in Kawasaki disease. Pediatr Allergy Immunol 2008;19:184-185.

36         Lau AC, Duong TT, Ito S, Yeung RS. Matrix metalloproteinase 9 activity leads to elastin breakdown in an animal model of Kawasaki disease. Arthritis Rheum 2008;58:854-863.

37         Lau AC, Rosenberg H, Duong TT, McCrindle BW, Yeung RS. Elastolytic matrix metalloproteinases and coronary outcome in children with Kawasaki disease. Pediatr Res 2007;61:710-715.

38         Rowley AH, Shulman ST, Spike BT, Mask CA, Baker SC. Oligoclonal IgA response in the vascular wall in acute Kawasaki disease. J Immunol 2001;166:1334-1343.

39         Lin MC, Lai MS. Pediatricians' role in caring for preschool children in Taiwan under the national health insurance program. J Formos Med Assoc 2009;108:849-855.

40         Wen CP, Tsai SP, Chung WS. A 10-year experience with universal health insurance in Taiwan: measuring changes in health and health disparity. Ann Intern Med 2008;148:258-267.

41         Lim GW, Lee M, Kim HS, Hong YM, Sohn S. Hyponatremia and syndrome of inappropriate antidiuretic hormone secretion in kawasaki disease. Korean Circ J 2010;40:507-513.

42         Mori J, Miura M, Shiro H, Fujioka K, Kohri T, Hasegawa T. Syndrome of inappropriate anti-diuretic hormone in Kawasaki disease. Pediatr Int 2011;53:354-357.

43         Kobayashi T, Inoue Y, Takeuchi K, Okada Y, Tamura K, Tomomasa T, et al. Prediction of intravenous immunoglobulin unresponsiveness in patients with Kawasaki disease. Circulation 2006;113:2606-2612.

44         Kaneko K, Hirabayashi M, Tateiwa A, Shimo T, Teranishi K, Tanaka S, et al. Immunoglobulin preparations affect hyponatremia in Kawasaki disease. Eur J Pediatr 2010;169:957-960.

Accepted after revision January 28, 2014