The data are presented as percentages for descriptive variables; and as medians and interquartile (lower and upper) ranges (IQRs), or as means and standard deviations (SDs) for continuous variables, as appropriate. We did not perform statistical analysis between subgroups (by disease location), because of the small sample size. The data were analyzed by a biostatistician using IBM SPSS statistics version 24 (Armonk, NY: IBM Corp).

All patients had colonic inflammation at diagnosis, of whom, 14 (61%) had pancolitis. Terminal ileum (TI) involvement was observed in 1 (4%) patient who was classified as CD. Esophagogastroduodenoscopy (EGD) was completed in 18 (78%) patients, of them, 11 (61%) had signs of macroscopic inflammation and histologically, chronic inflammation was absent in 8/18 (44%) patients. Classification of the 13 patients with CD included 11 with inflammatory disease (B1), one with stricturing disease (B2) and 2 with fistulizing disease (B3). Granulomas were found in intestinal biopsies of 4/13 (31%) of the CD patients.

The initial medical therapy after diagnosis was a combination of corticosteroids with 5-aminosalicylic acid (5-ASA) or an immunomodulatory agent [6-mercaptopurine (6-MP) or azathioprine (AZA)] in 20/23 (87%) patients. Monotherapy with infliximab, 5-ASA, or AZA was initiated in one patient each (Table 3). Following induction, an additional six patients needed escalation to biological therapy and 10/20 (50%) were steroid dependent. Information on nutritional therapy at presentation was available for 16 patients, 8 of whom were treated with total parenteral nutrition (TPN). A response to biological treatment was observed in 4/7 (57%) patients. However, in three of them treatment was discontinued due to allergic reactions (Table 3). Diverting ileostomy was performed in 6 (26%) patients, three with a CD phenotype (one with IL-10 receptor mutation) due to intractable inflammation and steroid dependency, and three with a UC phenotype (one with CARMIL 2 mutation, due to perforation during colonoscopy).

Information regarding the clinical state and treatment at the end of the follow up was available for 22 patients. The median follow-up time was 51.2 (26–110.3) months and the mean patients’ age at the last follow-up was 101 ± 77 months. Height Z-score and weight Z-score, both at diagnosis and at the end of follow up, were available in 8 and 12 patients, respectively. Thus, at diagnosis, mean height and weight Z-score of those patients were (−0.82 ± 1.69) and (−1.77 ± 1.92), as compared to (−0.89 ± 0.98) and (−0.89 ± 1.17) at the end of follow up, (p = 0.46 and p = 0.1), respectively. Growth failure was observed in 1/8 (12.5%) patients with available height measurements at diagnosis and end of follow up. Both height Z-score and weight Z-score at diagnosis and end of follow-up were available in 7 patients. Three patients (2 with CD, 1 with UC), had both stunting (Z-core ≤ 2) and wasting (Z-score ≤ 2) at the end of follow-up. The mean final height Z-score of all patients with available data was −0.8 ± 1.1. In general, the weight Z-score showed a tendency for improvement, when final weight Z-score was compared to weight Z-score at diagnosis: −0.7 ± 1.2 vs. −1.5 ± 1.7, p < 0.06.

Long-term remission, [median 51.2 (26–110.3) months], was achieved in 16/22 (73%) patients, of these, one underwent colectomy and ileostomy at diagnosis and one underwent ileostomy and hemicolectomy due to perforation during bowel dilation later in the course of disease. At last follow-up, three patients (aged 1.3, 8.2, and 12.0 years, respectively, Table 3), were in clinical remission without medical treatment, two of them (#12 and #16) with no surgeries and one (#2), after ileostomy and total colectomy very early in the course of the disease. Another seven patients were in remission with 5-ASA treatment only (3 CD, 4 UC). Monotherapy with infliximab, methotrexate, or AZA/6MP was administered to one patient each, combination therapy with infliximab and AZA/6MP to one patient, and 5-ASA with AZA/6MP to one patient. Three patients (14%) remained steroid dependent. Overall, in 11/22 (50%) patients, the treatment was de-escalated or stopped during follow-up; and in 4/22 (18%), the treatment was escalated to biological agents or immunomodulators.

Five out of six patients, who underwent surgery at the time of diagnosis, were with active disease despite the surgical procedure [of them one with IL-10 receptor mutation (patient #13), one with CARMIL 2 mutation (patient #4) and one patient in whom later in the course of the disease ileitis was demonstrated on MRE (patient #5)]. These five patients were treated with TPN, steroids, cyclosporine or anti-tumor necrosis factor (TNF)-α medications. At the end of follow up, the patient with CARMIL 2 mutation was treated with Budesonide gel for upper GI inflammation and was waiting for initiation of Sirolimus. The patient with IL-10 receptor mutation had an episode of severe sepsis after a single dose of Etanercept given for his arthritis, and at the end of follow up was without regular treatment except antibiotics and topical treatment for skin manifestations. His parents refused bone marrow transplant. Four patients (Table 3) were followed for 10 years or longer; of them, three were in remission and one was steroid dependent after surgery at diagnosis.

Severe long-term complications included bowel perforation during endoscopic follow up in one patient, and an Epstein-Barr virus infection in one patient (#10), in which lymphoma was suspected and eventually ruled out after the patient was lost to follow-up in our center.

The most common induction treatment at presentation was corticosteroids, within the range of 80%–92% reported for other series of IO-IBD including recent study from 4 Israeli Health Maintenance Organizations (5, 24, 29). The treatment regimens included 5-ASA, AZA, 6-MP, infliximab, and nutritional support by TPN. Infliximab treatment failure was observed in all, but one of our patients during induction. This high failure rate corroborates other reports of VEO-IBD. One study reported a high rate of treatment discontinuation before week 14 (30), due to adverse effects and treatment failure. Another study reported a higher rate of treatment failure during the first year than in older children (31). Finally, recent data showed that up to 35% newly diagnosed IO-IBD patients at each year fail to respond to biologics (29). Data have not been published specifically on the response to anti-TNFα medications in IO-IBD. The lower response rate to anti-TNFα medications in younger children may reflect a higher predisposition to infections, different pharmacokinetics, or genetic background, leading to non-TNFα mediated inflammation (30, 32, 33). In addition, we did not use therapeutic drug monitoring during the study years, and a more intense treatment regimen may be needed to control inflammation in young patients.

Of our patients with available information regarding nutritional therapy, half needed TPN at presentation. This is similar to the proportion of 59% (10/17), in the Japanese cohort of VEO-IBD (15) but lower than 90% (9/10), reported among patients who were diagnosed with IBD during their first year of life (5). Notably, patients with monogenic disease were also described to have higher TPN requirements (34). In studies of older IBD patients at older ages (35), the TPN requirement for TPN was much lower. Taken together, TPN use at presentation appears to be inversely proportional to patient age at diagnosis. The young age, together with severe diarrhea and failure to thrive, and the low response rate to anti-TNFα medications, are possible causes of the high rates of TPN initiation in IO-IBD.

Surgery at an early stage after diagnosis was performed in 26% of our patients. This is within the range of 19%–50% reported by studies from Asia, England, France and Israel (5, 21, 22, 29). The need for early surgery reflects the severity of disease at presentation in this age group and was shown to have 1.4 times higher risk compared to toddler-onset group (29). Another possible explanation to high surgery rates at this age group is their biological treatment refractory “behavior” most probably due to suboptimal dosing of biological agents and unclear pharmacokinetics (30, 32, 33).

The long-term outcomes of the patients in our cohort were more favorable than previously described, despite the severe disease at presentation. Clinical remission was achieved in 73% of the patients after a median of 51 months. Notably, at the end of the follow up, about one-third of the patients were treated only with 5-ASA and 3 (14%) remained without any treatment, though one of them needed surgery early in the course of the disease. In other studies only 26% of children in the UK with IO-IBD did not require treatment escalation beyond first-line immunomodulator therapy (22), and 2 (20%) of 10 children diagnosed during their first year of life with IBD in France, stopped medications within 1 year and had long-term remission (5). The early surgery rate, 26% at the first hospitalization, was similar to that described in the literature for IO-IBD (7), and higher than in later-onset childhood IBD (36). Interestingly, after the initial surgeries, none of our patients required repeat surgery, except one patient who had a bowel perforation during colonoscopy. Similar to other studies of IO-IBD patients, one of our patients (#5) who was primarily diagnosed with UC and underwent total colectomy, developed ileitis during follow up, and most probably was wrongly diagnosed as UC at diagnosis (37, 38).

Despite presentation with severe disease at a very young age, none of our patients died. Mortality has rarely been reported in relation to IO-IBD. However, higher mortality rates, 7% and 19% were reported for IO-IBD cohorts with high proportions (17% and 44%) of monogenic diseases and immune deficiency (5, 39). The small size of our series precluded identifying factors that associate with such favorable outcomes as long-term remission and treatment de-escalation.

The variable outcomes between studies on IO-IBD and VEO-IBD may result from differences between the cohorts in the study periods, the availability of biologic treatment, the extent of genetic evaluations, and the proportions of patients with monogenic diseases.

Our study has limitations that are associated with its multicenter retrospective design. The genetic evaluation and treatment of VEO-IBD in general, and particularly of IO-IBD, have changed significantly over the past two decades. Secondly, our definition of remission was clinical, and did not include fecal calprotectin levels or consistent evaluation of endoscopic remission. In addition, small bowel imaging was not feasible in this age group at presentation. Nevertheless, our study contributes information on the long-term outcomes of children with IO-IBD as a distinct group, rather than as a part of VEO-IBD and shows similar results to data from a validated Israeli IBD Research Nucleus (29), thus providing validity to our results.

In conclusion, though the evaluation and treatment of children with IO-IBD pose substantial challenges, a large proportion of children have favorable long-term prognosis, even following severe disease course at presentation. Prospective studies of this population are needed to identify predictors for favorable outcomes, to identify those with monogenic diseases, and to evaluate responses to biological treatment using therapeutic drug monitoring.