Hospital das Clínicas is a 3,271- bed hospital employing 9,888 health care providers, serving patients referred from the Public Health System, and a number of patients referred from private health care providers. The hospital manages a day care center to serve its workers, enrolling children from 4 months to 4 years of age. This center enrolls children based on age or child development, separating them into 7 groups: Nursery I and II (N I and N II) with 46 and 59 children; Mini Group I and II (MG I and MG II) with 41 and 49 children and Toddlers I, II, and III (T I, T II, and T III) with 53, 45, and 35 children respectively.

Stool samples from 224 of the 328 children (68.3%) attending this day care were collected during the outbreak period in March and May, 2001. The stool samples were processed by concentration methods for ova and parasite (O&P) examination34–36; smears were stained with Kinyoun's modified acid-fast stain for identification of Cryptosporidium sp.37 One part of the selected positive samples was mixed with 3 parts of 2.5% of potassium dichromate and kept at 4°C until DNA extraction was performed for molecular analysis.

DNA was extracted from aliquots of approximately 300 μl of each stool specimen using a modification of the FastDNA® method (Q-Biogene, Carlsbad, CA.) as previously described.38 The extracted DNA samples were stored at 4°C and used for polymerase chain reaction (PCR) amplification.

A PCR was performed to amplify fragments from 3 different loci of the Cryptosporidium sp genome, ie, 18S rRNA, COWP, and microsatellite locus 1 (ML1), following the procedures described below. The PCR products were analyzed by electrophoresis on 2% SeaKem GTG agarose (Cat. No. 50074, FMC Bioproducts, Rockland, Maine), stained with ethidium bromide and visualized on an ultraviolet transilluminator.

The primer pair named CPBDIAGF/CPBDIAGR that produces fragments of 435, 438, and 455 base pairs (bp) from the C. parvum, C. hominis (formerly know as C. parvum genotype 1), and C. felis, respectively, was used for amplification of a variable region of the SSU-rRNA.39 Sequencing of this region can distinguish between all the Cryptosporidium species and genotypes described to date. Polymerase chain reactions with these primers were performed as previously described.40

Two primer pairs, CRY12/CRY14 and CRY15/CRY9, were used to amplify 2 distinct fragments of the COWP gene. The primer pair CRY12/CRY14 was used to amplify a fragment from the C-terminal domain of this gene. Amplification with this primer pair produces fragments that vary from 568 and 571 bp if used on templates from C. parvum and C. hominis, respectively. The primer pair CRY15/CRY9 was used to amplify a fragment of the N-terminal domain of the same gene. Amplification with these primers produces a DNA fragment of 553 bp from both C. parvum and C. hominis templates.41 Amplifications with primer pairs CRY12/CRY14 and CRY9/CRY15 were performed as described previously,41 the only differences being primer concentration (50 pmoles) and reaction cycles (45 times instead of 30).

ML1 was amplified using primers GAGF (5’ CTAAAAATGGTGGAGAATATTC 3’) and GAGR (5’ CAACAAAATCTATATCCTC 3’); the procedure has been described elsewhere.42 These primers amplify a fragment of approximately 240 bp arranged in tandem GAG repeats. Previous analysis of this locus has revealed polymorphisms that discriminate 2 and 4 genotypes of C. hominis and C. parvum, respectively.

Amplification products were purified by using the Stratagene PCR purification kit (Cat. No. 400773, Stratagene, La Jolla, Calif.). Sequencing reactions were performed using the Perkin Elmer Big Dye kit (Cat. No. 4303149, PE Biosystems, Foster City, California), and sequence data were obtained by using the Perkin Elmer ABI 3100 automatic DNA sequencer. Sequences were assembled using the program SeqMan II (DNASTAR Inc., Madison, Wisc.). Genotype identification of the ML1 was done by aligning unknowns with master sequences retrieved from GenBank using the program, Clustal X v.18.43 For the other loci analyzed, genotype identification was done by using the GeneStudio suite (GeneStudio Inc., Suwanee, Georgia).

The investigation included interviews with children's mothers and staff as well as analysis of sanitary conditions of the day care center. Children with diarrhea were defined as those with liquid or semi-liquid stools. The risk factors were determined using all patients who were positive for Cryptosporidium as confirmed by PCR and compared with 100 negative-control patients. We considered the same risk factors as those observed by the hospital surveillance group.44

We developed an analytical study (retrospective cohort) for Cryptosporidium processing the distribution of frequencies among 2 groups for the qualitative variables, including sex, diarrhea, class, exposure to filtered tap water, use of an earth filter, use of a nursing bottle, use of diapers, ingestion of raw vegetables, and contact among children in the cafeteria and recreation area, using Pearson's chi square test.45 Fisher's exact test was used when the expected values were less than 5. We considered the value P < 0.05 as statistically significant. Then we calculated the relative risks and their confidence intervals. For ages, we used the Mann-Whitney's nonparametric test,46 and P < 0.05 was considered statistically significant.

The day care at Hospital das Clinicas had some diarrhea control measures, including dismissal of children with diarrhea, assigning different employees to different functions, such as changing diapers and handling food. Employees conducted such activities in different areas, performing appropriate disposal of diapers and hand washing between procedures. There were distinct restrooms for children and staff, and the water and sewage services used by the day care were the same used by the entire Hospital.

Of the 224 children with stool samples analyzed for parasites, 47 (21%) were negative and 26 (11.6%) were positive for Giardia lamblia, while 23 (10.3%) were positive for other parasites, ie, Isospora belli, Trichuris trichiuris, Entamoeba coli, Entamoeba hartmani, Enterobius vermicularis, and Ascaris lumbricoides. For Cryptosporidium sp, 29 (12.9%) stool samples were positive by microscopic analysis as well as by PCR and were used for analytical epidemiology.

Cryptosporidium DNA was amplified by PCR from the 29 stool samples using 4 different primer pairs that generate a) 2 independent fragments from the C and N terminal domains of the COWP gene (primer pairs CRY12/CRY14 and CRY15/CRY9, respectively); b) 1 fragment from the SSUrRNA coding region (primers CPBDIAGF/CPBDIAGR); and c) the ML1 (primers GAGF and GAGR).

Genotyping of Cryptosporidium was based on sequencing of all fragments amplified for speciation and for identification of species genotype. The expected fragment size was amplified in all samples using the primers described above. Table 1 summarizes the results obtained from this analysis. Not all samples were amplified with all primers, which might indicate a difference of amplification efficiency among these tools. The only species found in this set was C. hominis. Data obtained from the ML1, which can distinguish between the genotypes of C. hominis and C. parvum, revealed the presence of only 1 genotype, ie, ML1 genotype1, in 45% of the 29 samples positive for C. hominis, which was subjected to ML1 analysis.

A total of 180 cases met the diarrhea illness definition (general attack rate = 54.9%): 19 (10.5%) cases occurred in March, 152 (84%) in April, and 9 (5.5%) in May. Of these, 30 cases were from class N I (attack rate [AR] = 65.2%), 33 from N II (AR = 55.9%), 20 from MG I (AR = 48.8%), 34 MG II (AR = 69.4%), 25 T I (AR = 47.2%), 28 T II (AR = 62.2%), and 10 T III (AR = 28.6%). We analyzed 164 cases (91.1), and the presence of Cryptosporidium was statistically significant in all classes (P = 0.001), with a higher concentration in MG I (Table 2). We observed no significant association of C. hominis with sex, diarrhea, use of a nursing bottle, and contact with other children during recreation (results summarized in Table 3). Children using diapers and drinking water filtered through an earth filter were at higher risk for acquiring C. hominis infection compared to the control group (28.4% versus 12.5%; P = 0.037 and 39.1% versus 13.3%; P = 0.001, respectively). However, risk for acquiring C. hominis infection was lower for children who used filtered tap water and ingested raw vegetables (P < 0.05). For children with C. hominis who drank filtered tap water, the frequency was 13.3% versus 39.1% compared to children who did not drink filtered tap water. Children who ingested raw vegetables had a C. hominis infection frequency of 12.5% versus 28.4% for children who did not eat raw vegetables (P = 0.037). There was no significant difference in ages between infected and uninfected children (P = 0.316).