ANNALS OF CLINICAL AND LABORATORY SCIENCE, Vol. 12, No. 2 Copyright 1982, Institute for Clinical Science, Inc. Improved Immunodiagnosis of Neutrophil Dysfunction in the Newborn and Infant ALAN B. LOREN, M.D., Ph.D., M. M. YOKOYAMA, M.D., Ph.D., and EGIL FOSSLIEN, M.D. Departm ent o f Surgery, Loyola University Medical Center, Maywood, IL 60153 and Departm ents o f Pathology and M icrobiology, University o f Illinois M edical Center, Chicago, IL 60680 ABSTRACT An improved assay for the simultaneous assessment of phagocytic uptake (via Immunobeads ) and metabolic integrity (via nitroblue tetrazolium (NBT) dye reduction) was used to evaluate the neutrophil function in neonates, one year olds, and adults. The unique advantage of this assay is that it offers greater standardization since the beads are commercially available with a known quantity of immunoglobulin bound to their surface which allows for considerably less variation than particles opsonized in vivo. Blood samples were collected from 20 full term healthy neonates, 20 healthy one year olds, and 20 healthy adults. The neutrophils were isolated, and phagocytic and killing function compared among the three groups. It was found that the neonates had a small but significant neutrophil dysfunction with respect to phagocytic and intracellular killing ability when compared to the one year olds and adults. Additionally, blood was collected and evaluated from five premature infants with varying degrees of stress. Their neutrophil dysfunction was much more pronounced. Although it was previously thought that full term healthy neonates have no demonstrable neutrophil dysfunction unless stressed in some manner, a subtle dysfunction was identified even in unstressed neonates. It was, however, found to be more pronounced if the neonate was either premature or stressed in some manner. It is hoped that this assay, through its greater sensitivity and ease of standardization, will uncover subtle neutrophil dysfunctions in various disease states that as yet remain undiagnosed. The clinical significance of such subtle neutrophil dysfunctions is not yet known. Introduction Numerous methods have been described for analyzing neutrophil function and can be categorized according to the particular function being studied. Neutrophils have five basic functions: motility, recognition, ingestion, degranulation, and intracellular killing. A defect in any one of these functions is associated with an alteration in primary immune response 0091-7370/82/0300-0111 $00.90 Institute for Clinical Science, Inc.
112 LOREN, YOKOYAMA, AND FOSSLIEN of the host, resulting in an increased susceptibility to infection. Two assays have been widely used clinically to measure the intracellular killing functions of the neutrophil, the nitroblue tetrazolium (NBT) dye reduction test and the intraleukocyte killing test. It has been shown that neutrophils rapidly generate reducing power via the hexose monophosphate shunt in what is termed a metabolic burst.1,4,9 During this process if NBT is present, it will be reduced to formazaan and can be detected either by visual inspection or spectrophotometrically.3 The intraleukocytic killing test is performed by incubating viable bacteria with a suspension of lysed neutrophils and subsequent assessment of bacterial viability.5 An improved assay for the simultaneous assessment of phagocytic uptake (via Immunobeads )* and metabolic integrity (via NBT dye reduction) has been recently developed.14 The unique advantage of the Immunobead assay is that it offers greater standardization since the beads are prepared with a known quantity of immunoglobulin bound to their surface which allows for considerably less variation than particles opsonized in vivo. The efficacy of this assay has been previously demonstrated in a study involving a small group of normal individuals and several patients with chronic granulomatous disease (CGD).14 In that study, all of the normal adult donors had neutrophils that engulfed the Immunobeads and reduced the NBT dye. Additionally, the neutrophils from patients with CGD showed ingestion equal to or greater than that of normal neutrophils, but they were totally unable to reduce the NBT dye in all cases. The purpose of this study was to use the newly developed Immunobead assay in evaluating neutrophils as a function of age, and hopefully to settle the controversy as to whether or not neonatal * Bio-Rad Laboratories, Richmond, CA. neutrophils are less functional than adult neutrophils. Materials and Methods I s o l a t i o n o f N e u t r o p h i l s Approximately six ml of blood were collected in heparinized tubes from each of the donors. Twenty samples were from cord blood of full term neonates of uncomplicated pregnancy and delivery with APGAR scores of 7 or greater. Another 20 samples were from healthy children between the ages of one and two years. Finally, 20 samples were from healthy adults between the ages of 18 and 40 years. Additionally, two ml of venous blood were taken from five premature infants at three days of age. The blood was diluted 2:1 with phosphate buffered saline (PBS) and, after mixing by gentle inversion, was layered on six ml of a double layer gradient of Ficoll-Hypaque solution. The bottom layer consisted of three ml of Ficoll-Hypaque solution (specific gravity 1.119) prepared by mixing 10 parts of 50 percent Hypaque* with 20 parts of 9 percent Ficoll 400 f. The top layer consisted of three ml Ficoll-Paque (specific gravity 1.007) f. The solutions were layered in 16 x 100 mm round bottom plastic tubes $ and centrifuged at 400 x g for 30 minutes at room temperature.6 After centrifugation, two cell zones were visible, the lower zone predominantly neutrophils and the upper zone predominantly lymphocytes. The neutrophil zone was removed by aspiration with a Pasteur pipet and placed in a conical plastic tube. $ The suspension was then washed by adding 8 to 10 ml of phosphate buffered saline (PBS) and gently mixed. This was followed by centrifugation for 10 minutes at 350 x g at room temperature. The supernatant was then discarded, and the wash- * Winthrop Labs, NY. f Pharmacia Fine Chemical, Piscataway, NJ. j Falcon Plastics, Los Angeles, CA.
IM M U NODIAGNOSIS O F N E U T R O P H IL D Y SFU N C T IO N IN N EW B O R N 113 ing procedure repeated two more times. After the third wash, the cells were resuspended in PBS with 10 percent fetal calf serum (PFS-FCS), and the cell count adjusted to 3 x 106 cells per ml. P r e p a r a t i o n o f I m m u n o b e a d s i n N i t r o b l u e T e t r a z o l i u m Nitroblue tetrazolium was reconstituted in PBS by adding 6 mg NBT per ml of PBS and vortexed vigorously for one minute followed by filtering of the insoluble residue. The NBT solution must be shielded from light as much as possible, since NBT is a light labile compound and, for optimal results, this solution was prepared fresh each day. Immunobeads, which are polyacrylamide beads coated with rabbit anti-human IgG antibody, IgG class, were then suspended in the NBT solution at a concentration of 150 to 200 x 106 beads per ml. N e u t r o p h i l F u n c t i o n A s s a y Two hundred j l \ of the neutrophil suspension were added to an equal volume of the Immunobead suspension in 12 x 75 mm siliconized glass tubes. The tubes were then centrifuged for one minute at 160 x g at room temperature. The supernatant was drawn off to remove excess Immunobeads and replaced with an equal volume of PBS-FCS. The tubes were then incubated for five minutes at 37 C. An incubation time of five minutes was chosen because it has been previously demonstrated that there is no significant difference with respect to phagocytosis and NBT dye reduction when the incubation time is varied betw een five and 30 m inutes.14 After incubation, the pellet was gently resuspended and the neutrophil function determined. This was done by placing one drop of the cell suspension on a microscope slide and covered with a glass coverslip. Two hundred Sigma, St. Louis, MO. TABLE I Comparison of Neutrophil Function in Adults, One Year Olds, and Full Term Neonates TFN PFN AFN Donor (Mean ± S.D.) (Mean ± S.D.) (Mean ± S.D.) Adults (n=20) 81.0 ± 7.5 10.2 ± 4.3 8.8 ± 3.9 One year olds 80.8 ± 3.4 9.6 ± 1.5 9.6 ± 4.2 (n=20) Full term 70.6 ± 6.5 14.2 ± 5.8 15.2 ± 5.2 neonates (n=20) p < 0.01 TFN = Totally functional neutrophil, i.e. capable of phagocytosis and nitro blue tetrazolium (NBT) dye reduction. PFN = Partially functional neutrophil, i.e. capable of phagocytosis, but not NBT dye reduction. AFN = Afunctional neutrophil, i.e. incapable of phagocytosis hence no assessment of NBT dye reduction is possible. cells were then observed microscopically at a magnification of 400 x. In this study, all neutrophils were grouped into one of three categories; totally functional neutrophils (TFN), partially functional neutrophils (PFN), and afunctional neutrophils (AFN). A TFN is a cell that has the ability to ingest the Immunobeads, indicating that the cell is capable of phagocytosis in addition to being able to reduce the NBT dye (seen as a color change from yellow to dark purple) which indicates metabolic integrity and has been shown to correlate with intracellular killing ability.8*15 A PFN is defined as a cell capable of phagocytic function although it lacks the metabolic integrity. The AFN is one that does not ingest the beads at all, hence no assessment of its metabolic integrity is feasible. Results The mean percentage of totally functional neutrophils isolated from adults, children one year of age, and neonates was 81.0 percent, 80.8 percent, and 70.6 percent, respectively. The mean percentage of partially functional neutrophils was 10.2 percent, 9.6 percent, and 14.2 percent, respectively. The mean percentage of afunctional neutrophils was 8.8 percent, 9.6 percent, and 15.2 percent, respectively.
1 14 LOREN, YOKOYAMA, AND FOSSLIEN Additionally, the néutrophils of five preterm infants were isolated and evaluated. Two of the infants were 26 weeks gestational age. One had 68 percent TFN, 16 percent PFN, and 16 percent AFN. The other had 70 percent TFN, 12 percent PFN, and 18 percent AFN. Two 28 week gestational age infants were studied. One had 75 percent, 13 percent, and 12 percent TFN, PFN, and AFN, respectively. The other 28 week gestational age infant who was stressed by a complicated delivery with a low APGAR and resultant septicemia had 57 percent, 21 percent, and 22 percent, respectively. A 31 week gestatational age infant who was considered stressed owing to septicemia had 53 percent, 22 percent, and 25 percent, respectively (table II). Discussion As with many in vitro systems, neutrophil function assays vary considerably in design. Included among the important variables are cell concentration, opsonic concentration, type of particle being ingested, and phagocyte : particle ratio. Despite these differences, results obtained by most investigators studying neonatal neutrophils have been reasonably consist- TABLE I I Comparison N eu tro p h il Function In Five Preterm N eonates Gestational Age TFN PFN AFN Weeks (percent) (percent) (percent) 26 68 16 16 26 70 12 18 28* 57 21 22 28 75 13 12 31* 53 22 25 *Indicates the neonate was stressed. TFN = Totally functional neutrophil, i.e. capable of phagocytosis and nitro blue tetrazolium (NBT) dye reduction. PFN ~ Partially functional neutrophil, i.e. capable of phagocytosis, but not NBT dye reduction. AFN = Afunctional neutrophil, i.e. incapable of phagocytosis hence no assessment of NBT dye reduction is feasible. tent. One group of investigators has found that the neonatal neutrophil is equal to the adult neutrophil in phagocytic ability under normal conditions.5,10-13 However, a second group of investigations carried out under stress conditions concluded that the neonatal neutrophil is deficient in phagocytic ability when compared with that of the adult.10,12 W hen intracellular killing function was investigated, similar results were obtained, i.e., studies under normal conditions showed no significant difference betw een neonatal and adult neutrophils while studies under stress conditions revealed a deficiency in intracellular killing function by the neonatal cells.13,17-20 It is our belief that there is indeed a deficiency in the neonatal neutrophil, and the defect is present at the level of both phagocytic ingestion and intracellular killing functions. In our study, the neonatal cells showed a significantly lower percentage of TFN s with a resultant increase in PFN s and AFN s. The main difference betw een our study and previous ones is that the present authors were able to uncover the defect under normal conditions while other investigators found the defect only under stress conditions. It is our contention that the controversy is related to the sensitivity of the assay. An individual with a major neutrophil dysfunction becomes particularly susceptible to infections with Staphylococcus aureus, the enteric bacilli, and certain fungi (Candida and Aspergillus). Since these infections are not a problem in most neonates, it is likely that the neutrophil dysfunction, if present, is very slight. For this reason, the dysfunction could only be detected by a very sensitive assay. It is only when the neonate is stressed that the dysfunction becomes pronounced enough to be detected by less sensitive assays. When the neutrophil function of presumably healthy one year olds was compared to that of adults, no significant difference was found. However, when
IM M U N O D IA G N O SIS O F N E U T R O P H IL D Y SFU N C T IO N IN N E W B O R N 115 neutrophils from premature neonates were evaluated, the results were more dramatic. Owing to the small num ber of premature neonates in this study, the results are difficult to interpret completely, although the presence of a neutrophil dysfunction is obvious. In our study, the magnitude of the dysfunction does not appear to be related to gestational age; however, two of the neonates were stressed, which by itself seems to exacerbate the dysfunction. One of the stressed infants underw ent a complicated delivery and, subsequently, had a low APGAR score and w ent on to develop infection. The other stressed infant was suffering from septicemia at the time of the evaluation. The stressed infants had a more pronounced neutrophil dysfunction, but they could not be equally compared to the others. In conclusion then, our assay appears to be more sensitive than previous methods for evaluating neutrophil function, in addition to providing a simpler method for simultaneous evaluation of phagocytic and intracellular killing ability. Furthermore the existence of a subtle yet significant dysfunction has been demonstrated in neonatal neutrophils under normal conditions. Finally, our studies indicate that a stressed neonate will have an even more pronounced neutrophil dysfunction. It is hoped that this assay, through its greater sensitivity and ease of standardization, will uncover subtle neutrophil dysfunction in various disease states that as yet remain undiagnosed. References 1. B a e h n e r, R. L.: The biochemical basis of NBT reduction in normal human and CGD PMN. Blood 4 8 :3 0 9, 1976. 2. C o e n, R., G r u s h, O., a n d Ka u d e r, E.: S tu d ie s o f b a c te rio c id a l a c tiv ity a n d m e ta b o lis m o f th e le u k o c y te s in fu ll te rm n e o n a te s. J. 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O D o n n e l l, M. ]., J a b s, A. D., H o r i t a, M., R e g a n, M. A., and Y o k o y a m a, M. M.: The application of Immunobeads in the NBT test for the detection of ingestion and killing functions of human neutrophils. Immunol. Comm. 8:539, 1979. 15. P a r k, B. H., F i k r i g, S. M., and Sm i t h w i c k, E. M.: Infection and nitroblue tetrazolium reduction by neutrophils. Lancet 2:532, 1968. 16. P a r k, B. H., H o l m e s, B., a n d G o o d, R. A.: M e ta b o lic a c tiv itie s in le u k o c y te s o f n e w b o rn s. J. P ed iat. 76 :237, 1970. 17. Q u i e, P. G., W h i t e, J. G., H o l m e s, B., and G o o d, R. A.: In vitro bacteriocidal capacity of human polymorphonuclear leukocytes: Diminished activity in chronic granulomatous disease of childhood. J. Clin. Invest. 46:668, 1967. 18. S h i g e o k a, A. O., S a n t o s, J. I., and H i l l, H. R.: Functional analysis of neutrophil granulocytes from healthy, infected and stressed neonates. J. Pediat. 95:454, 1979. 19. V a n E p p s, D. E., R e e d, K., and W i l l i a m s, R. C.: Suppression of human PMN bacteriocidal activity by human IgA paraproteins. Cell. Immunol. 36:363, 1978. 20. W r i g h t, W. C., A n k, B. K., and H e r b e r t, J.: Decreased bacteriocidal activity of leukocytes of stressed newborn infants. Pediatrics 56:579, 1975.