A study led by UT Southwestern and Children's Health researchers defines parameters for the number of white blood cells that must be present in children's urine at different concentrations to suggest a urinary tract infection (UTI). The findings, published recently in Pediatrics, could help speed treatment of this common condition and prevent potentially lifelong complications.
If a diagnosis is delayed, he explains, a UTI can develop into a serious infection that can cause lasting consequences. For example, UTI-related kidney scarring has been linked with hypertension and chronic kidney disease later in life.
To diagnose a UTI, doctors must culture a urine sample and wait for it to grow telltale bacteria in a petri dish containing nutrients. However, says Nadeem, this process can take up to two days, delaying treatment. Consequently, he and other doctors typically rely on testing urine for a white blood cell-linked protein known as leukocyte esterase (LE), then confirm the presence of white blood cells—a sign of immune activity—by looking for them in urine under a microscope.
In children, he adds, the number of white blood cells can be highly variable, with some of this variation potentially due to varying urine concentration. As such, it's been unknown what white blood cell number threshold should be used to begin treating a suspected UTI based on urine concentration.
To determine these parameters, Nadeem and his colleagues searched medical records of children younger than 24 months old who were brought to the emergency department at Children's Medical Center between January 2012 and December 2017 with a suspected UTI and had both a urinalysis—in which their urine concentration and the presence of LE and white blood cells were assessed—and a urine culture. The search turned up 24,171 patients, 2,003 of whom were diagnosed with a UTI based on urine culture.
Using their urine's specific gravity—the density of urine compared with water, a measurement that serves as a surrogate for concentration—and the number of white blood cells present in the field of a high-power microscope, the researchers came up with cutoff points for three urine concentration groups: For low urine concentrations, children needed only three white blood cells to suspect UTI; for moderate concentrations, that number was six; and for high concentrations, it was eight.
For each of these concentration groups, leukocyte esterase remained constant, says Nadeem—suggesting that it's a good trigger for analyzing urine for the presence of white blood cells.
Knowing how many white blood cells tend to be present in urine samples at different concentrations in children with UTIs could help physicians start treating these infections before they receive urine culture results, he adds, giving relief to patients and their parents and preventing complications.
"The earlier we can start treatment, the better it is for these young patients," Nadeem says. "Our results add more information to physicians' toolboxes to make this decision."