A method of using microfluidic chips to significantly accelerate the time to identify and quantify microbes in a biological sample and test them for antibiotic resistance, particularly for urinary tract infections. A first microfluidic chip uses antibody or similar probes to identify and quantify any microbes present. The same or a similar chip uses antibody or similar probes to identify microbes with DNA or RNA known to indicate antibiotic resistance. Another microfluidic chip tests for antibiotic susceptibility of any microbes by growing them in very small wells in the presence of antibiotics, reducing the time required for such testing by as much as 95%. Another microfluidic chip runs traditional urinalysis or similar tests.

The disclosure provides compositions and methods for the detection of renal disease and periodontal disease in mammals.

The present invention relates to methods for detecting, diagnosing and/or treating ulcerative interstitial cystitis (UIC) by detecting in a urine sample from a patient the levels of each of the proteins IL-6, IL-8 and GRO [also known as CXCL 1 (chemokine C-X-C motif ligand 1]. In some embodiments, the method also includes diagnosing the patient with UIC when each of the proteins IL-6, IL-8 and GRO in the urine sample is at a different level than a statistically validated threshold for the respective proteins. In some embodiments a companion diagnostic, e.g., a cystoscopy, is used in conjunction with the protein biomarker diagnostic. In some embodiments, once UIC is diagnosed, the patient is treated for the UIC.

Described herein are kits for assessing the calcium oxalate titration test of an animal as well as methods for predicting the risk of calcium oxalate stone formation. Further described herein are methods and compositions forinter alialowering the specific gravity of urine and lowering the calcium oxalate titration test in felines. In particular, diets and methods utilizing certain amounts and ratios of arachidonic acid (AA), eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) are disclosed herein.

Method for detecting a urinary tract infection (UTI) in a subject comprising determining levels of one or more biomarkers selected from MMP8, HNE, Cystatin C, MMP9, HSA, IL-8, interleukin-6 (IL-6), interleukin-1 beta (IL-1b), fibrinogen, RBP4, active MMP9 and MMP2, NGAL, Desmosine, MPO and CRP in a urine sample obtained from the subject. The determined levels may then be compared with a threshold level, wherein increased levels of at least one of the biomarkers in the urine sample relative to the threshold level is indicative of the presence of a urinary tract infection. Methods for monitoring a UTI and monitoring treatment of a UTI are also provided as are companion systems or test kits.

Several microfluidic chips are used to significantly accelerate the time to identify and quantify microbes in a biological sample and test them for antibiotic resistance, particularly for urinary tract infections. A first microfluidic chip uses antibody or similar probes to identify and quantify any microbes present. The same or a similar chip uses antibody or similar probes to identify microbes with DNA or RNA known to indicate antibiotic resistance. Another microfluidic chip tests for antibiotic susceptibility of any microbes by growing them in very small wells in the presence of antibiotics, reducing the time required for such testing by as much as 95%. Another microfluidic chip runs traditional urinalysis or similar tests.

The disclosure provides compositions and methods for the detection of renal disease and periodontal disease in mammals.

Described herein are methods and compositions forinter alialowering the specific gravity of urine and lowering the calcium oxalate risk index of in felines. In particular, diets and methods utilizing certain amounts and ratios of arachidonic acid (AA), eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA).

Several microfluidic chips are used to significantly accelerate the time to identify and quantify microbes in a biological sample and test them for antibiotic resistance, particularly for urinary tract infections. A first microfluidic chip uses antibody or similar probes to identify and quantify any microbes present. The same or a similar chip uses antibody or similar probes to identify microbes with DNA or RNA known to indicate antibiotic resistance. Another microfluidic chip tests for antibiotic susceptibility of any microbes by growing them in very small wells in the presence of antibiotics, reducing the time required for such testing by as much as 95%. Another microfluidic chip runs traditional urinalysis or similar tests.

The present disclosure relates to, inter alia, materials, and methods for detection of infection. More particularly materials, and methods for detecting an infection in a subject's urine or wound exudate are described, e.g. by electrochemically measuring a target molecule and/or a metabolic activity associated with infection using an electrochemical sensor array.