In vitro and in vivo safety studies of a proprietary whey extract.

A proprietary whey growth factor extract (WGFE) or Lactermin (Lact milk; ermin growth factors) is a whey fraction of milk containing the major proteins lactoperoxidase and lactoferrin, together with a variety of minor proteins and peptides such as the growth factors IGF-I, IGF-II, PDGF, FGF, TGF-ss and betacellulin. This growth factor component of milk has been suggested to possess biological properties such as the promotion of tissue repair and anti-inflammatory activity. In this study the safety of Lactermin has been evaluated using genotoxicity assays (Ames, mouse lymphoma and micronucleus assay) and in a subchronic (13 week) rat oral toxicity study. In vitro Lactermin did not show any mutagenic properties in the Ames or mouse lymphoma assay and in vivo did not show any adverse clinical effects or in the bone marrow of male or female mice. In the subchronic oral toxicity study in which 10 rats per sex were fed Lactermin mixed with rat diet to deliver doses of 300, 1000 and 3000 mg/kg/day for 13 weeks, male and female rats did not show any test article-related clinical observations or effects on body weight, food consumption, ophthalmic effects, functional observational battery, organ weights, locomotor activity, hematology, serum chemistry, urinalysis or macroscopic or microscopic pathology. The results from the genotoxicity studies and the subchronic oral toxicity study suggest Lactermin is safe for consumption with a no-observed-adverse-effect level (NOAEL) of 3000 mg/kg/day.

Use of the 13C-sucrose breath test to assess chemotherapy-induced small intestinal mucositis in the rat.

Mucositis is a debilitating side-effect of chemotherapy which affects the mucosa of the gastrointestinal tract, particularly the small intestine. Currently there are no simple, noninvasive methods to detect and monitor small intestinal function and the severity of mucosal damage. Activity of the brush-border enzyme sucrase provides an indicator of small intestinal absorptive function that remains relatively constant throughout life. Measuring 13CO2 levels in expired breath following ingestion of 13C-sucrose is a non-invasive marker of total intestinal sucrase activity. We evaluated the sucrose breath test (SBT) as an indicator of small intestinal injury and dysfunction, utilizing a rat model of chemotherapy-induced mucositis. SBT results reflected the time-course of damage and repair after methotrexate (MTX) treatment, with damage most severe 72 h after chemotherapy, and repair commencing after 96 h. SBT results correlated significantly with jejunal sucrase activity determined biochemically (r2= 0.89; p < 0.005). Moreover, calcium folinate ingested prior to chemotherapy totally prevented damage to the small intestinal mucosa induced by MTX, as assessed by the SBT in concert with structural, and biochemical indices. The SBT provides a simple, non-invasive, integrated measure of small intestinal damage and function. The SBT holds significant potential to monitor small intestinal function in cancer patients undergoing chemotherapy. This technique possesses further applicability to the screening of newly-developed agents for potential gastrointestinal toxicity including the development of new therapies targeted at minimising or preventing the onset of chemotherapy-induced mucositis.

Effects of insulin-like growth factor-I and its analogue, long-R3-IGF-I, on intestinal absorption of 3-O-methyl-D-glucose are less pronounced than gut mucosal growth responses.

The relationship between insulin-like growth factor-I (IGF-I) peptide-induced increases in bowel mass and functional improvement is unclear. We utilised three independent methods to investigate the effects of IGF-I peptides on intestinal absorption of the glucose analogue, 3-O-methyl-D-glucose (3MG) in rats. Rats received vehicle, IGF-I or the more potent analogue, long-R3-IGF-I via subcutaneously implanted mini-pump, for 7 days, at which time intestinal absorption was assessed by: (1) plasma 3MG appearance following oral gavage, (2) single-pass- or (3) recirculating-perfusion of a jejunal segment. 3MG (320 or 800 mg) was gavaged on day 7 to rats treated with vehicle, IGR-I or long-R3-IGF-I. With the lower 3MG dose, only long-R3-IGF-I increased (40%) the initial rate of 3MG appearance in plasma. IGF-I had no significant effect, whilst at the higher 3MG dose neither peptide was effective. Utilising perfusion techniques, long-R3-IGF-I, but not IGF-I, significantly increased 3MG uptake per cm of jejunum by up to 69%, although significance was lost when expressed as a function of tissue weight. Long-R3-IGF-I, but not native IGF-I, enhanced 3MG absorption from the intestinal lumen, presumably reflecting an increased mucosal mass rather than an up-regulation of specific epithelial glucose transporters.

Effects of TGF-alpha gene knockout on epithelial cell kinetics and repair of methotrexate-induced damage in mouse small intestine.

While previous studies have indicated that exogenous TGF-alpha stimulates epithelial growth, maintenance, and repair of the gut, roles of endogenous TGF-alpha are less well-defined particularly in the small bowel. The current study examined effects of TGF-alpha knockout on adult small intestinal epithelial cell proliferation, migration, apoptosis, and damage/repair response after methotrexate treatment. Compared to normal mice, TGF-alpha gene knockout did not affect crypt cell production, mitosis position, migration, and apoptosis in non-injured intestine. RT-PCR gene expression analysis revealed presence of four out of six TGF-alpha related EGF family ligands in the normal intestine, suggesting a possible functional redundancy of the EGF family in maintenance of the intestine. Although TGF-alpha gene knockout did not significantly impair the overall mucosal repair in methotrexate-induced acute damage in the small intestine, it resulted in a higher apoptotic response in the early hours following methotrexate challenge, and a delayed and reduced crypt cell proliferation during repair. Consistently, after methotrexate challenge, intestinal TGF-alpha mRNA was found to be markedly upregulated in the early hours and during repair in the wild type, and there were similar profiles in the increased expression of all other ligands (except EGF) between the wild type and knockout intestines. Therefore, despite a possible functional redundancy among the EGF family ligands in the normal small intestine, TGF-alpha may play a role in modulating the early apoptotic events and in enhancing the subsequent reparative proliferative response in the methotrexate-damaged intestine.