Mechanical & Industrial Engineering
Permanent URI for this communityhttps://scholarworks.montana.edu/handle/1/33
The mission of the Mechanical & Industrial Engineering Department is to serve the State of Montana, the region, and the nation by providing outstanding leadership and contributions in knowledge discovery, student learning, innovation and entrepreneurship, and service to community and profession.
Browse
2 results
Search Results
Item Hydromulches suppress weeds and maintain fruit production in organically managed strawberry systems(Frontiers Media SA, 2024-05) Ahmad, Waqas; DeVetter, Lisa W.; McFadden, Dakota; Maupin, Brian; Bajwa, Dilpreet S.; Durado, Andrew; Weyers, Sharon; Galinato, Suzette P.; Weiss, Ben; Gramig, GretaPolyethylene (PE) mulches are widely used in strawberry (Fragaria × ananassa Duch) production for weed suppression and crop growth optimization. However, PE mulches are not biodegradable and contribute to plastic pollution. Our objective was to develop and test biodegradable liquid-applied ‘hydromulches’ (HMs) as a sustainable alternative to PE mulch. HM weed suppression efficacy, strawberry plant growth, and yield were evaluated. HM formulations consisted of shredded newsprint paper (NP), water, and a tackifier, either guar gum (GG) or psyllium husk (PH) added at 2 or 6%. Experiments were conducted at two environmentally distinct locations: northwest Washington (WA) and eastern North Dakota (ND). Five HM formulations were compared to black PE mulch within a randomized complete block design with four replications. PE mulch suppressed weeds completely at peak weed emergence and peak weed vegetative growth at both locations. Formulations of HM containing GG provided superior weed suppression compared to other HM formulations at peak weed emergence (4–6 vs. 18–22 plants m-2, respectively). At peak vegetative growth, HM formulations containing GG had the lowest weed density compared to other HMs in ND (1 vs. 9–12 plants m-2), whereas these differences were not observed in WA. Total weed biomass did not differ among HMs across both locations. GG HM formulations deteriorated similarly to PE mulch (3–5% vs. 2%, respectively) in ND, whereas other HMs deteriorated more substantially. In WA, all HMs deteriorated more than PE mulch (6–12% vs. 1%, respectively). Fruit yield did not differ among treatments in weedy and weed-free subplots (194–254 g plant-1) in WA. In ND, yield was greater in all HM treatments compared to PE mulch in both weedy and weed-free subplots. Across both locations, strawberry canopy cover was greater in PE mulch (56.1% canopy cover) compared to 2%GG and NP (42.4 and 39.8% canopy cover). Strawberry plant biomass was similar among mulch treatments. However, strawberry leaf and crown biomass were slightly lower in 2%PH compared to other mulch treatments. Results demonstrate HMs with GG tackifier are a promising alternative to PE mulch in organic strawberry systems based on ability to suppress weeds, enhance strawberry growth, and maintain yield.Item Natural polymer hydrogel based 3D printed bioreactor testing platform for cancer cell culture(Elsevier, 2024-06) Rehovsky, Chad; Bajwa, Dilpreet S.; Mallik, Sanku; Pullman, Jessica E.; Ara, IsmatAlthough two-dimensional cell cultures provide a time- and cost-effective method for testing drugs at the preclinical level, they do not capture the three-dimensional cellular interactions or tumor penetration that must occur in vivo. Therefore, these drugs often fail as they transition from two-dimensional culture models to more complex ones, including animal models or even human clinical trials. The goal of this research was to develop a three-dimensional bioprinted pancreatic cancer drug testing platform that could increase the effectiveness of drug testing during the early preclinical stages. Specifically, different natural polymer hydrogel formulations of cellulose, alginate, and gelatin were tested to find the optimal printability and cell viability. It was determined that a cellulose nanocrystal and alginate hydrogel provided the best printability because of its superior shear thinning properties. In addition, BxPC-3 cells, that were printed and then cultured within this hydrogel for four days, exhibited a range of cell viability between 80 % and 60 %. To simulate vasculature around the bioprinted cultures, a spinning bioreactor was manufactured; however, it disturbed the cells, leading to a decrease in cell viability compared to stagnant cultures. Overall, the platform demonstrated good printability and cell viability for future use in pancreatic cancer drug testing.