Large-scale Production Research Articles

Graphene Oxide and Based Materials: Synthesis, Properties, and Applications – A Comprehensive Review

Graphene-based materials have garnered significant interest in the burgeoning field of contemporary flexible and bendable technologies. Graphene has emerged as a prime candidate for the development of flexible electronics due to its outstanding electrical, mechanical, and optical properties, coupled with the ease of functionalizing its derivatives. This review provides an exhaustive analysis of the latest advancements in the synthesis and applications of graphene-based composites. Exceptional properties of Graphene including high thermal conductivity, chemical stability, optical transparency, high current density, and increased surface area, have broad implications across thermodynamics, chemistry, optics, and mechanics. The growing use of graphene oxide materials across various industries has fueled a surge in interest. The synthesis of graphene oxide compounds follows established procedures such as those by Brodie, Staudenmaier, and Tour, with ongoing discussions on large-scale production using various oxidants. Recent developments have led to numerous new, enhanced, and modified Hummers techniques for producing graphene oxide. Graphene oxide (GO) serves as a crucial foundational material for a wide range of applications, including energy storage, water purification, and as a composite in biosensors, electronics, and hazardous gas removal. This review delves into these applications, highlighting GO’s role in improving the efficiency and performance of these technologies. Additionally, the paper addresses the current challenges and obstacles in the development and application of graphene, providing insights into potential solutions and future research directions. By offering a comprehensive and practical database, this review aims to facilitate the future development of graphene-based composite materials, driving innovation and advancements in various high-impact applications.

Kinetics of hydrothermal reactions of n-butanol over Pt/Al2O3 catalyst for biopropane fuel gas production

Energy defossilisation using drop-in biofuels is an important step towards Net Zero. Producing low-carbon clean-burning propane fuel from biomass provides such additional sustainability benefits. In this work, kinetics of hydrothermal reactions of n-butanol, a biomass-derived feedstock, to produce propane over 5 wt% Pt/Al2O3 catalyst have been studied from 523- 573 K. Experimental data revealed negligible internal and external mass transfer effects and, when fitted to an integral power-rate law equation, gave activation energy of 70 kJ mol−1 (n-butanol reaction order = 1). Furthermore, an appropriate Langmuir-Hinshelwood model was developed, which predicted similar activation energy 62 kJ mol−1. Low adsorption enthalpies for n-butanol (–33.51 kJ mol−1) and water (−18.16 kJ mol−1) indicated weak interactions on the catalyst surface. These agreed with the fast reaction rate of ≈1.0 x 10-5 mol gcat-1 s−1 obtained at ≥ 548 K. As a new research area, generation of such accurate kinetics data will contribute to process development for large-scale biopropane production.

Dual-functionalized ORMOSIL nanoparticles to enhance superhydrophobicity of epoxy based coatings

Organically modified silica (ORMOSIL) nanoparticles bearing fluoro-octyl and glycidoxy-propyl groups were prepared by two simple methods: i) modification of silica (SiO2) nanoparticles with the corresponding organo-silanes and ii) sol-gel process involving tetraethoxy-silane in the presence of the organo-silanes. These hydrophobic ORMOSIL particles were mixed with epoxy resin/amino-based hardener in 2-propanol medium and sprayed on the surface of carbon-steel substrate. The epoxy coating containing ORMOSIL prepared by modification of SiO2 nanoparticle presented outstanding water repellence with water contact angle (WCA) of ≈ 162° and high roll-off ability of the water droplets. Furthermore, excellent adhesion to the substrate was evidenced by sandpaper abrasion and tape peeling test. The effect of the solid content in the 2-propanol dispersion on the superhydrophobicity character was investigated. It was observed that the spray dispersion with higher solid concentration resulted in better superhydrophobicity response, mechanical durability and effective self-cleaning behavior. The hierarchical structure and roughness were identified by scanning electron microscopy (SEM) and atomic force microscopy (AFM). The coatings presented in this work are strong candidates for large scale production due to the low-cost and simplicity of the spraying technique and the economically feasibility of the involved compounds.

High efficient synthesis of benzyl lactate through waste PLA alcoholysis by protic ionic salt

Benzyl lactate (BL) is a critical reagent in pharmaceutical and chemical synthesis due to its versatility. Traditional synthesis of BL was constrained by the high cost and low yield, thereby hindering the feasibility of large-scale production. Here, we reported a novel synthesis strategy for BL by utilizing the alcoholysis of waste polylactic acid (PLA) by benzyl alcohol with the protic ionic salt, HTBD-OAc, as the catalyst. The gram-scale experiments achieved a 94.9 % yield, and the robustness of this reaction was evidenced by the yield maintaining 92.5 % across six recycling experiments. More impressively, kilogram-scale synthesis facilitated a complete conversion of PLA to BL, achieving an unprecedented yield of 98.7 % at 180 °C within two hours. The exceptional catalytic efficiency of this reaction is attributed to the synergistic functions between the HTBD+ cation and OAc− anion in the catalyst HTBD-OAc. This study heralds a significant stride towards the sustainable and scalable production of high-purity benzyl lactate, paving the way for extended industrial applicability for this essential compound.

Dynamic hydrogen bubble template electrodeposition of a self-supported Co-P electrocatalyst for efficient alkaline oxygen evolution reaction

The development of efficient, inexpensive, and earth-abundant electrocatalysts for the oxygen evolution reaction (OER) represents a significant challenge for the large-scale production of hydrogen. The primary obstacle to the advancement of OER is the necessity for a considerably higher overpotential than the theoretical oxygen evolution potential, due to the sluggish kinetics of the electron transfer reaction, which involves a large amount of thermodynamic energy. In this article, amorphous and cauliflower-like Co-P electrocatalysts were in situ grown on nickel foam by dynamic hydrogen bubble template (DHBT) electrodeposition method. The Co-P electrocatalyst with Co/P ratio optimal presented excellent electrocatalytic activities with a low overpotential of 239 mV for OER at 10 mA·cm−2 and long-term stability in 1.0 M KOH. The outstanding OER performance of the catalyst is mainly attributed the synergistic effect of amorphous and cauliflower-like structure, superhydrophilicity surface, and the electronic regulation by adjusting the atomic ratio of Co to P. This research will bring fresh ideas and strategies for developing novel simple, affordable, and efficient electrocatalysts to boost OER kinetics.

Enhancing the oil/water separation efficiency of polylactic acid fiber membrane via polydimethylsiloxane-polycaprolactone copolymer

Membrane technology is one of the important methods of treating oily wastewater due to low energy consumption. How to design the membrane with high efficiency, biodegradable, reusable and good mechanical properties has attracted increasing interest. In this work, a polydimethylsiloxane-polycaprolactone (PDMS- PCL) was synthesized to endow polylactic acid (PLA) fiber membrane with superhydrophobicity and superoleophilicity via electrospinning without secondary processing. When the blend ratio of PDMS-PCL/PLA is 15wt%, the water contact angle of the fiber membrane is 155.1 ± 3°, and the oil contact angle is almost zero. The tensile strength and elongation at break are 2.05 ± 0.16MPa and 37.9 ± 2.3%, respectively. The fiber membrane exhibited high oil/water separation performance and quick adsorption of oil drop underwater. The permeate flux and separation efficiency for n-hexane are 3550 ± 50L·m-2·h-1 and 99.3 ± 0.2%, separately. It also has excellent self-cleaning and durable properties. The fiber membrane maintains high oil flux, separation efficiency, and mechanical properties after more than 10 rounds of separation. The fiber membrane can resist the external environment variation such as to some extent. The water contact angle of the fiber membrane undergoing friction and heating at 100 °C stably remains at about 150°. The weight loss is little in salt solution. Then this simple efficient method is suitable large-scale production and will promote membrane technologies in application of oil/water separation.

Date palm (Phoenix dactylifera L.) pollen-based microgel and its promising medical and environmental applications

Pollen, a natural bi-layered porous microcapsule, plays a crucial role in plant reproduction by protecting the plant's genetic material. Due to its unique properties, it has garnered attention for medical and environmental applications. Recent studies have focused on transforming the pollen's rigid structure to soft, gel-like matter, enabling the creation of pollen-based products such as paper and sponge. The main factor in the gelation process involves pectin-to-pectate conversion within the pollen's inner layer. Previously, claimed that this transformation is restricted to eudicot plants, and some others, such as monocot plant pollens do not exhibit this gelation phenomenon. In this study, we successfully produced microgel from date palm (Phoenix dactylifera L.) pollen (DPP), challenging this assertion. A significant portion of these monocot plant pollens exceeds the requirement of date production, presenting an opportunity for large-scale production without environmental concerns. Here, we have prepared pollen-based microgel, paper, and sponge and conducted a comprehensive analysis using various techniques such as optical and fluorescence microscopy, scanning electron microscopy (SEM), Brunauer-Emmett-Teller (BET), elemental CHN analysis, Fourier-transform infrared spectroscopy (FTIR), thermogravimetric differential thermal analysis (TGA/DTA), rheological measurements, mechanical analysis, pH-sensitivity tests, swelling analysis, and oil absorption capacity. By discerning the specific physicochemical properties of these materials, we propose potential medical and environmental applications for further investigation.

A robust, recyclable, and biodegradable whole corn bioplastic enabled by dissolution-regeneration strategy

Biomass-based plastic, derived from renewable and biodegradable resources such as plant materials, offers a promising solution to mitigate the severe energy and environmental issues caused by petroleum-based plastics. While challenges remain in addressing complex and costly processing produces, as well as improving mechanical properties and water resistance in bioplastic production, these factors hinder the widespread application of bioplastic. Herein, we proposed a facile and cost-efficient method to prepare high-performance bioplastics from whole corn by dissolving it in a green metal salt solution system (ZnCl2/AlCl3 system) to deconstruct into a homogeneous and viscous precursor slurry, and then regenerating it from ethanol to form a dense hydrogen and ionic crosslinking network. The prepared whole corn-based bioplastic has a uniform and dense structure, exhibiting excellent mechanical properties (78.5 MPa), water stability, thermostability, and recyclability. Owing to entirely biomass-based components and their effective processes, bioplastic is biodegradable and has low environmental impact. This strategy provides an avenue for the scalable production of large-scale production of high-performance, environmental, renewable, and biodegradable bioplastic, thus demonstrating a promising alternative for reducing the consumption of petroleum resources.

Biofuel: A sustainable and clean alternative to fossil fuel

Increasing fuel consumption has threatened energy supply stability, raising significant environmental and economic concerns for many countries. As global energy demand rises, reliance on fossil fuels poses serious challenges, including greenhouse gas emissions and resource depletion. In response, substantial efforts are made to develop and adopt clean renewable fuel alternatives. Replacing fossil fuels with biofuels can significantly reduce emissions of carbon monoxide (CO), sulfur dioxide (SO2), nitrogen oxides (NOx), particulate matter (PM), and tropospheric ozone (O3). Recent advances in the development of biofuels via genetic engineering have larger prospects for commercial-scale production. However, large-scale production remains challenging; therefore, to address this issue, it is vital to convert biomass into biofuels by developing revolutionary technology to improve biofuel production to meet present and future energy demands. The study aims to analyze alternative renewable energy sources and recent trends in the production of biofuel that are required to meet the demands of the global energy sector and economy while also considering future demand and utilization.

Optimizing Basil Seed Vigor Evaluations: An Automatic Approach Using Computer Vision-Based Technique

The short cultivation cycle and high essential oil content of basil plants render them a valuable raw material source for diverse industries. However, large-scale production is hindered by the lack of specific protocols to assess seed vigor; thus, a consistent supply of high-quality seeds that meet consumer demands cannot be ensured. This study investigated the effectiveness of an automated system for seedling analysis as a tool for evaluating basil seed vigor and compared it to traditional tests. For this purpose, seeds from eight commercial lots were evaluated in two separate trials spaced six months apart using the following tests: germination, first germination count, saturated salt accelerated aging, primary root emergence, mean germination time, seedling emergence, seedling emergence speed index, and computerized seedling image analysis. The parameters provided by the system allowed us to clearly and objectively classify the basil seed lots based on vigor, and the results were strongly and significantly correlated with the findings of traditional vigor tests, particularly between the vigor index and seedling length. Digital analysis of four-day-old seedlings proved to be a fast and efficient technique for evaluating basil seed vigor and has the potential for use in automating the data collection and analysis process.

Towards precision medicine: design considerations for nanozymes in tumor treatment.

Since the discovery of Fe3O4 nanoparticles with enzyme-like activity in 2007, nanozymes have emerged as a promising class of catalysts, offering advantages such as high catalytic efficiency, low cost, mild reaction conditions, and excellent stability. These properties make nanozymes highly suitable for large-scale production. In recent years, the convergence of nanomedicine and nanocatalysis has highlighted the potential of nanozymes in diagnostic and therapeutic applications, particularly in tumor therapy. Despite these advancements, the clinical translation of nanozymes remains hindered by the lack of designs tailored to specific tumor characteristics, limiting their effectiveness in targeted therapy. This review addresses the mechanisms by which nanozymes induce cell death in various tumor types and emphasizes the key design considerations needed to enhance their therapeutic potential. By identifying the challenges and opportunities in the field, this study aims to provide a foundation for future nanozyme development, ultimately contributing to more precise and effective cancer treatments.

Mechanisms of ROS-induced mitochondria-dependent apoptosis in Phaeodactylum tricornutum under AgNPs exposure

IntroductionNanomaterials such as silver nanoparticles (AgNPs) have gained widespread application across various fields. However, the large-scale production and application of AgNPs have raised concerns about their distribution in the environment and potential pollution issues.MethodsThis study investigates the toxic effects of AgNPs on the diatom Phaeodactylum tricornutum by employing electron microscopy for cellular observation, quantifying apoptotic cell numbers, and measuring antioxidant indicators. The research examines how varying concentrations of AgNPs induce stress in P. tricornutum and the specific mechanisms of the toxic effect.ResultsThe findings reveal that AgNPs induce apoptosis in P. tricornutum cells by triggering a mitochondria-mediated pathway, marked by a decrease in mitochondrial membrane potential and the activation of caspase enzymes. Additionally, AgNP exposure results in an overproduction of reactive oxygen species (ROS) within the algal cells, leading to lipid peroxidation of the cell membrane and a consequent increase in malondialdehyde (MDA) levels. This oxidative stress response induces the upregulation of antioxidant enzyme activities in an attempt to mitigate the excessive ROS.DiscussionROS is identified as the primary factor responsible for inducing mitochondria-mediated apoptosis. The research results will provide a theoretical basis for understanding the toxic effects and mechanisms of AgNPs on marine microalgae.

Automated Manufacturing Processes and Platforms for Large-scale Production of Clinical-grade Mesenchymal Stem/ Stromal Cells.

Mesenchymal stem/stromal cells (MSCs) hold immense potential for regenerative medicine due to their remarkable regenerative and immunomodulatory properties. However, their therapeutic application requires large-scale production under stringent regulatory standards and Good Manufacturing Practice (GMP) guidelines, presenting significant challenges. This review comprehensively evaluates automated manufacturing processes and platforms for the scalable production of clinical-grade MSCs. Various large-scale culture vessels, including multilayer flasks and bioreactors, are analyzed for their efficacy in MSCs expansion. Furthermore, automated MSCs production platforms, such as Quantum® Cell Expansion System, CliniMACS Prodigy®, NANT001/ XL, CellQualia™, Cocoon® Platform, and Xuri™ Cell Expansion System W25 are reviewed and compared as well. We also underscore the importance of optimizing culture media specifically emphasizing the shift from fetal bovine serum to humanized or serum-free alternatives to meet GMP standards. Moreover, advances in alternative cryopreservation methods and controlled-rate freezing systems, that offer promising improvements in MSCs preservation, are discussed as well. In conclusion, advancing automated manufacturing processes and platforms is essential for realizing the full potential of MSCs-based regenerative medicine and accomplishing the increasing demand for cell-based therapies. Collaborative initiatives involving industry, academia, and regulatory bodies are emphasized to accelerate the translation of MSCs-based therapies into clinical practice.

Systematic characterization of extracellular vesicles from potato (Solanum tuberosum cv. Laura) roots and peels: biophysical properties and proteomic profiling

IntroductionExtracellular vesicles (EVs) facilitate inter and intra-species/kingdom communication through biomolecule transfer, including proteins and small RNAs. Plant-derived EVs, a hot topic in the field, hold immense capability both as a potential biomarker to study plant physiology and as a biomaterial that can be mass-produced to be used in various industries ranging from cosmetics and food additives to biological pesticides. However, a systematic characterization of plant EVs is required to establish a foundation for further applications and studies.MethodsIn this study, EVs were enriched from hydroponically cultivated potato plants (Solanum tuberosum, cv. Laura). We isolated EVs from root exudates and the apoplastic wash of potato peels using vacuum infiltration. These EVs were then systematically characterized for their biophysical and chemical properties to compare with standard EV characteristics and to explore their roles in plant physiology.ResultsBiophysical and chemical analyses revealed morphological similarities between potato root and peel-derived EVs. The average diameter of root-derived EVs (164.6 ± 7.3 nm) was significantly larger than that of peel-derived EVs (132.2 ± 2.0 nm, p < 0.004). Liquid chromatography–mass spectrometry (LC-MS) demonstrated substantial protein enrichment in purified EVs compared to crude samples, with a 42% enrichment for root EVs and 25% for peel EVs. Only 11.8% of the identified proteins were common between root and peel EVs, with just 2% of significantly enriched proteins shared. Enriched pathways in both EV proteomes were associated with responses to biotic and abiotic stress, suggesting a defensive role of EVs in plants.DiscussionWith further experimentation to elucidate the specific methods of communication, these findings increase the details known about plant EVs in terms of their physical and chemical characteristics and their potential functions, aiding in sustainable agricultural waste utilization for large-scale EV production, aligning with the concept of “valorization”.

A Ni4O4-cubane-squarate coordination framework for molecular recognition.

Molecular recognition is a fundamental function of natural systems that ensures biological activity. This is achieved through the sieving effect, host-guest interactions, or both in biological environments. Recent advancements in multifunctional proteins reveal a new dimension of functional organization that goes beyond single-function molecular recognition, emphasizing the need for artificial multifunctional materials in industrial applications. Herein, we have designed a porous Ni4O4-cubane squarate coordination polymer as an artificial molecular recognition host, drawing inspiration from the structural and functional features of natural enzymes. A comprehensive assessment of the material's ability to distinguish target species under different operating conditions was carried out. The results confirm its sieving function through hexane isomers separation, host-guest interaction function via xenon/krypton separation, and dual presence of sieving and interaction through carbon dioxide/nitrogen separation. Additionally, the material demonstrates good stability and feasibility for large-scale production, indicating its practical potential. Our findings provide a bio-inspired multifunctional recognition material for chemical separations as proof-of-concept while offering solutions to advance artificial multifunctional materials adaptable to other applications beyond chemical separations.

Olfactory response and food preference of Gromphadorhina portentosa (Blattodea: blaberidae) to agro-industrial waste for biomass production

The Madagascar cockroach (Gromphadorhina portentosa) is a species widely used in insect farming, including in animal and human diets. Because of these potential applications, we are looking for effective ways to breed them in captivity, through alternatives that reduce production costs. One solution to this problem would be to use agro-industrial waste to feed these insects. Therefore, this study aimed to evaluate the olfactory behavior of the Madagascar cockroach when exposed to different agro-industrial residues. The experiments were conducted at the Entomoculture Laboratory of the Federal Rural University of Pernambuco (UFRPE) using agro-industrial waste from sugarcane bagasse (Saccharum spp.), forage palm (Opuntia ficus), moringa (Moringa oleifera L.), and wheat bran (Triticum vulgare). The waste was distributed randomly in the evaluation arena. There were 20 repetitions of both sexes with an evaluation period of 20 min each. The bioassays were carried out in sequence: response time of the cockroaches, first olfactory choice, and food preference. Males and females had the highest average consumption in the 20-min evaluation period, and the first olfactory choice was for moringa; however, food preference was concentrated on wheat bran, where females had an average consumption of 1.3g of wheat bran and males 0.85g. Therefore, using wheat bran could make large-scale production of Madagascar cockroaches feasible and potentially make it possible to reuse and sustainably use this waste.

Using Biotechnology to Make Biofuels from Algae as Renewable Energy

According to research published in the Journal of Applied Phycology, algae have the ability to produce biofuels with five times higher energy efficiency compared to soybean plants, making it a highly efficient and sustainable option for renewable fuels. The goal of this research is to use biotechnology to create biofuels from algae as a renewable energy. This study used a laboratory experimental design with a quantitative approach. Population: Microalgae or green algae that have high potential in lipid production, such as Chlorella vulgaris or Spirulina platensis, which are commonly used in biofuel research. Sample: Several species of algae were selected to test their effectiveness as biofuels, including genetically engineered species and natural species as a comparison. The results of the ANOVA analysis showed significant differences in lipid levels between treatment groups. The results of the T/Post-hoc test confirmed that the genetically engineered species had higher lipid levels, supporting the efficiency of biofuels. The regression results showed a strong positive correlation (R² = 0.68), which supports other studies that found that microalgae can produce biomass in a relatively short time with a controlled environment, making it efficient for large-scale biofuel production. The conversion efficiency of lipids to biofuels reached 85.5%, indicating that the transesterification method used in this study is very effective in converting algae lipids to biodiesel. The use of biotechnology in the production of biofuels from algae has great potential as an efficient and sustainable renewable energy source.

Retina-Inspired X-Ray Optoelectronic Synapse Using Amorphous Ga2O3 Thin Film.

Machine vision techniques are widely applied for object identification in daily life and industrial production, where images are captured and processed by sensors, memories, and processing units sequentially. Neuromorphic optoelectronic synapses, as a preferable option to promote the efficiency of image recognition, are hotly pursued in non-ionizing radiation range, but rarely in ionizing radiation including X-rays. Here, the study proposes an X-ray optoelectronic synapse using amorphous Ga2O3 (a-Ga2O3) thin film. Boosted by the interfacial VO 2+ defects and its slow neutralization rate, the enhanced electron tunneling process at metal/a-Ga2O3 interface produces remarkable X-ray-induced post-synaptic current, contributing to a sensitivity of 20.5, 64.3, 164.1 µC mGy-1 cm-2 for the 1st, 5th, and 10th excitation periods, respectively. Further, a 64×64 imaging sensor is constructed on a commercial amorphous Si (a-Si) thin film transistor (TFT) array. The image contrast can be apparently improved under a series of X-ray pulses due to an outstanding long-term plasticity of the single pixel, which is beneficial to the subsequent image recognition and classification based on artificial neural network. The merits of large-scale production ability and good compatibility with modern microelectronic techniques belonging to amorphous oxide semiconductors may promote the development of neuro-inspired X-ray imagers and corresponding machine vision systems.

Pomegranate plant tissue culture technique - a review

‌Background: The pomegranate, or Punica granatum L., is a member of the "Punicaceae" family, which also includes Punica protopunica and Punica granatum. Originating in Afghanistan and Iran, it has spread over Asia, Africa, and Europe's Mediterranean region. The traditional method of pomegranate propagation is laborious and time-consuming. It does not guarantee healthy, disease-free plants. Its shortcomings include poor success rates, extremely sluggish replication, and a one-year establishing period for new plants. Tissue culture is a technique that can be used to grow plants in all seasons without restrictions. Several pomegranate-growing nations have tried in vitro propagation to generate virus-free, similar-type plants, and it has been widely used for propagating many fruit trees. Research Purpose: The goal of this essay was to examine how to do plant tissue culture method and get familiar with the techniques. with an emphasis on the pomegranate micropropagation. The only aspect of plant tissue culture that may be able to get around these issues is in vitro technology. Therefore, there is plenty of room for employing micropropagation to multiply desired genotypes on a wide scale. Research Method: This review article was conducted based on scientific websites in Persian and English languages, including SID, Magiran, Google Scholar, Web of Science, and Library Studies, Results: Pomegranate plants multiply quickly through micropropagation, producing plants (clones) that are genetically similar. In a short amount of time, a single explant can yield thousands of plants. These plants match exactly. The study provides a standardized protocol for in vitro regeneration of nodal explants, which could be useful in large-scale production of uniform and disease-free plantlets. The process of plant tissue culture reduces the need for importing expensive plant seeds.

Yeast metabolism adaptation for efficient terpenoids synthesis via isopentenol utilization.

Microbial biosynthesis has become the leading commercial approach for large-scale production of terpenoids, a valuable class of natural products. Enhancing terpenoid production, however, requires complex modifications on the host organism. Recently, a two-step isopentenol utilization (IU) pathway relying solely on ATP as the cofactor has been proposed as an alternative to the mevalonate (MVA) pathway, streamlining the synthesis of the common terpenoid precursors. Herein, we find that isopentenol inhibits energy metabolism, leading to reduced efficiency of the IU pathway in Saccharomyces cerevisiae. To overcome this, we engineer an IU pathway-dependent (IUPD) strain, designed for growth-coupled production. The IUPD strain is compelled to enhance the ATP supply, essential for the IU pathway, and incorporates a high-throughput screening method for enzyme evolution. The refined IU pathway surpasses the MVA pathway in synthesizing complex terpenoids. Our work offers valuable insights into developing growth-coupled strains adapted to efficient natural product synthesis.