Sustained Delivery Research Articles

Peroxynitrite-Free Nitric Oxide-Embedded Nanoparticles Maintain Nitric Oxide Homeostasis for Effective Revascularization of Myocardial Infarcts.

Revascularization is crucial for treating myocardial infarction (MI). Nitric oxide (NO), at an appropriate concentration, is recognized as an ideal and potent pro-angiogenic factor. However, the application of NO in the treatment of MI is limited. Improper NO supplementation is harmful to revascularization because NO is converted into harmful peroxynitrite (ONOO-) in MI tissues with high reactive oxygen species (ROS) levels. We overcome these obstacles by embedding biliverdin and NO into Prussian blue (PB) nanolattices to obtain an ONOO--free NO-embedded nanomedicine (OFEN). Unlike previous NO donors, OFEN provides NO stably and spontaneously for a longer time (>7 days), which makes it possible to maintain a stable concentration of NO, suitable for angiogenesis, through dose optimization. More importantly, based on the synergy between PB and biliverdin, OFEN converts ROS into beneficial O2 and inhibits the production of ONOO- from the source. OFEN specifically targets MI tissues and achieves sustained and stable NO delivery at the MI site. OFEN effectively promotes revascularization in the MI tissue, significantly reduces myocardial death and fibrosis, and ultimately promotes the complete recovery of cardiac function. Our strategy provides a promising approach for the treatment of myocardial and other ischemic diseases.

Prioritizing Oral Health: Oral Health IS Health!

How did we let the mouth get separated from the rest of the body? And more importantly, how do we put oral health back into overall health? This issue of the NCMJ highlights recent efforts to develop strategies to create an accessible, sustainable, and equitable care delivery system in North Carolina.

Development and characterization of solriamfetol-loaded PVA/PLGA electrospun nanofiber membranes: A promising approach for sustained narcolepsy treatment

Narcolepsy presents challenges in medication adherence and delivery, with traditional oral medications not always suitable for patients experiencing unexpected sleep episodes or difficulty in swallowing pills. This study focused on developing a solriamfetol (SF) loaded nanofiber membrane using a polymer blend of polyvinyl alcohol (PVA) and polylactic-co-glycolic acid (PLGA) for the management of narcoleptic patients with non-oral dosage options. The design required synthesis, optimization, characterization, and evaluation of these nanofibers for transdermal drug delivery. Using a Box-Behnken design, the nanofibers were produced via the electrospinning technique, achieving a high drug content of 96.31 ± 1.21 % and entrapment efficiency of 96.18 ± 1.42 %. The in vitro drug release studies demonstrated a prolonged release profile of SF over 24 h, with 97 % ± 2 % of the drug released. The SEM analysis revealed that the surface morphology of the nanofibers was smooth and homogenous, and the average diameter of the SF/PVA/PLGA nanofibers was found to be 150.23 ± 2.50 nm. X-ray diffraction results confirmed the amorphous structure of the nanofibers. The zebrafish embryonic toxicological study did not reveal any signs of toxicity or morphological abnormalities in the developing embryos, indicating that the nanofibers are safe. The results point to the applicability of SF nanofiber membranes in personalized narcolepsy therapy, which improves patients’ quality of life and the efficacy of their treatment. These nanofibers can be given in the form of a transdermal patch to patients for sustained drug delivery, even when they fall asleep or when they cannot take medicines orally.

Multi objective constellation optimization and dynamic link utilization for sustainable information delivery using PD-NOMA deep reinforcement learning

Multi objective constellation optimization and dynamic link utilization for sustainable information delivery using PD-NOMA deep reinforcement learning

Electrospun gelatin/hyaluronic acid nanofibers as a platform for uric acid delivery to neural tissue.

Uric acid (UA) is an antioxidant that has been reported to be a neuroprotective compound for injuries and diseases, and specifically, diseases of the central nervous system. However, uric acid is highly insoluble in aqueous solutions, and high levels in the serum lead to gout, which limits its use in humans. Here, we develop a novel drug delivery platform that will release uric acid in a sustained manner for application to neural tissue. We demonstrate that one-step incorporation of UA into an electrospun gelatin/hyaluronic acid nanofiber mat results in controlled release of UA in culture medium. Taking a unique approach, we made solutions of 12% gelatin and 1% hyaluronic acid in a formic acid solvent and added UA for production of nanofiber mats. We then dehydrothermally crosslinked the mats and tested for release of UA into physiological cell culture medium. To test whether the mats have any detrimental effects on healthy nervous system tissue, we cultured spinal cord explants on the mats extended and assessed extensions from the explants. We observed that comparable numbers and lengths of dendrites are extended from the spinal cord tissue, regardless of the amount UA content in the mats. Our results suggest that electrospun gelatin/hyaluronic acid nanofibers can be used as a platform for sustained uric acid delivery to neural tissue without detrimental effects.

Drone-Assisted Last-Mile Delivery Under Windy Conditions: Zero Pollution Solutions

As cities expand and the global push for zero pollution intensifies, sustainable last-mile delivery (LMD) systems are essential to minimizing environmental and health impacts. This study addresses the need for more sustainable LMD by examining the integration of wind conditions into drone-assisted deliveries, focusing on their effects on air and noise pollution in urban areas. We extend the flying sidekick traveling salesman problem (FSTSP) by incorporating meteorological factors, specifically wind, to assess drone delivery efficiency in varying conditions. Our results show that while drones significantly reduce greenhouse gas emissions compared to traditional delivery vehicles, their contribution to noise pollution remains a concern. This research highlights the environmental advantages of using drones, particularly in reducing CO2 emissions, while also emphasizing the need for further investigation into mitigating their noise impact. By evaluating the trade-offs between air and noise pollution, this study provides insights into developing more sustainable, health-conscious delivery models that contribute to smart city initiatives. The findings inform policy, urban planning, and logistics strategies aimed at achieving zero pollution goals and improving urban livability.

Pioneering sustainable treatment delivery in childhood leukemia through synchronous telemedicine-A pilot study.

Cancer care places a heavy economic burden on families and health systems, driven by high treatment costs, lengthy hospital stays, and the necessity for extensive travel to specialized facilities. To address this challenge, an integrated health care network (IHCN) was implemented for maintenance treatment in acute leukemia. The IHCN encompassed outpatient services provided by local physicians and synchronous telemedicine consultation with pediatric oncologists. This study included twenty-two pediatric patients (eleven [50.0%] females; twenty [90.9%] with B-ALL and two [9.1%] with AML). The IHCN was offered to all rural patients (n = 17) with a one-way driving distance more than 30 km, while urban patients (n = 5) received regular cancer care. Throughout the study, rural patients had a total of 510 routine clinical visits, with 367 (72%) conducted through the IHCN. Physical examinations revealed similar frequency of new abnormal findings for urban and rural patients (22.4% vs. 17.8%; p = .31). Laboratory tests indicated no significant difference in the frequency of abnormal values for various parameters between both groups. Similarly, there was no discrepancy of drug modifications or interruption in maintenance therapy between the two settings (p = .85). Moreover, patients' health-related quality of life remained within the normative range, and user satisfaction with the IHCN was notably high. The implementation of the IHCN resulted in savings of 70,158 km, 950 h of travel, and 12,277 kg CO2 emissions. This pilot study underscores the efficacy of a telemedicine-based IHCN, ensuring safety, quality of care, cost reduction, and satisfaction for both families and health care providers in pediatric leukemia management.

Sense of Community in the context of disease prevention and health promotion: A scoping review of the literature

BackgroundThe centrality of community engagement in disease prevention and health promotion interventions highlights the need to understand the contextual factors that shape participation. Sense of Community (SoC), characterized by feelings of belonging, connection, and interdependence among members of a community, has emerged as a key component of community capacity and is therefore expected to influence engagement outcomes. However, empirical evidence is needed to assess its actual impact on community engagement. Additionally, the literature lacks a broader synthesis of the role and implications of SoC in this context. This study aims to review the empirical literature on SoC in disease prevention and health promotion, with a special focus on its association with community engagement.MethodsA scoping review was conducted following the PRISMA guidelines, searching for empirical studies published between 1974 and 2023 via Scopus, Web of Science, and PubMed.ResultsNineteen studies were included in the review, revealing three key themes: (1) the community to which SoC refers – among intervention participants, within community coalitions, and defined by the place of residence; (2) the interpretation of SoC, either as a generic, intuitive concept or as a theoretically defined construct; (3) the ways in which SoC is studied – as a predictor of engagement but also as an outcome of the interventions. Generic SoC among intervention participants emerged as a positive outcome and a factor contributing to engagement. However, as the scope expanded to encompass broader communities and SoC became more theoretically grounded, these dynamics shifted. SoC related to the place of residence did not exhibit significant improvement after interventions. Broader community-level SoC showed positive associations with engagement among members of community coalitions, but evidence was less consistent among the individuals targeted by interventions.ConclusionsThe review highlighted a scarcity of empirical research on SoC despite its recognition as a key component of community capacity. Contextualizing SoC is crucial, as its interpretation significantly influences its role in disease prevention and health promotion interventions. Further research is needed to clarify whether SoC can foster engagement at all community levels, especially among the general population. This is particularly relevant amid the current context of escalating health needs and strained traditional resources, where community engagement is increasingly essential to ensuring the sustainable delivery of disease prevention and health promotion efforts. If SoC can drive widespread engagement, it could play a pivotal role in building more proactive and autonomous health-promoting communities.

Development and characterization of PVA-zein/α-tocopherol nonwoven mats for functional wound dressing applications

Wound healing poses significant clinical challenges due to issues like bacterial infections, oxidative stress, and the need for sustained therapeutic delivery. This study aimed to develop and characterize biocompatible nonwoven fibrous mats composed of poly(vinyl alcohol) (PVA) and zein encapsulating α-tocopherol for wound dressing applications. α-Tocopherol was nano-encapsulated in zein proteins using an antisolvent co-precipitation method, followed by its dispersion in PVA solutions. The resulting composition was then processed using a novel, scalable, and inexpensive solution blow spinning (SBS) process that offers higher throughputs to generate non-woven mats. The resulting fibers in the non-woven mats, ranging in diameter from 350 nm to 796 nm, demonstrate uniform morphology, as confirmed by scanning electron microscopy. Fourier transform infrared (FTIR) spectroscopy validated the successful incorporation of α-tocopherol without altering the chemical structure of the PVA-zein matrix. Rheological assessments revealed Newtonian behavior and a decrease in viscosity with higher tocopherol content, enhancing the processability of the mats. Mechanical testing showed that increasing tocopherol content improved tensile strength, elongation, and Young's modulus. The mats exhibited a biphasic release profile with an initial burst and sustained α-tocopherol release over 24 h, fitting the Korsmeyer-Peppas model and hence indicating a diffusion-controlled mechanism. Cytotoxicity assays confirmed high cell viability (>90 %) and enhanced cell spreading, underscoring their biocompatibility. These findings suggest that PVA-zein/tocopherol fiber mats are promising candidates for functional wound dressing materials, offering sustained antioxidant activity and a favorable wound healing environment. Future work will focus on optimizing fiber composition for antimicrobial properties and conducting in vivo studies to validate their clinical efficacy.

Formulation and Assessment of Tolnaftate Microsponges for Topical Medication Deliverance

Objective: This study aimed to develop and evaluate the sustained delivery of Tolnaftate using topical polymeric microsponges. Materials and Methods: Tolnaftate-loaded microsponges made of ethyl cellulose were prepared via quasi-emulsion solvent diffusion. The effects of the drug-to-polymer ratio on active drug content, particle size, and entrapment efficiency were examined. The optimized formulation was incorporated into a Carbopol gel and evaluated for drug content, pH, viscosity, and in vitro drug release. The study considered internal phase volume, stirring rate, and emulsifier concentration as variables and analyzed their impact on entrapment efficiency and particle size. Results: Increasing stirring speed reduced particle size and improved entrapment efficiency, while a higher volume of dichloromethane decreased particle size. Scanning electron microscopy revealed porous and spherical microsponges. The 1.5:1 drug-to-polymer ratio yielded the highest active drug content, optimal entrapment efficiency, and smallest particle size, making it the preferred ratio for further studies. Conclusions: The drug release from the microsponge gel was more sustained compared to both the marketed product and pure drug gel. An ex vivo drug deposition study using rat abdominal skin showed satisfactory drug deposition. These polymeric microsponges show potential as a topical drug delivery system for antifungal therapy.

Hydrogel for Sustained Delivery of Therapeutic Agents

In recent years, hydrogels have emerged as a highly promising platform for the sustained delivery of therapeutic agents, addressing critical challenges in drug delivery systems, from controlled release to biocompatibility [...]

Routine HPV vaccination: Reflection on delivery strategies based on countries’ experiences

Despite the introduction of the human papillomavirus (HPV) vaccine in many low- and middle-income countries (LMICs), countries are still struggling to maintain HPV vaccination coverage and manage sustainable delivery strategies. This article explores the challenges and effective strategies for HPV vaccine delivery in LMICs, with a focus on reflecting upon current HPV vaccine delivery strategies in the World Health Organization (WHO) HPV vaccine introduction guidelines to align with practical implementation experiences. The article utilizes presentations and discussions from Coalition to Strengthen the HPV Immunization Community (CHIC) symposia, field experiences of program implementers who participated in the meeting and immunization expert opinions, to inform its findings. Several countries are spotlighted for their delivery strategies. These include routinized campaign mode vaccinations at schools in The Gambia, Zambia, and Ethiopia; routine health facility services in Tanzania, Kenya, and Maldives; and outreach strategies targeting out-of-school girls. By evaluating these diverse strategies, the article suggests a need to delve deeper and build an understanding of the routinized campaign mode of HPV vaccine delivery, and advocates for expanding the scope of delivery strategies and consequently updating the WHO HPV vaccine delivery guidelines in line with the evolving landscape of HPV vaccination delivery to ensure comprehensive, cost-effective, and sustainable programs in LMICs.

How food delivery service can be sustainable: some evidence from the Giusta delivery case

PurposeThe study explores the drivers of the intention to continue using sustainable food delivery services, considering the influence of value, satisfaction and the combined effects of utilitarian and hedonic motives. We employ a comprehensive framework that integrates the norm activation model (NAM) and the theory of planned behavior (TPB), with satisfaction, utilitarian motives and hedonic motives. This approach facilitates a deeper understanding of the factors motivating users to remain loyal to the service.Design/methodology/approachThe study examines the data using a quantitative approach based on the partial least squares approach to structural equation modeling (PLS-SEM).FindingsThe findings suggest that the intention to continue using sustainable food delivery services, such as the Giusta app, is significantly influenced by user satisfaction and attitudes. Attitudes not only influence the intention but also user satisfaction and are shaped by utilitarian motivations associated with sustainable food delivery. Beyond personal expectations and perceived benefits, the study reveals that behavior is also driven by altruistic values and moral convictions. Specifically, attitudes and satisfaction are positively affected by personal norms, which are influenced by ascribed responsibility. This ascribed responsibility is, in turn, shaped by awareness of both environmental and social issues.Originality/valueThis research contributes to the current debate on consumers' ethical behavior in food delivery. Only a few studies have integrated the NAM and TPB models in this context. This article highlights the factors useful in predicting people’s choice of food delivery services, showing the key role of personal norms, attitude, satisfaction and utilitarian motives.

Ionically crosslinked Sodium alginate – Galactoxyloglucan hydrogel beads as a controlled release system for sustainable urea delivery

The prolonged usage of chemical fertilizers often causes deleterious effects on the environment, and it remains an alarming issue in agricultural practices. Smart delivery of fertilizers achieved by hydrogels proved their efficiency in reducing risk in action. In this study, we investigated the optimization of urea-encapsulated hydrogel formulations and evaluated their physical and chemical attributes for agricultural applications. The proposed hydrogel formulation consists of ionically crosslinked two promising plant biopolymers (galactoxyloglucan and sodium alginate) which are specifically developed for the controlled release of urea fertilizer. The FT-IR analysis of the hydrogel beads confirmed the presence of biopolymer functional groups and urea. XRD analysis indicated the amorphous nature of the biopolymers. TGA revealed a thermal stability of up to 350°C. SEM images showed the porous structure of the hydrogel beads. To investigate the controlled release of urea, two kinetic models were employed: Korsmeyer-Peppas and Peppas-Sahlin. The results indicated a controlled release mechanism. The hydrogel beads demonstrated excellent water retention properties, maintaining soil moisture for up to 16 days. Additionally, degradability results demonstrated that in the soil environment, the hydrogel beads were degraded completely in 21 days. Therefore, we are confident that the formulated hydrogel bead exhibits eco-friendly and bio-compatible characteristics, which potentially mitigate the risks associated with urea fertilizers.

Utilizing metal-organic framework porosity for efficient antibiotic separation and sustained release

Metal-organic frameworks (MOFs) have emerged as a revolutionary class of nanoporous materials due to their highly tunable porosity and functionality. With the vast number of MOFs being discovered, traditional experimental techniques to identify the best candidates for various applications, including water treatment and drug delivery become time-consuming and expensive. This is where computational screening offers a powerful solution. We present a computational screening strategy using Monte Carlo (MC) simulation to identify the promising MOFs among over 14,000 MOFs for efficient absorption, membrane separation, and sustained delivery of antibiotics (e.g., azithromycin, AZ). The MC simulation was used to calculate the loading capacity and isosteric heat of the AZ absorption. These absorption properties were correlated with several structural characteristics of the MOF, including the largest cavity diameter, pore limiting diameter, accessible volume, helium void fraction, etc. Critical evaluation of the correlation results identified the best MOFs for AZ absorption, separation, and delivery. The results recommended a total of 578 MOFs, with 126 identified as suitable for use as AZ adsorbents or drug carriers, and 452 for use as membranes to separate AZ from water. Furthermore, the adsorption mechanism of the top MOF was analyzed using molecular dynamics simulation and non-covalent interactions. The solvation-free energy of AZ was evaluated in various solvents to identify the most effective solvent for extracting AZ from MOFs, thereby facilitating the regeneration of the MOF.

Synthesis and mechanism of Mg/Al layered double oxides-silica nanocomposites for sustainable multi-nutrient delivery in agricultural applications

Potassium (K), urea (N), phosphate (P), and selenite (Se) are widely used in modern agriculture for improvement of crop yield and quality. However, traditional fertilizer suffers from poor fertilizer utilization efficiency and noncontrollable slow-release behavior. To improve nutrient utilization, we developed a layered double oxides-silica (LDO@Si) based on calcined Mg/Al layered double hydroxide-silica nanocomposites (LDH@Si), for slow release of K, N, P, and Se to crops. In this study, SEM, XRD, FT-IR, XPS, BET, and TGA were employed to analyze the structure, morphology, and microstructures of the samples. Results show that LDH@Si successfully transforms into LDO@Si after calcination, where LDO is mainly connected to silica via M-O-Si bonds. Furthermore, after K, P, and Se loading, the LDH@Si structure was successfully restored, indicating that phosphate and selenite ions have been effectively embedded in the inner layer of LDH. K ions are firmly fixed to the material surface via M-O-K bonds. After urea introducing, the pore structure of the material was completely filled, and excess urea formed a urea layer on the surface of the material. LDO@Si can continuously release nutrients into water through diffusion and LDO@Si dissolution for up to 240 h. Compared with chemical fertilizers, LDO@Si based slow-release fertilizer (CRSF2) significantly improves plant fresh weight, dry weight and chlorophyll content, increasing them by 13.91 %–23.13 %, 18.20 %–34.40 % and 2.24 %–14.81 %, respectively. Furthermore, a modest increase in the levels of nutrients N, P, and K is observed, while the Se concentration in plants treated with CRSF2 demonstrates significant enhancements of 9.57 %, 72.49 %, and 50.97 % compared to control treatments. These results illustrate the potential agricultural application of LDO@Si as a slow-release fertilizer for improving crop yields while minimizing the required amount of fertilizer.

Design of Nanocrystalline Suspension of Dutasteride for Intramuscular Prolonged Delivery

The aim of the study is to formulate an injectable nanocrystalline suspension (NS) of dutasteride (DTS), a hydrophobic 5α-reductase inhibitor used to treat benign prostatic hyperplasia and scalp hair loss, for parenteral long-acting delivery. A DTS-loaded NS (DTS-NS, 40 mg/mL DTS) was prepared using a lab-scale bead-milling technique. The optimized DTS-NS prepared using Tween 80 (0.5% w/v) as a nano-suspending agent, was characterized as follows: rod/rectangular shape; particle size of 324 nm; zeta potential of −11 mV; and decreased drug crystallinity compared with intact drug powder. The DTS-NS exhibited a markedly protracted drug concentration-time profile following intramuscular injection, reaching a maximum concentration after 8.40 days, with an elimination half-life of 9.94 days in rats. Histopathological observations revealed a granulomatous inflammatory response at the injection site 7 days after intramuscular administration, which significantly subsided by day 14 and showed minimal inflammation by day 28. These findings suggest that the nanosuspension system is a promising approach for the sustained release parenteral DTS delivery, with a protracted pharmacokinetic profile and tolerable local inflammation.

Predicting dropout and non-response to psychotherapy for personality disorders: A study protocol focusing on therapist, patient, and the therapeutic relationship

BackgroundThe abandonment of psychotherapeutic treatments is influenced by various factors, including patient characteristics, therapist traits, and the therapeutic relationship. Despite the well-documented importance of these factors, limited empirical research has focused on the role of the therapeutic relationship and the characteristics of therapist-patient dyads in predicting treatment dropout. This study protocol outlines a longitudinal research project aimed at predicting dropout and non-response in psychotherapy for individuals with personality disorders. The research seeks to identify predictive factors related to psychotherapy outcomes, focusing on patient, therapist, and dyadic elements. Specifically, the study will examine the influence of therapist characteristics (e.g., personality traits, countertransference, responsiveness) on treatment outcomes, explore the impact of relational factors (e.g., treatment expectations, epistemic trust, therapeutic alliance) on therapy effectiveness, and assess how the therapeutic alliance within therapist-patient dyads affects the likelihood of dropout and non-response.MethodsThe longitudinal study will include 100 therapist-patient dyads (200 participants) recruited from various Mental Health Services in Milan, Italy. Validated instruments will be administered to both patients and therapists at four-time points: T0 (baseline), T1 (3 months), T2 (6 months), and T3 (1 year). Data will be collected at baseline and at the one-year mark to evaluate the relationships between therapist, patient, and dyadic factors and treatment outcomes.DiscussionIdentifying predictive variables associated with high dropout rates can help preempt treatment discontinuation, reducing the financial and operational burdens on mental health services. Understanding these factors will enable the development of targeted interventions to improve treatment engagement and reduce attrition. This approach could enhance outcomes for individuals with personality disorders and lead to more efficient resource allocation and sustainable delivery of mental health care.

Amphotericin B Ocular Films for Fungal Keratitis and a Novel 3D-Printed Microfluidic Ocular Lens Infection Model

Fungal keratitis (FK), a severe eye infection that leads to vision impairment and blindness, poses a high risk to contact lens users, and Candida albicans remains the most common underpinning fungal pathogen in temperate climates. Patients are initially treated empirically (econazole 1% drops hourly for 24–48 h), and if there is no response, amphotericin B (AmB) 0.15% eye drops (extemporaneously manufactured to be stable for a week) are the gold-standard treatment. Here, we aim to develop a sustained-release AmB ocular film to treat FK with an enhanced corneal retention time. As there is a paucity of reliable in vitro models to evaluate ocular drug release and antifungal efficacy under flow, we developed a 3D-printed microfluidic device based on four chambers stacked in parallel, in which lenses previously inoculated with a C. albicans suspension were placed. Under the flow of a physiological fluid over 24 h, the release from the AmB-loaded film that was placed dry onto the surface of the wetted contact lenses was quantified, and their antifungal activity was assessed. AmB sodium deoxycholate micelle (dimeric form) was mixed with sodium alginate and hyaluronic acid (3:1 w/w) and cast into films (0.48 or 2.4%), which showed sustained release over 24 h and resulted in a 1.23-fold reduction and a 5.7-fold reduction in CFU/mL of C. albicans, respectively. This study demonstrates that the sustained delivery of dimeric AmB can be used for the treatment of FK and provides a facile in vitro microfluidic model for the development and testing of ophthalmic antimicrobial therapies.

Sustained release of heparin from PLLA micropartricles for tissue engineering applications

Heparin holds promise for cardiac tissue engineering, but challenges such as hematoma or bleeding and accumulation in tissue caused by excessive release, and short half-life persist. The present study aimed to introduce a reliable mechanism for the prolonged heparin release from a biocompatible polymer carrier. The designed system must ensure that heparin retains its bioactivity over time while preventing premature release. Heparin was encapsulated within poly (L-lactic acid) microparticles using the double emulsion method, with polyvinyl alcohol employed as the stabilizer. The encapsulation efficiency of heparin in the microparticles was calculated as 25.56 %. The functionality of the design was evaluated using Attenuated Total Reflection Fourier Transform Infrared Spectroscopy, Scanning Electron Microscopy, and Energy Dispersive X-ray Spectroscopy. Drug release and microparticle degradation studies were conducted alongside cell viability tests. The particle sizes ranged from 5 to 10 ± 2.53 μm, with evidence suggesting that heparin promotes the smaller particle formation. The system demonstrated a consistent drug release profile over six weeks with a release rate of 54 % by week two and 97.65 % by week six. The degradation of heparin-loaded microparticles reached less than 50 % by week six, and the loading of heparin did not significantly affect the degradation behavior of the PLLA microparticles in PBS. Furthermore, heparin concentrations between 200 and 400 μg/ml enhanced the viability of Placenta-derived Mesenchymal Stem Cells and H9c2. These findings suggest that the system could be considered as an effective vehicle for sustained heparin delivery across a spectrum of biological applications, particularly in cardiac tissue engineering.