An oral drug delivery system using proteinoid microspheres is discussed with respect to itsunique dependence on pH. It has been found that certain drugs such as insulin and heparin canbe encapsulated in proteinoid sph...An oral drug delivery system using proteinoid microspheres is discussed with respect to itsunique dependence on pH. It has been found that certain drugs such as insulin and heparin canbe encapsulated in proteinoid spheres at stomach pH's (1--3). These spheres also dissemble atintestinal pH's (6--7) releasing the drug for absorption. Using this technique low molecularweight heparin and human growth hormone have been orally delivered successfully to severalanimal species. Future work has been proposed to study the interaction and binding of thespecific drugs with synthesized oligopeptides.展开更多
The objective of this study is to utilize the pH sensitivity of modified silica nanoparticles (SNIL) by imidazole-based ionic liquid for oral delivery of insulin. In the first time, the imidazole was covalently attach...The objective of this study is to utilize the pH sensitivity of modified silica nanoparticles (SNIL) by imidazole-based ionic liquid for oral delivery of insulin. In the first time, the imidazole was covalently attached to the 3-trimethoxysily-lpropyl chloride with replacement of all the chlorine atoms. Then, a silica nanoparticle was modified by N-(3-trimeth-oxysilylpropyl) imidazole. The nanocapsule (NCIL) was achieved after the etching of the modified silica nanoparticle template with hydrofluoric acid. The nanoparticles connected through an ionic liquid-like network were characterized by FTIR and SEM. Insulin was entrapped in these carriers and the in vitro release profiles were established separately in both enzyme-free simulated gastric and intestinal fluids (SGF, pH 1) and (SIF, pH 7.4), respectively. When these drug-loaded nanoparticles was placed in physiological buffer solution (pH 7.4), a partial negative surface charge on the modified silica nanoparticle was generated due to the deprotonation of silanol groups, and the strong electrostatic repulsion triggered a sustained release of the loaded molecules.展开更多
Effective oral drugs and vaccines require high delivery efficiency across the gastrointestinal epithelia and protection of medically effective payloads(i.e.,immunogens)against gastric damage.In this study,hollowed nan...Effective oral drugs and vaccines require high delivery efficiency across the gastrointestinal epithelia and protection of medically effective payloads(i.e.,immunogens)against gastric damage.In this study,hollowed nanocarriers(NCs:silica nanospheres and gold nanocages)with poly-l-lysine(PLL)coating and mammalian orthoreovirus cell attachment proteinσ1 functionalization(NC-PLL-σ1)were explored as functional oral drug delivery vehicles(ODDVs).The transport of these ODDVs to mucosal lymphoid tissues could be facilitated by microfold cells(M-cells)mediated transcytosis(viaσ1-α2–3-linked sialic acids adherence)across gastrointestinal epithelia.PLL coating provided protection and slow-release of rhodamine 6 G(R6G),a model payload.The transport effectiveness of these ODDVs was tested on intestinal organoid monolayers in vitro.When compared with other experimental groups,the fully functionalized ODDV system(with PLL-σ1)demonstrated two significant advantages:a significantly higher transport efficiency(198%over blank control at 48 h);and protection of payloads which led to both better transport efficiency and extended-release of payloads(61%over uncoated carriers at 48 h).In addition,it was shown that the M cell presence in intestinal organoid monolayers(modulated by Rank L stimulation)was a determining factor on the transport efficiency of the ODDVs:more M-cells(induced by higher Rank L)in the organoid monolayers led to higher transport efficiency for ODDV-delivered model payload(R6G).The fully functionalized ODDVs showed great potential as effective oral delivery vehicles for drugs and vaccines.展开更多
Due to its safety,convenience,low cost and good compliance,oral administration attracts lots of attention.However,the efficacy of many oral drugs is limited to their unsatisfactory bioavailability in the gastrointesti...Due to its safety,convenience,low cost and good compliance,oral administration attracts lots of attention.However,the efficacy of many oral drugs is limited to their unsatisfactory bioavailability in the gastrointestinal tract.One of the critical and most overlooked factors is the symbiotic gut microbiota that can modulate the bioavailability of oral drugs by participating in the biotransformation of oral drugs,influencing the drug transport process and altering some gastrointestinal properties.In this review,we summarized the existing research investigating the possible relationship between the gut microbiota and the bioavailability of oral drugs,which may provide great ideas and useful instructions for the design of novel drug delivery systems or the achievement of personalized medicine.展开更多
As endogenous courier vesicles,exosomes play crucial roles in macromolecule transmission and intercellular communication.Therefore,exosomes have drawn increasing attention as biomimetic drug-delivery vehicles over the...As endogenous courier vesicles,exosomes play crucial roles in macromolecule transmission and intercellular communication.Therefore,exosomes have drawn increasing attention as biomimetic drug-delivery vehicles over the past few years.However,few studies have investigated the encapsulation of peptide/protein drugs into exosomes for oral administration.Additionally,the mechanisms underlying their biomimetic properties as oral delivery vehicles remain unknown.Herein,insulin-loaded milk-derived exosomes(EXO@INS)were fabricated and the in vivo hypoglycemic effect was investigated on type I diabetic rats.Surprisingly,EXO@INS(50 and 30 IU/kg)elicited a more superior and more sustained hypoglycemic effect compared with that obtained with subcutaneously injected insulin.Further mechanism studies indicated that the origin of excellent oral-performance of milk-derived exosomes combined active multi-targeting uptake,pH adaptation during gastrointestinal transit,nutrient assimilation related ERK1/2 and p38 MAPK signal pathway activation and intestinal mucus penetration.This study provides the first demonstration that multifunctional milk-derived exosomes offer solutions to many of the challenges arising from oral drug delivery and thus provide new insights into developing naturally-equipped nanovehicles for oral drug administration.展开更多
Oral drugs such as ibrutinib play an important role in the treatment of mature B-cell lymphoma(BCL)due to their reliable efficacy,manageable safety,high accessibility,and convenience for use.Still,no guidelines or con...Oral drugs such as ibrutinib play an important role in the treatment of mature B-cell lymphoma(BCL)due to their reliable efficacy,manageable safety,high accessibility,and convenience for use.Still,no guidelines or consensus focusing on oral drug therapies for BCL is available.To provide a reference of oral agent-based treatment for mature BCL,a panel of experts from the Lymphocyte Disease Group,Chinese Society of Hematology,Chinese Medical Association conducted an extensive discussion and reached a consensus on oral drugs for Chinese BCL patients on the basis of the current application status of oral drugs in China,combined with the latest authoritative guidelines in the world and current research reports.This consensus reviewed the application of oral drugs in the treatment of BCL and the latest research and provided appropriate recommendations on the use of oral drugs for indolent or aggressive BCL patients.With the deepening of research and the development of standardized clinical applications,oral medications will bring better treatment to BCL patients,enabling more patients to benefit from them.展开更多
Oral drugs have been widely used in clinical therapy, but their developments were severely limited by the side effects of drug exposure as well as the multiple biological barriers. In this study, we constructed a “cl...Oral drugs have been widely used in clinical therapy, but their developments were severely limited by the side effects of drug exposure as well as the multiple biological barriers. In this study, we constructed a “cluster bomb” oral drug delivery system (DOX@PFeL@L100) with core-shell structure to overcome the complex absorption barriers. The inner core termed as “bomb” that contains a lot of ultra-small diameter Fe_(3)O_(4) nanoparticles (DOX@PFeL NPs) loaded with doxorubicin (DOX) and modified with l-valine, which can efficiently penetrate the epithelial cells via PePT1 receptor mediated endocytosis. The outer shell of this “cluster bomb” is a layer of pH-sensitive polymer (Eudragit®L100) that can be served as a pH-responsive switch and effectively control the “bomb” release in the intestinal microenvironment to improve the antitumor efficiency by the Fenton like reaction of DOX and Fe^(2+)/Fe^(3+). This study demonstrates that the “cluster comb” oral drug delivery system can sequentially overcome the multiple biological barriers, providing a safe and effective approach for tumor therapy.展开更多
Liposomes mimic natural cell membranes and have long been investigated as drug carriers due to excellent entrapment capacity, biocompatibility and safety. Despite the success of parenteral liposomes,oral delivery of l...Liposomes mimic natural cell membranes and have long been investigated as drug carriers due to excellent entrapment capacity, biocompatibility and safety. Despite the success of parenteral liposomes,oral delivery of liposomes is impeded by various barriers such as instability in the gastrointestinal tract,difficulties in crossing biomembranes, and mass production problems. By modulating the compositions of the lipid bilayers and adding polymers or ligands, both the stability and permeability of liposomes can be greatly improved for oral drug delivery. This review provides an overview of the challenges and current approaches toward the oral delivery of liposomes.展开更多
文摘An oral drug delivery system using proteinoid microspheres is discussed with respect to itsunique dependence on pH. It has been found that certain drugs such as insulin and heparin canbe encapsulated in proteinoid spheres at stomach pH's (1--3). These spheres also dissemble atintestinal pH's (6--7) releasing the drug for absorption. Using this technique low molecularweight heparin and human growth hormone have been orally delivered successfully to severalanimal species. Future work has been proposed to study the interaction and binding of thespecific drugs with synthesized oligopeptides.
文摘The objective of this study is to utilize the pH sensitivity of modified silica nanoparticles (SNIL) by imidazole-based ionic liquid for oral delivery of insulin. In the first time, the imidazole was covalently attached to the 3-trimethoxysily-lpropyl chloride with replacement of all the chlorine atoms. Then, a silica nanoparticle was modified by N-(3-trimeth-oxysilylpropyl) imidazole. The nanocapsule (NCIL) was achieved after the etching of the modified silica nanoparticle template with hydrofluoric acid. The nanoparticles connected through an ionic liquid-like network were characterized by FTIR and SEM. Insulin was entrapped in these carriers and the in vitro release profiles were established separately in both enzyme-free simulated gastric and intestinal fluids (SGF, pH 1) and (SIF, pH 7.4), respectively. When these drug-loaded nanoparticles was placed in physiological buffer solution (pH 7.4), a partial negative surface charge on the modified silica nanoparticle was generated due to the deprotonation of silanol groups, and the strong electrostatic repulsion triggered a sustained release of the loaded molecules.
基金the National Institute of Biomedical Imaging and Bioengineering(NIBIB)Trailblazer Award(1R21EB032991-01)the Shanti V.Sitaraman,MD,PhD Inflammatory Bowel Diseases Young Investigator Award(No.439516)Dr.Yu would like to thank USDA-NIFA(grant no.2016-07802)and USDA-ARS(award no.019636-00001)for partially funding this research.
文摘Effective oral drugs and vaccines require high delivery efficiency across the gastrointestinal epithelia and protection of medically effective payloads(i.e.,immunogens)against gastric damage.In this study,hollowed nanocarriers(NCs:silica nanospheres and gold nanocages)with poly-l-lysine(PLL)coating and mammalian orthoreovirus cell attachment proteinσ1 functionalization(NC-PLL-σ1)were explored as functional oral drug delivery vehicles(ODDVs).The transport of these ODDVs to mucosal lymphoid tissues could be facilitated by microfold cells(M-cells)mediated transcytosis(viaσ1-α2–3-linked sialic acids adherence)across gastrointestinal epithelia.PLL coating provided protection and slow-release of rhodamine 6 G(R6G),a model payload.The transport effectiveness of these ODDVs was tested on intestinal organoid monolayers in vitro.When compared with other experimental groups,the fully functionalized ODDV system(with PLL-σ1)demonstrated two significant advantages:a significantly higher transport efficiency(198%over blank control at 48 h);and protection of payloads which led to both better transport efficiency and extended-release of payloads(61%over uncoated carriers at 48 h).In addition,it was shown that the M cell presence in intestinal organoid monolayers(modulated by Rank L stimulation)was a determining factor on the transport efficiency of the ODDVs:more M-cells(induced by higher Rank L)in the organoid monolayers led to higher transport efficiency for ODDV-delivered model payload(R6G).The fully functionalized ODDVs showed great potential as effective oral delivery vehicles for drugs and vaccines.
基金supported by Chinese Academy of Medical Sciences(CAMS)Innovation Fund for Medical Sciences(2017-I2M1e011,China)the Drug Innovation Major Project(2018ZX09711001-002-005,China)+1 种基金National Natural Science Foundation of China(No.82073778,China)the Fundamental Research Funds for the Central Public Welfare Research Institutes(2018PT35002,China)
文摘Due to its safety,convenience,low cost and good compliance,oral administration attracts lots of attention.However,the efficacy of many oral drugs is limited to their unsatisfactory bioavailability in the gastrointestinal tract.One of the critical and most overlooked factors is the symbiotic gut microbiota that can modulate the bioavailability of oral drugs by participating in the biotransformation of oral drugs,influencing the drug transport process and altering some gastrointestinal properties.In this review,we summarized the existing research investigating the possible relationship between the gut microbiota and the bioavailability of oral drugs,which may provide great ideas and useful instructions for the design of novel drug delivery systems or the achievement of personalized medicine.
基金We gratefully acknowledge financial support from the National Science Foundation for Distinguished Young Scholars(81625023,China)the National Natural Science Foundation of China(81872818)the Major Research Plan of National Natural Science Foundation of China(81690261).
文摘As endogenous courier vesicles,exosomes play crucial roles in macromolecule transmission and intercellular communication.Therefore,exosomes have drawn increasing attention as biomimetic drug-delivery vehicles over the past few years.However,few studies have investigated the encapsulation of peptide/protein drugs into exosomes for oral administration.Additionally,the mechanisms underlying their biomimetic properties as oral delivery vehicles remain unknown.Herein,insulin-loaded milk-derived exosomes(EXO@INS)were fabricated and the in vivo hypoglycemic effect was investigated on type I diabetic rats.Surprisingly,EXO@INS(50 and 30 IU/kg)elicited a more superior and more sustained hypoglycemic effect compared with that obtained with subcutaneously injected insulin.Further mechanism studies indicated that the origin of excellent oral-performance of milk-derived exosomes combined active multi-targeting uptake,pH adaptation during gastrointestinal transit,nutrient assimilation related ERK1/2 and p38 MAPK signal pathway activation and intestinal mucus penetration.This study provides the first demonstration that multifunctional milk-derived exosomes offer solutions to many of the challenges arising from oral drug delivery and thus provide new insights into developing naturally-equipped nanovehicles for oral drug administration.
文摘Oral drugs such as ibrutinib play an important role in the treatment of mature B-cell lymphoma(BCL)due to their reliable efficacy,manageable safety,high accessibility,and convenience for use.Still,no guidelines or consensus focusing on oral drug therapies for BCL is available.To provide a reference of oral agent-based treatment for mature BCL,a panel of experts from the Lymphocyte Disease Group,Chinese Society of Hematology,Chinese Medical Association conducted an extensive discussion and reached a consensus on oral drugs for Chinese BCL patients on the basis of the current application status of oral drugs in China,combined with the latest authoritative guidelines in the world and current research reports.This consensus reviewed the application of oral drugs in the treatment of BCL and the latest research and provided appropriate recommendations on the use of oral drugs for indolent or aggressive BCL patients.With the deepening of research and the development of standardized clinical applications,oral medications will bring better treatment to BCL patients,enabling more patients to benefit from them.
基金supported by the National Natural Science Foundation of China (Nos. 81773276, 81972907, 81874304, and U1804183)Key Scientific Research Project (Education Department of Henan Province)(No. 20HASTIT049)Modern Analysis and Computer Center of Zhengzhou University。
文摘Oral drugs have been widely used in clinical therapy, but their developments were severely limited by the side effects of drug exposure as well as the multiple biological barriers. In this study, we constructed a “cluster bomb” oral drug delivery system (DOX@PFeL@L100) with core-shell structure to overcome the complex absorption barriers. The inner core termed as “bomb” that contains a lot of ultra-small diameter Fe_(3)O_(4) nanoparticles (DOX@PFeL NPs) loaded with doxorubicin (DOX) and modified with l-valine, which can efficiently penetrate the epithelial cells via PePT1 receptor mediated endocytosis. The outer shell of this “cluster bomb” is a layer of pH-sensitive polymer (Eudragit®L100) that can be served as a pH-responsive switch and effectively control the “bomb” release in the intestinal microenvironment to improve the antitumor efficiency by the Fenton like reaction of DOX and Fe^(2+)/Fe^(3+). This study demonstrates that the “cluster comb” oral drug delivery system can sequentially overcome the multiple biological barriers, providing a safe and effective approach for tumor therapy.
基金financially supported by National Natural Science Foundation of China (81573363 and 81690263)National Key Basic Research Program (2015CB931800)
文摘Liposomes mimic natural cell membranes and have long been investigated as drug carriers due to excellent entrapment capacity, biocompatibility and safety. Despite the success of parenteral liposomes,oral delivery of liposomes is impeded by various barriers such as instability in the gastrointestinal tract,difficulties in crossing biomembranes, and mass production problems. By modulating the compositions of the lipid bilayers and adding polymers or ligands, both the stability and permeability of liposomes can be greatly improved for oral drug delivery. This review provides an overview of the challenges and current approaches toward the oral delivery of liposomes.
