Carbon nanomaterialsCarbon Nanomaterials (CNM) have gathered substantial awareness in the biomedicalBiomedical field for applications such as biosensing, drug deliveryDrug delivery, and tissue engineeringTissue engineering. Their exceptional structure and extraordinary conductivity permit them to address current challenges in biomedical research, including biomolecular instability, low biosensor sensitivity and selectivity, and difficulties in precise drug delivery. Novel nanomaterials have recently been integrated with carbon nanoparticlesNanoparticles to create complexCarbon-based nanocomposites carbon-based nanocompositesNanocomposites for biomedical applicationsBiomedical applications. This chapter examines these developments, highlighting the potential of non-traditional carbonaceous nanocomposites as efficient functional drug deliveryDrug delivery systemsDrug delivery systems. Improved protection against environmental deterioration and increased medication loading efficiency are two advantages of these materials. Different carbon-based nanocarriers, including fullerenes, graphene/graphite, carbon nanotubesCarbon Nanotube (CNT), and nanodiamonds/diamond-like carbon, will be discussed along with their unique properties. This chapter examines how carbon-based nanocarriers capabilities are being upgraded by sophisticated surface functionalizationSurface functionalization approaches. Key studies that show their effectiveness in drug loading and sustained release in both lab (in vitro) and living organism (in vivo) conditions will be studied. We will also explore basic ideas in drug distribution, such as: Targeted delivery: The process of guiding these nanocarriers to particular locations. Stimulus-responsive mechanisms: How they release medications in reaction to stimuli such as pH sensitivity or acidity changes, chemical interactions, photothermal activation. In the end, this conversation seeks to deepen our knowledge of carbonaceous nanocompositesNanocomposites, generating greater curiosity and stimulating further study of cutting-edge drug deliveryDrug delivery methods.

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Carbon-Based Nanocomposites for Drug Delivery

  • Anju Singh,
  • Dalia Fouad,
  • Kamal Kishor Thakur

摘要

Carbon nanomaterialsCarbon Nanomaterials (CNM) have gathered substantial awareness in the biomedicalBiomedical field for applications such as biosensing, drug deliveryDrug delivery, and tissue engineeringTissue engineering. Their exceptional structure and extraordinary conductivity permit them to address current challenges in biomedical research, including biomolecular instability, low biosensor sensitivity and selectivity, and difficulties in precise drug delivery. Novel nanomaterials have recently been integrated with carbon nanoparticlesNanoparticles to create complexCarbon-based nanocomposites carbon-based nanocompositesNanocomposites for biomedical applicationsBiomedical applications. This chapter examines these developments, highlighting the potential of non-traditional carbonaceous nanocomposites as efficient functional drug deliveryDrug delivery systemsDrug delivery systems. Improved protection against environmental deterioration and increased medication loading efficiency are two advantages of these materials. Different carbon-based nanocarriers, including fullerenes, graphene/graphite, carbon nanotubesCarbon Nanotube (CNT), and nanodiamonds/diamond-like carbon, will be discussed along with their unique properties. This chapter examines how carbon-based nanocarriers capabilities are being upgraded by sophisticated surface functionalizationSurface functionalization approaches. Key studies that show their effectiveness in drug loading and sustained release in both lab (in vitro) and living organism (in vivo) conditions will be studied. We will also explore basic ideas in drug distribution, such as: Targeted delivery: The process of guiding these nanocarriers to particular locations. Stimulus-responsive mechanisms: How they release medications in reaction to stimuli such as pH sensitivity or acidity changes, chemical interactions, photothermal activation. In the end, this conversation seeks to deepen our knowledge of carbonaceous nanocompositesNanocomposites, generating greater curiosity and stimulating further study of cutting-edge drug deliveryDrug delivery methods.