Grafting of molecularly imprinted polymers on iniferter-modified carbon nanotube

Molecularly imprinted polymers (MIPs) were grafted on iniferter-modified carbon nanotube (CNT). Tween 20 was first immobilized on CNT by hydrophobic interactions. The hydroxyl-functionalized CNT was modified by silanisation with 3-chloropropyl trimethoxysilane. The iniferter groups were then introduced by reacting the CNT-bound chloropropyl groups with sodium N,N-diethyldithiocarbamate. UV light-initiated copolymerization of ethylene glycol dimethacrylate (crosslinking agent) and methacrylic acid (functional monomer) resulted in grafting of MIP on CNT for theophylline as a model template. MIPs grafted on CNT were characterized with elemental analysis, scanning electron microscopy, and thermogravimetric analysis. The theophylline-imprinted polymer on CNT showed higher binding capacity for theophylline than non-imprinted polymer on CNT and selectivity for theophylline over caffeine and theobromine (similar structure molecules). The data of theophylline and caffeine binding into the theophylline-imprinted polymer correlated well with the Scatchard plot. These MIPs on CNT can potentially be applied to probe materials in biosensor system based on CNT field effect transistor.     

Direct electron transfer and bioelectrocatalysis of hemoglobin at a carbon nanotube electrode

A stable suspension of carbon nanotube (CNT) can be obtained by dispersing the CNT in the solution of the surfactant cetyltrimethylammonium bromide. CNT has promotion effects on the direct electron transfer of hemoglobin (Hb), which was immobilized onto the surface of CNT. The direct electron transfer rate of Hb was greatly enhanced after it was immobilized onto the surface of CNT. Cyclic voltammetric results showed a pair of well-defined redox peaks, which corresponded to the direct electron transfer of Hb, with the formal potential (E^0′) at about −0.343 V (vs. saturated calomel electrode) in the phosphate buffer solution (pH 6.8). The electrochemical parameters such as apparent heterogeneous electron transfer rate constant (k_s) and the value of formal potential (E^0′) were estimated. The dependence of E^0′ on solution pH indicated that the direct electron transfer reaction of Hb is a one-electron transfer coupled with a one-proton transfer reaction process. The experimental results also demonstrated that the immobilized Hb retained its bioelectrocatalytic activity to the reduction of H₂O₂. The electrocatalytic current was proportional to the concentration of H₂O₂ at least up to 20 mM.     

Quantum chemical molecular dynamics simulation of carbon nanotube–graphene fusion

Abstract

Here we report a quantum mechanical molecular dynamics (QM/MD) study of a fusion process of an open-ended carbon nanotube on a graphene hole, which results in the formation of a so-called pillared graphene structure – a three-dimensional nanomaterial consisting entirely of sp²-carbons. The self-consistent-charge density-functional tight-binding potential was adopted in this study. Two different sizes of graphene holes with 12 or 24 central carbon atoms removed from a graphene flake, and a (6,6) carbon nanotube with a compatible diameter were adopted. Formations of 6–7–6/5–8–5 defect structures were found on the fusion border between tube and graphene hole. The 6–7–6 structure was found to bear less curvature-induced strain energy and therefore to be more stable and much easier to form than the 5–8–5 structure.     

Noncovalent and covalent functionalization of a (5, 0) single-walled carbon nanotube with alanine and alanine radicals

We have systematically investigated the noncovalent and covalent adsorption of alanine and alanine radicals, respectively, onto a (5, 0) single-walled carbon nanotube using first-principles calculation. It was found that XH···π (X = N, O, C) interactions play a crucial role in the non-ovalent adsorption and that the functional group close to the carbon nanotube exhibits a significant influence on the binding strength. Noncovalent functionalization of the carbon nanotube with alanine enhances the conductivity of the metallic (5, 0) nanotube. In the covalent adsorption of each alanine radical onto a carbon nanotube, the binding energy depends on the adsorption site on CNT and the electronegative atom that binds with the CNT. The strongest complex is formed when the alanine radical interacts with a (5, 0) carbon nanotube through the amine group. In some cases, the covalent interaction of the alanine radical introduces a half-filled band at the Fermi level due to the local sp ³ hybridization, which modifies the conductivity of the tube.     

Carbon nanotubes accelerate methane production in pure cultures of methanogens and in a syntrophic coculture

Carbon materials have been reported to facilitate direct interspecies electron transfer (DIET) between bacteria and methanogens improving methane production in anaerobic processes. In this work, the effect of increasing concentrations of carbon nanotubes (CNT) on the activity of pure cultures of methanogens and on typical fatty acid‐degrading syntrophic methanogenic coculture was evaluated. CNT affected methane production by methanogenic cultures, although acceleration was higher for hydrogenotrophic methanogens than for acetoclastic methanogens or syntrophic coculture. Interestingly, the initial methane production rate (IMPR) by Methanobacterium formicicum cultures increased 17 times with 5 g·L^?1 CNT. Butyrate conversion to methane by Syntrophomonas wolfei and Methanospirillum hungatei was enhanced (～1.5 times) in the presence of CNT (5 g·L^?1), but indications of DIET were not obtained. Increasing CNT concentrations resulted in more negative redox potentials in the anaerobic microcosms. Remarkably, without a reducing agent but in the presence of CNT, the IMPR was higher than in incubations with reducing agent. No growth was observed without reducing agent and without CNT. This finding is important to re‐frame discussions and re‐interpret data on the role of conductive materials as mediators of DIET in anaerobic communities. It also opens new challenges to improve methane production in engineered methanogenic processes.     

Study of the acyl transfer activity of a recombinant amidase overproduced in an Escherichia coli strain. Application for short-chain hydroxamic acid and acid hydrazide synthesis

The study of acyl transfer activity of a wide spectrum amidase from Rhodococcus sp. R312, overproduced in an Escherichia coli strain, revealed that the ‘bi-bi-ping-pong’ type reaction was efficient with only four very-short chain (C₂–C₃) aliphatic amides as substrates. The optimum working pH was 7.0 for all neutral amides. Very short-chain aliphatic carboxylic acids were 10–1000-fold less efficient and the corresponding optimum working pH values depended on the acid used. Very polar molecules, such as water, hydroxylamine and hydrazine, were good acyl acceptors. An [acyl donor]/[acyl acceptor] ratio lower than 0.3-0.5 had to be maintained to avoid enzyme inhibition by excess acyl donor. The different acyl-enzyme complexes generally exhibited high affinity for hydroxylamine or hydrazine (except the propionyl-enzyme complex), so that the residual hydrolysis activities were almost totally inhibited at appropriate acyl acceptor concentrations. Molar conversion yields were higher with hydrazine as acyl acceptor (e.g., 97% with acetamide as acyl donor) because of the higher V_max values, but in all cases, interesting quantities of short-chain hydroxamic acids (2.9-6.5 g l⁻¹) and acid hydrazides (6.4–7.8 g l⁻¹) could be quickly obtained (10–60 min) with small amounts of enzyme (0.04-0.20 g l⁻¹).     

Serratia marcescens SYBC08 catalase isolated from sludge containing hydrogen peroxide shows increased catalase production by regulation of carbon metabolism

A high‐catalase‐producing strain, which was isolated from sludge containing hydrogen peroxide, was identified as Serratia marcescens SYBC08 by 16S rDNA sequence analysis. Serratia spp. was reported as non‐spore‐forming bacterium (except S. marcescens spp. sakuensis), but in our study electron microscopic observation revealed that the strain did produce spores. The content of the main fatty acid C_16:0 (14.8%) was significantly different from that of S. marcescens spp. sakuensis (33.2%) and S. marcescens spp. marcescens DSM 30121^T (34.8%), and the biochemical characteristics were not identical to those of S. marcescens spp. sakuensis. We speculate that the relatively high catalase activity and the spore structures may enable the strain to survive in a hydrogen peroxide environment. The most suitable carbon and nitrogen sources for the catalase production by S. marcescens SYBC08 were citric acid and corn steep liquor powder. A strategy of carbon metabolism regulation to enhance the catalase production was exploited. In the 7‐L fermenter, catalase production (20 353 U/mL) obtained in the presence of glucose and citric acid was 1.68‐ and 1.31‐fold higher than that obtained in the presence of glucose or citric acid, at equimolar carbon concentration. This production yield was much higher than that of many catalase‐producing strains, but only slightly lower than the production by Micrococcus luteus (34 601 U/mL). The results suggest that the new spore‐forming S. marcescens SYBC08 is a potential candidate for the production of catalase.     

Sensitive amperometric immunosensor for α-fetoprotein based on carbon nanotube/gold nanoparticle doped chitosan film

A novel strategy for the fabrication of sensitive immunosensor to detect α-fetoprotein (AFP) in human serum has been proposed. The immunosensor was prepared by immobilizing AFP antigen onto the glassy carbon electrode (GC) modified by gold nanoparticles and carbon nanotubes doped chitosan (GNP/CNT/Ch) film. GNP/CNT hybrids were produced by one-step synthesis based on the direct redox reaction. The electrochemical properties of GNP/CNT/Ch films were characterized by impedance spectroscopy and cyclic voltammetry. It was indicated that GNP/CNT nanohybrid acted as an electron promoter and accelerated the electron transfer. Sample AFP, immobilized AFP, and alkaline phosphatase (ALP)-labeled antibody were incubated together for the determination based on a competitive immunoassay format. After the immunoassay reaction, the bound ALP label on the modified GC led to an amperometric response of 1-naphthyl phosphate (1-NP), which was changed with the different antigen concentrations in solution. Under the optimized experimental conditions, the resulting immunosensor could detect AFP in a linear range from 1 to 55 ng ml⁻¹ with a detection limit of 0.6 ng ml⁻¹. The proposed immunosensor, by using GNP/CNT/Ch as the immobilization matrix of AFP, offers an excellent amperometric response of ALP-anti-AFP to 1-NP. The immunosensor provided a new alternative to the application of other antigens or other bioactive molecules.     

Discovery of a bicyclo[4.3.0]nonane derivative DS88790512 as a potent,selective, and orally bioavailable blocker of transient receptor potential canonical 6 (TRPC6)

In this study, we aimed to synthesize a novel blocker of transient receptor potential canonical 6 (TRPC6). The sp² carbon atoms of the aminoindane skeleton of the known inhibitor were replaced with sp³ carbon atoms to increase the molecular complexity, measured by fraction sp³ (Fsp³). The representative compound, a bicyclo[4.3.0]nonane derivative DS88790512, inhibited TRPC6 with an IC₅₀ value of 11?nM. Notably, DS88790512 exhibited excellent selectivity against hERG and hNa_V1.5 channels, and was identified as an orally bioavailable compound.     

Carbon Source Requirements for Exopolysaccharide Production by Lactobacillus casei CG11 and Partial Structure Analysis of the Polymer

Exopolysaccharide production by Lactobacillus casei CG11 was studied in basal minimum medium containing various carbon sources (galactose, glucose, lactose, sucrose, maltose, melibiose) at concentrations of 2, 5, 10, and 20 g/liter. L. casei CG11 produced exopolysaccharides in basal minimum medium containing each of the sugars tested; lactose and galactose were the poorest carbon sources, and glucose was by far the most efficient carbon source. Sugar concentrations had a marked effect on polymer yield. Plasmid-cured Muc^- derivatives grew better in the presence of glucose and attained slightly higher populations than the wild-type strain. The values obtained with lactose were considerably lower for both growth and exopolysaccharide yield. The level of specific polymer production per cell obtained with glucose was distinctively lower for Muc^- derivatives than for the Muc⁺ strain. The polymer produced by L. casei CG11 in the presence of glucose was different from that formed in the presence of lactose. The polysaccharide produced by L. casei CG11 in basal minimum medium containing 20 g of glucose per liter had an intrinsic viscosity of 1.13 dl/g. It was rich in glucose (76%), which was present mostly as 2- or 3-linked residues along with some 2,3 doubly substituted glucose units, and in rhamnose (21%), which was present as 2-linked or terminal rhamnose; traces of mannose and galactose were also present.     

华南热带人工林土壤有机碳含量及其稳定性特征

研究华南热带多雨地区小良人工森林生态系统定位站不同人工林的碳固持特征,测定了林地表土有机碳含量、有机碳随土层深度的变化以及有机碳在不同粒级团聚体上的分布。结果表明：无植被覆盖的光裸地储存了极低水平的有机碳,在光裸地上种植桉树林后,如果地表枯落物长期人为取走,则土壤有机碳积累大大低于未受干扰桉林。当桉林进一步改造为阔叶混交林后,30-40a林龄混交林土壤有机碳含量均高于16.5gkg^-1,但仍只有邻近天然林土壤有机碳水平的76%,因而,这些人工混交林土壤具有进一步积累碳的潜力。光裸地在1m剖面上的含碳量均极低,并无显著的深度变化,约2-3gkg^-1,未保护的桉林含量水平在4-5gkg^-1,同样表土与心土层没有明显差别,通过地表输入的凋落物对土壤有机碳的影响主要集中在表层0.5m范围内。以豹皮樟Litsea rotundifolia,阴香Cinnamomum burmanni,潺槁木姜子Litsea glutinosa,陈氏钓樟Lindera chuni等为优势种的混交林,深层土壤含碳量显著高于其它混交林,并与村边林相似。土壤有机碳储量与土壤团聚体发育有一定的相关性,非水稳性团聚体以最小粒径（〈0.25mm）的含碳浓度最高,其它粒级的有机碳浓度相似,未成熟人工林,小团聚体的碳浓度较高,成熟林则在不同粒级中较均匀地分配有机碳,但实际碳储量于最大粒级的非水稳性团聚体中最多。成熟森林土壤水稳性团聚体含碳浓度大大高于非水稳性团聚体,水稳性团聚体在0.25-0.5mm及0.5-1.0mm两个粒级上有最大的碳积累量。结果表明,建立特定类型的混交林是增加林地碳汇功能的一个有效途径,非水稳性的大团聚体与水稳性的小团聚体的有效发育可能是成熟森林高固碳量的重要机理。     

Enhanced Exopolysaccharide Production by Metabolic Engineering of Streptococcus thermophilus

It is possible that the low levels of production of exopolysaccharides (EPSs) by lactic acid bacteria could be improved by altering the levels of enzymes in the central metabolism that influence the production of precursor nucleotide sugars. To test this hypothesis, we identified and cloned the galU gene, which codes for UDP glucose pyrophosphorylase (GalU) in Streptococcus thermophilus LY03. Homologous overexpression of the gene led to a 10-fold increase in GalU activity but did not have any effect on the EPS yield when lactose was the carbon source. However, when galU was overexpressed in combination with pgmA, which encodes phosphoglucomutase (PGM), the EPS yield increased from 0.17 to 0.31 g/mol of carbon from lactose. A galactose-fermenting LY03 mutant (Gal⁺) with increased activities of the Leloir enzymes was also found to have a higher EPS yield (0.24 g/mol of carbon) than the parent strain. The EPS yield was further improved to 0.27 g/mol of carbon by overexpressing galU in this strain. However, the highest EPS yield, 0.36 g/mol of carbon, was obtained when pgmA was knocked out in the Gal⁺ strain. Measurements of the levels of intracellular metabolites in the cultures revealed that the Gal⁺ strains had considerably higher glucose 1-phosphate levels than the other strains, and the strain lacking PGM activity had threefold-higher levels of glucose 1-phosphate than the other Gal⁺ strains. These results show that it is possible to increase EPS production by altering the levels of enzymes in the central carbohydrate metabolism.     

Preparation of co‐Co3O4/carbon nanotube/carbon foam for glucose sensor

Co‐Co₃O₄/carbon nanotube/carbon foam (Co‐Co₃O₄/CNT/CF) nanocomposites were prepared by soaking melamine foam into a solution of Co(NO₃)₂·6H₂O, followed by calcination in N₂ and air in sequence. The obtained Co‐Co₃O₄/CNT/CF nanocomposites were characterized with scanning electron microscopy and cyclic voltammetry. It was found that Co₃O₄ nanoparticles were grown on the external of CF successfully, while CNTs were grown on the surfaces of CF in a large amount, which further improved the electrical conductivity of the. The prepared Co‐Co₃O₄/CNT/CF nanocomposites were then used to construct nonenzymatic sensor to detect glucose in alkaline solution. The sensor showed detection range from 1.2 μM to 2.29 mM with a detection limit of 0.4 μM (S/N =3) and a high sensitivity of 637.5 μA^?1 cm^?2. The developed sensor also showed an instant response, favorable reproducibility, and high selectivity. The results attest that Co‐Co₃O₄/CNT/CF composites have great potential in the development of nonenzymatic sensors for glucose.     

Mechanistic Diversity of Radical S-Adenosylmethionine (SAM)-dependent Methylation

Radical S-adenosylmethionine (SAM) enzymes use the oxidizing power of a 5′-deoxyadenosyl 5′-radical to initiate an amazing array of transformations, usually through the abstraction of a target substrate hydrogen atom. A common reaction of radical SAM (RS) enzymes is the methylation of unactivated carbon or phosphorous atoms found in numerous primary and secondary metabolites, as well as in proteins, sugars, lipids, and RNA. However, neither the chemical mechanisms by which these unactivated atoms obtain methyl groups nor the actual methyl donors are conserved. In fact, RS methylases have been grouped into three classes based on protein architecture, cofactor requirement, and predicted mechanism of catalysis. Class A methylases use two cysteine residues to methylate sp²-hybridized carbon centers. Class B methylases require a cobalamin cofactor to methylate both sp²-hybridized and sp³-hybridized carbon centers as well as phosphinate phosphorous atoms. Class C methylases share significant sequence homology with the RS enzyme, HemN, and may bind two SAM molecules simultaneously to methylate sp²-hybridized carbon centers. Lastly, we describe a new class of recently discovered RS methylases. These Class D methylases, unlike Class A, B, and C enzymes, which use SAM as the source of the donated methyl carbon, are proposed to methylate sp²-hybridized carbon centers using methylenetetrahydrofolate as the source of the appended methyl carbon.     

Carbon mass balance methodology to characterize the growth of pigmented marine bacteria under conditions of light cycling

A carbon mass balance methodology employing minimal measurements was applied to heterotrophic and photoheterotrophic marine bacteria grown under constant dilution and exposed to 12-h intervals of light or darkness. Carbon mass balance calculations using measurements taken every 3 h closed to within 93–103% using dissolved organic carbon, biomass carbon and CO₂ production data only, indicating that background interference from dissolved inorganic carbon variations in the amended seawater medium was not significant. Neither strain was observed to sustain a net CO₂ fixation using paramagnetic measurement of oxygen uptake rates (OUR), indicating a need for more sensitive on-line measurement techniques for OUR. Photoheterotrophic growth demonstrated lower carbon-mole biomass yields (0.41±0.026 vs. 0.64±0.013 mol mol^–1) despite higher specific glucose uptake rates (0.025 vs. 0.02 mol mol^–1 h^–1), suggesting that bioreactor-based study of marine bacteria can present growth modes that are different from those encountered in the marine environment.     

Enriched rhizosphere CO2 concentrations can ameliorate the influence of salinity on hydroponically grown tomato plants

Our previous work indicated that salinity caused a shift in the predominant site of nitrate reduction and assimilation from the shoot to the root in tomato plants. In the present work we tested whether an enhanced supply of dissolved inorganic carbon (DIC, CO₂+ HCO₃) to the root solution could increase anaplerotic provision of carbon compounds for the increased nitrogen assimilation in the root of salinity-stressed Lycopersicon esculentum (L.) Mill. cv. F144. The seedlings were grown in hydroponic culture with 0 or 100mM NaCl and aeration of the root solution with either ambient or CO₂-enriched air (5000 μmol mol^?1). The salinity-treated plants accumulated more dry weight and higher total N when the roots were supplied with CO₂-enriched aeration than when aerated with ambient air. Plants grown with salinity and enriched DIC also had higher rates of NO^?₃ uptake and translocated more NO^?₃ and reduced N in the xylem sap than did equivalent plants grown with ambient DIC. Incorporation of DIC was measured by supplying a 1 -h pulse of H¹⁴CO^?₃ to the roots followed by extraction with 80% ethanol. Enriched DIC increased root incorporation of DIC 10-fold in both salinized and non-salinized plants. In salinity-stressed plants, the products of dissolved inorganic ¹⁴C were preferentially diverted into amino acid synthesis to a greater extent than in non-salinized plants in which label was accumulated in organic acids. It was concluded that enriched DIC can increase the supply of N and anaplerotic carbon for amino acid synthesis in roots of salinized plants. Thus enriched DIC could relieve the limitation of carbon supply for ammonium assimilation and thus ameliorate the influence of salinity on NO^?₃ uptake and assimilation as well as on plant growth.     

Carbon uptake and respiration in above-ground parts of a Larix decidua × leptolepis tree

Summary Shade needles of hybrid larch (Larix decidua × leptolepis) had the same rates of photosynthesis as sun needles per dry weight and nitrogen, and a similar leaf conductance under conditions of light saturation at ambient CO₂ (A_max). However, on an area basis, A_max and specific leaf weight were lower in shade than in sun needles. Stomata of sun needles limited CO₂ uptake at light saturation by about 20%, but under natural conditions of light in the shade crown, shade needles operated in a range of saturating internal CO₂ without stomatal limitation of CO₂ uptake. In both needle types, stomata responded similarly to changes in light, but shade needles were more sensitive to changes in vapor pressure deficit than sun needles. Despite a high photosynthetic capacity, the ambient light conditions reduced the mean daily (in summer) and annual carbon gain of shade needles to less than 50% of that in sun needles. In sun needles, the transpiration per carbon gain was about 220 mol mol^–1 on an annual basis. The carbon budget of branches was determined from the photosynthetic rate, the needle biomass and respiration, the latter of which was (per growth and on a carbon basis) 1.6 mol mol^–1 year^–1 in branch and stem wood. In shade branches carbon gains exceeded carbon costs (growth + respiration) by only a factor of 1.6 compared with 3.5 in sun branches. The carbon balance of sun branches was 5 times higher per needle biomass of a branch or 9 times higher on a branch length basis than shade branches. The shade foliage (including the shaded near-stem sun foliage) only contributed approximately 23% to the total annual carbon gain of the tree.     

Endopolyploidy in Chlorella

A mutant of Dunaliella tertiolecta produced by treatment with methyl nitrosoguanidine and designated HL25/8, grew more slowly than the parent strain under all experimental conditions and was conspicuously less tolerant of NaCl. Total photosynthetic activity (C-fixation and O₂ evolution) was less in HL25/8 than in the parent strain and was affected differently by [NaCl] in the two strains. Various growth characteristics indicated that the mutant had a greater need than the parent strain for CO₂ as distinct from HCO ₃ ^– as a source of carbon. Gaseous CO₂ extended the range of salt tolerance of the mutant. For example, HL25/8 could not sustain growth at 1.02 M NaCl in a conventional buffered medium containing bicarbonate as the sole carbon source but could do so if the medium were sparged with a CO₂/air mixture. The mutant strain has a lower activity of carbonic anhydrase on the cell surface than the parent D. tertiolecta. Moreover, the two strains differ sharply in the responses of their surface carbonic anhydrase activity to salinity of the growth medium. Increasing sodium chloride concentration above 0.17 M raised activity of the enzyme in the parent strain but decreased it in HL25/8. We conclude that the low activity of carbonic anhydrase and its response to salinity can largely, but perhaps not fully, explain the diminished salt tolerance of the mutant. A plate counting method applicable to Dunaliella is described.     

Biomolecular interaction analysis for carbon nanotubes and for biocompatibility prediction

The interactions between carbon nanotubes (CNTs) and biologics have been commonly studied by various microscopy and spectroscopy methods. We tried biomolecular interaction analysis to measure the kinetic interactions between proteins and CNTs. The analysis demonstrated that wheat germ agglutinin (WGA) and other proteins have high affinity toward carboxylated CNT (f-MWCNT) but essentially no binding to normal CNT (p-MWCNT). The binding of f-MWCNT–protein showed dose dependence, and the observed kinetic constants were in the range of 10⁻⁹ to 10⁻¹¹ M with very small off-rates (10⁻³ to 10⁻⁷ s⁻¹), indicating a relatively tight and stable f-MWCNT–protein complex formation. Interestingly in hemolysis assay, p-MWCNT showed good biocompatibility, f-MWCNT caused 30% hemolysis, but WGA-coated f-MWCNT did not show hemolysis. Furthermore, the f-MWCNT–WGA complex demonstrated enhanced cytotoxicity toward cancer cells, perhaps through the glycoproteins expressed on the cells' surface. Taken together, biomolecular interaction analysis is a precise method that might be useful in evaluating the binding affinity of biologics to CNTs and in predicting biological actions.     

Carbon nanotube array: A new MIP platform

Here we demonstrate that a free-standing carbon nanotube (CNT) array can be used as a large surface area and high porosity 3D platform for molecular imprinted polymer (MIP), especially for surface imprinting. The thickness of polymer grafted around each CNT can be fine-tuned to imprint different sizes of target molecules, and yet it can be thin enough to expose every imprint site to the target molecules in solution without sacrificing the capacity of binding sites. The performance of this new CNT–MIP architecture was first assessed with a caffeine-imprinted polypyrrole (PPy) coating on two types of CNT arrays: sparse and dense CNTs. Real-time pulsed amperometric detection was used to study the rebinding of the caffeine molecules onto these CNT-MIPPy sensors. The dense CNT-MIPPy sensor presented the highest sensitivity, about 15 times better when compared to the conventional thin film, whereas an improvement of 3.6 times was recorded on the sparse CNT. However, due to the small tube-to-tube spacing in the dense CNT array, electrode fouling was observed during the detection of concentrated caffeine in phosphate buffer solution. A new I–V characterization method using pulsed amperometry was introduced to investigate the electrical characterization of these new devices. The resistance value derived from the I–V plot provides insight into the electrical conductivity of the CNT transducer and also the effective surface area for caffeine imprinting.