Better epoxy resin embedding for electron microscopy at low relative humidity.

In the absence of other factors known to influence sectioning properties, high environmental relative humidity is shown to yield poorly embedded tissue. Humidity-related effects are avoided if the following embedding precedure is used; impregnate tissues using the following solutions 1) 70% alcohol - 5 minutes, 2) 95% alcohol - 2 x 15 minutes, 3) absolute alcohol - 3 x 20 minutes, 4) acetone - 2 x 15 minutes, 5) 1:1 mixture of acetone-epoxy resin (DDSA, 63.4 g; Araldite 502, 5.6 g; Epon 812, 39.4 g; DMP-30, 2.6 g) - 1 hour, 6) acetone-epoxy resin 1:3 - 1 hour, 7) epoxy resin - 1 hour; complete the preparation of blocks as follows 8) when tissues have been oriented in epoxy resin in flat embedding molds, place molds in one evacuated vacuum desiccator 10 cm above a 2 cm layer of Drierite for 24 hours at room temperature, 9) raise temperature to 60 C and maintain for 3 days to cure resin.     

Selection for Electron Microscopy of Specific Areas in Large Epoxy Tissue Sections

Tissue blocks 2 × 2 × 0.4 cm were fixed 6-24 hr in phosphate-buffered 6% glutaraldehyde then sliced to 2 × 2 × 0.1 cm and rinsed in phosphate buffer for at least 12 hr. Fixation was continued for 2 hr in phosphate-buffered 1-2% OsO₄. The slices were dehydrated, infiltrated with Araldite, and embedded in flat-bottomed plastic molds. Sectioning at 4-8 μ with a sliding microtome was facilitated by addition of 10% dibutylphalate to the standard epoxy mixture. The sections were spread on water and attached to coverslips by drying, then heating to 80 C for 1 min. Staining 2 min with 1-3% KMnO₄ and temporary mounting in glycerol on a slide allowed the desired area for electron microscopy to be selected and marked. This area was then cemented to the facet of a conventional epoxy casting with a drop of epoxy resin (without added dibutylphthalate). After polymerization, the coverslip was removed by quick cooling leaving a flat re-embedded portion of the original section. This portion was viewed by transillumination in a dissecting microscope and trimmed of surplus tissue. Ultrathin sections for electron microscopy were obtained in the usual manner.     

Preparation of Large Epoxy Sections for Light Microscopy as an Adjunct to Fine-Structure Studies

Tissue blocks 2 × 2 × 0.4 cm were fixed 6-24 hr in phosphate-buffered 5% glutaraldehyde then sliced to 2 × 2 × 0.1 cm and soaked in 0.1 phosphate-buffer (pH 7.3) for at least 12 hr. Fixation was continued for 2 hr in phosphate-buffered 1-2% OsO₄. The slices were dehydrated, infiltrated with Araldite, and embedded in flat-bottomed plastic molds. Sectioning at 1-8 μ with a sliding microtome was facilitated by addition of 10% dibutylphthalate to the standard epoxy mixture. The sections were spread on warm 1% gelatin and attached to glass slides by drying, baking at 60 C, fixing in 10% formalin or 5% glutaraldehyde and baking again. Sections were mordanted in 5% KMnO₄ (5 min), bleached with 5% oxalic acid (5 min) and neutralized in 1% Li₂CO₃ (1 min). Several stains could then be applied: azure B, toluidine blue, azure B-malachite green, Stirling's gentian violet, MacCallum's stain (modified), tribasic stain (modified) and phosphotungstic acid-hematoxylin. Nuclei, mitochondria, specific granules, elastic tissue or collagen were selectively emphasized by appropriate choice of staining procedures, and cytologic detail in 1-3 μ sections was superior to that shown by conventional methods. Selected areas from adjacent 4-8 μ sections could be re-embedded for ultramicrotomy and electron microscopy.     

Epoxy Embedding, Sectioning and Staining of Plant Material for Light Microscopy

By using a formula which gives a relatively soft epoxy embedding medium, it is possible to cut sections of plant material with a sliding microtome equipped with a regular steel knife. Blocks having a cutting face of 10 × 10 mm, giving sections of 4-10 μm, can be used. Tissues are fixed in Karnovsky's fluid, postfixed in 1 or 2% OsO₄, embedded in Spurr's soft epoxy resin, Araldite, or Epon mixtures. 5% KMnO₄, followed by 5% oxalic acid, then neutralized in 1% LiCO₃, are used to mordant the sections. Some of the stains used are Mallory's phosphotungstic acid-hemotoxylin, acid fuchsin and toluidine blue, or toluidine blue. Mounting is done with whichever soft epoxy resin was used in casting the blocks.     

Improvements in Histological Techniques for Epoxy-Resin Embedded Bone Specimens

A procedure is presented in which some of the processing difficulties with fixation, embedding and cutting whole mouse bones and large bone pieces from other species are considered. The bone specimens are fixed in acetone or by a Karnovsky-formol-saline process which preserves intact endosteal surface-to-cortex layers. After fixation the bones are embedded in a hard mixture of epoxy resin to provide blocks with face sizes up to 3.5 × 3.0 cm. Mineralized sections are cut at 4 μm; demineralized at 3 μm. Sections are fastened to gelatin-subbed slides with pressure plates which produce flat, secure sections. After removal of the plastic, an unmodified Mayer's hematoxylin and a polychromatic eosin staining method is applied to demineralized sections, and a slightly modified method to mineralized sections.     

Species- and clone-specific responses to environmental stimuli in the cladocerans Bosmina cornuta and B. pellucida - a comparison with Daphnia

We studied the variation of small-scale swimming behaviour in eight Bosmina cornuta and ten B. pellucida clones in response to key environmental factors to test whether swimming behaviour and genotypes are linked in non-Daphnia cladocerans. We quantified (1) the short-term responses to changes in temperature, light intensity and pH, (2) the response to long-term temperature acclimation, and (3) the pH-related survival rates. Vertical swimming activity S was quantified in cuvette experiments as crossings of a line at 2 cm height per individual an hour. S differed significantly among species and conspecific clones. At any temperature, light intensity and pH tested, B. cornuta (clone variation: 40-58 crossings/ind.× h) showed a higher vertical swimming activity than B. pellucida (clone variation: 25-48 crossings/ind.× h). A short-term change of water temperature (range tested: 10-25°C) only affected S of B. cornuta, whereas that of B. pellucida remained unaltered. In contrast, S increased with rising temperature following long-term temperature acclimation (range tested: 10-20°C) in both species. Swimming activity was inversely related to the light intensity (range tested: 60-60,000 lux), but decrease of activity was stronger in B. pellucida (44 → 12 crossings/ind × h) than in B. cornuta (50 → 40 crossings/ind.× h). Short-term changes of pH (range tested: 4-6) did not influence swimming activity in any species, although a prolonged exposure (24 h) to pH 4 was lethal. Thus, Bosmina showed behavioural responses which permit to distinguish between the species and which are related to their seasonal succession and distribution pattern.     

The Production of Large, Epoxy-Embedded, 50 μ Sections by Precision Sawing; A Preliminary to Survey for Ultrathin Sectioning

Tissue slices not more than 4 mm thick—including those containing mineralized bone—were fixed in buffered 6.25% glutaraldehyde. Parts of the specimen to be used for subsequent electron microscopy had to be within 1 mm of the surface to permit proper penetration of the second fixation in 1% OsO₄, therefore, if such parts were not originally so exposed, superfluous tissue was dissected away. After fixation and washing, a regular dehydration and embedding sequence was used, but with the time in individual fluids tripled, and 2 changes of absolute ethanol and 2 of undiluted resin added to insure thorough permeation. The resin mixture (containing Epon 812) was the hardest one normally used for ultra-thin sectioning. The blocks were cut at 50 μ on a Gillings-Bronwill thin-sectioning, hardtissue saw, which had been modified by the addition of supplementary water jets for cooling the diamond blade and the tissue block. Sections were examined microscopically in glycerol; a selected area was punched out with a 1 mm diameter leather punch, and the resulting disk was cemented to a preformed blank casting adapted to the chuck of the ultramicrotome. Tissue specimens presenting surfaces of 1.5 × 3 cm can be surveyed rapidly with this method. The use of a punch to obtain the disks for ultramicrotomy leaves the rest of the section undamaged.     

Simultaneous determination of felbamate and four metabolites in rat cerebrospinal fluid by high-performance liquid chromatography

An isocratic liquid chromatographic method for direct sample injection has been developed for the quantitation of felbamate and four metabolites in rat cerebrospinal fluid. The method uses 0.050- or 0.025-ml aliquots of cerebrospinal fluid diluted with equal volumes of internal standard. Chromatography is performed on a 150 mm × 4.6 mm I.D. Spherisorb ODS2, 3-μm HPLC column eluted with a phosphate buffer—acetonitrile—methanol (820:120:60, v/v/v) mobile phase and ultraviolet absorbance detection at 210 nm. The linear quantitation ranges are: felbamate and the 2-hydroxy metabolite 0.195–200 μg/ml, the propionic acid metabolite 0.195–50.0 μg/ml, the p-hydroxy metabolite 0.781 to 50.0 μg/ml, and the monocarbamate metabolite 0.098–50.0 μg/ml.     

Estradiol inhibits the estrone sulfatase activity in normal and cancerous human breast tissues

It is well accepted that estradiol (E₂) plays an important role in the genesis and evolution of breast cancer. Quantitative evaluation indicates that in human breast tumor, estrone sulfate (E₁S) ‘via sulfatase’ is a much more likely precursor for E₂ than is androstenedione ‘via aromatase’. In previous studies, it was demonstrated that in isolated MCF-7 and T-47D breast cancer cell lines, estradiol can block estrone sulfatase activity. In the present study, the effect of E₂ was explored using total normal and cancerous breast tissues. This study was carried out with post-menopausal patients with breast cancer. None of the patients had a history of endocrine, metabolic or hepatic diseases or had received treatment in the previous 2 months. Each patient received local anaesthetic (lidocaine 1%) and two regions of the mammary tissue were selected: (A) the tumoral tissue and (B) the distant zone (glandular tissue) which was considered as normal. Samples were placed in liquid nitrogen and stored at –80 °C until enzyme activity analysis. Breast cancer histotypes were ductal and post-menopausal stages were T2. Homogenates of tumoral or normal breast tissues (45–75 mg) were incubated in 20 mM Tris–HCl, pH 7.2 with physiological concentrations of [³H]-E₁S (5 × 10⁻⁹ M) alone or in the presence of E₂ (5 × 10⁻⁵ to 5 × 10⁻⁷ M) during 30 min or 3 h. E₁S, E₁ and E₂ were characterized by thin layer chromatography and quantified using the corresponding standard. The sulfatase activity is significantly more intense with the breast cancer tissue than normal tissue, since the concentration of E₁ was 3.20 ± 0.15 and 0.42 ± 0.07 pmol/mg protein, respectively after 30 min incubation. The values were 27.8 ± 1.8 and 3.5 ± 0.21 pmol/mg protein, respectively after 3 h incubation. Estradiol at the concentration of 5 × 10⁻⁷ M inhibits this conversion by 33% and 31% in cancerous and normal breast tissues, respectively and by 53% and 88% at the concentration of 5 × 10⁻⁵ M after 30 min incubation. The values were 24% and 18% for 5 × 10⁻⁷ M and 49% and 42% for 5 × 10⁻⁵ M, respectively after 3 h incubation. It was observed that [³H]-E₁S is only converted to [³H]-E₁ and not to [³H]-E₂ in normal or cancerous breast tissues, which suggests a low or no 17β-hydroxysteroid dehydrogenase (17β-HSD) Type 1 reductive activity in these experimental conditions. In conclusion, estradiol is a strong anti-sulfatase agent in cancerous and normal breast tissues. This data can open attractive perspectives in clinical trials using this hormone.     

Extraction of [14CI Vitamin a from Rat Liver and Kidney During Processing for Transmission Electron Microscopy

The retention of radio isotope-labekd vitamin A during processing for electron microscopy was investigated using the livers and kidneys of vitamin A deficient rats. [15-¹⁴C]Retinol (3μCi/animal) was administered by esophageal intubation to male rats which had been maintained on a vitamin A deficient diet for five or sir weeks postweaning. Glutaraldehyde- or osmium-fixed tissue was processed by three methods: a) routine (a graded series of ethanols, propylene oxide and epoxy), b) rapid (75% and 95% ethanol with three changes of epoxy), or c) water-soluble embedding (70% and 80% hydrorypropyl methacrylate). Water-soluble embedding retained the highest percentage of label in the tissue (liver: 96.31%; kidney: 98.68%). Inclusion of osmium tetroxide in the processing sequence and minimal exposure of tissue to lipid solvents were necessary for good retention of labeled vitamin A in tissues.

The opinions or assertions contained herein are the private views of the author and are not to be construed as official or as reflecting the views of the Department of the Army or the Department of Defense.

In conducting the research described in this report, the investigators adhered to the “Guide for Laboratory Animal Facilities and Care,” as promulgated by the Committee on the Guide for Laboratory Animal Resources, National Academy of Sciences—National Research Council.     

Orcein-Hematoxylin in Iodized Ferric Chloride as a Stain for Elastic Fibers, With Metanil Yellow Counterstaining

Autopsy and biopsy specimens of human skin were fixed overnight in alcoholic Bouin's solution, embedded in paraffin, cut at 7 μ, deparaffinized, hydrated to 70% alcohol, and treated as follows—stained 2 hours in a mixture consisting of: 0.2% orcein in 70% alcohol and 1% HC1 (conc.), 125 ml; 5% hematoxylin in absolute alcohol, 40 ml; 6% FeCl₃ in water, 25 ml; and aqueous I₂-KI (1:2:100), 25 ml—rinsed in distilled water until the excess stain was removed—differentiated in 1.2% FeCl₃, 5-15 sec—washed in running water, 5 min—differentiation completed in 0.01% HC1 acid-alcohol, 1 min—a dip in 95% alcohol—distilled water, 2 min—0.25% aqueous metanil yellow, 5-10 sec—a 95% alcohol dip—dehydrated in absolute alcohol, xylene, and mounted in a resinous medium. The technic combines the orcein of Pinkus' stain and the hematoxylin mixture of Verhoeff into a single staining solution and gives sharp and reliable results for both coarse and extremely delicate elastic fibers. These stain purple; nuclei, violet; and background, yellow. The stain allows the use of formalin, Bouin's fluid and Zenker-formol fixation. The results have been consistent in other primates as well as in man.     

Rearrangement of concanavalin A receptor sites on cells tagged with dinitrofluorobenzene: Evidence for the chemical induction of a change usually associated with malignant transformation

Normal human peripheral blood granulocytes which are tagged with 1-fluoro-2,4-dinitrobenzene (DNFB) are agglutinated by concanavalin A (ConA) in a way which resembles the pattern of reactivity displayed by leukemic cells. The present study further defines this reaction. The binding of ConA to untagged and DNP-tagged granulocytes, treated with DNFB at a ratio of 10¹¹ molecules/cell, was quantified by isotopic dilution experiments employing [³H]ConA. Similar amounts of the lectin were bound to untagged and DNP-tagged cells following incubation for 5 min at 4 °C or 30 min at 24 °C: 1.1 × 10⁵ molecules/cell, 4.6 × 10²/μ² of surface area, and 1.6 × 10³/μg of protein. The binding of [³H]ConA to both untagged and DNP-tagged cells was inhibited to the same degree by α-methylglucopyranoside (α-MG). Fixation with either glutaraldehyde or formaldehyde, which immobilizes ConA receptor sites, completely inhibited the agglutination of both untagged and DNP-tagged cells although lectin binding was unchanged. This suggests that the inhibition of agglutination was not due to the blocking of ConA-binding sites by aldehyde groups but rather to the immobilization of lectin receptors. We conclude that dinitrophenylation of normal granulocytes facilitates the rearrangement of lectin receptors in a way which resembles the ConA-induced clustering of sites which have been observed with malignant and transformed cells.     

Action of endogenous steroid inhibitors of brain aromatase relative to fadrozole

To study mechanisms of aromatase inhibition in brain cells, a highly effective non-steroidal aromatase inhibitor (Fadrozole; 4-[5,6,7,8-tetra-hydroimidazo-(1,5-a)-pyridin-5-yl] benzonitrile HCl; CGS 16949A) was compared with endogenous C-19 steroids, known to be formed in the preoptic area, which inhibit oestrogen formation. Using a sensitive in vitro tritiated water assay for aromatase activity in avian (dove) preoptic tissue, the order of potency, with testosterone as substrate was: Fadrozole (K_i < 1 × 10⁻⁹ M) > 4-androstenedione 5-androstanedione > 5-dihydrotestosterone (K_i = 6 × 10⁻⁸ M) > 5β-androstanedione > 5β-dihydrotestosterone (K_i = 3.5 × 10⁻⁷ M) > 5-androstane-3, 17β-diol (K_i = 5 × 10⁻⁶ M) > 5β-androstane-3β,17β-diol. Five other steroids, 5β-androstane-3,17β-diol, 5-androstane-3β,17β-diol, progesterone, oestradiol and oestrone, showed no inhibition at 10⁻⁴ M. The kinetics indicate that endogenous C-19 steroids show similar competitive inhibition of the aromatase as Fadrozole. Mouse (BALB/c) preoptic aromatase was also inhibited by Fadrozole. We conclude that endogenous C-19 metabolites of testosterone are effective inhibitors of the brain aromatase, and suggest that they bind competitively at the same active site as Fadrozole.     

Immunofluorescence Microscopy of Cyanurated Tissues

Test tissues consisted of: (1) popliteal lymph nodes of rabbits, removed 6 hr after injection of hind footpads with 0.2 ml of 125 mg/ml solution of 5× crystallized chicken ovalbumin, and (2) lungs from guinea pigs, passively sensitized with rabbit antiovalbumin serum, then anaphylactically shocked by intracardial injection of a 1% chicken ovalbumin solution. Similar control tissues from normal rabbits, and lungs of passively sensitized guinea pigs, but shocked with histamine instead of ovalbumin, were included. Pieces of fresh tissue not exceeding 2 mm³ were fixed as follows: (1) Cyanuration—lymph nodes, 1 hr; lung, 0.5 hr; both at 23-27 C—in anhydrous methanol containing 0.5% w/v cyanuric chloride and 1% v/v N, N-diethylaminoethanol. (2) Control fixatives—all specimens 18-24 hr at 4—6 C—absolute methanol; 95% ethanol; neutral buffered 10% formalin; and an FAA mixture (formalin, conc., 6; glacial acetic acid, 2; 30% ethanol, 92). Freeze-dried material was either left unfixed (a control) or fixed in xylene or toluene containing 0.5% w/'v cyanuric chloride and 1% v/v N, N-diisopropylaminoethanol; time and temperature as for fresh tissues. All tissues were routinely dehydrated, cleared, and vacuum embedded in an ester wax, diethylene glycol distearate, or in paraffin at 52 C. Sections 2-4 μ thick were attached to gelatin-coated slides, the wax removed in petroleum ether, and stained 20 min at 23-27 C in a 0.10% solution of fluorescein isothiocyanate-conjugated rabbit antiovalbumin globulin, washed in phosphate buffered saline 10 min, dehydrated, cleared and covered in a nonfluorescent medium. With ultraviolet illumination, brightly immunofluorescent, anti-genically specific staining was obtained in cyanurated fresh and freeze-dried lymph node and lung tissues. In contrast, specific staining was diminished or absent in comparable tissues reacted in the control fixatives.     

Direct Epoxy Embedding for Vertical Sectioning of Cells Grown as a Monolayer on Millipore Filter

Cells cultured as a monolayer on MF-Millpore GSWP. 0.22 μ pore size, filter were fixed, dehydrated, and examined by phase-contrast microscopy with the filter immersed in a 1:1 mixture of xylene and the embedding medium. The membrane was cut into 2 × 20 mm strips, and each strip which was selected for desired cells was embedded vertically in a BEEM capsule. Thus direct embedding which allowed edgewise sectioning of cells was obtained without removing them from the culturing support.     

The Surface Staining of Embedded Tissues

The staining procedure is based on the theory that the freshly cut surface of embedded material will absorb stain only in the exposed tissue elements, provided that the embedding compound itself will not absorb the staining fluid. Concentrated stains are used for short intervals to insure minimum penetration. For paraffin embedded materials: (1) Cut block, preferably on microtome, to the desired tissue surface. (2) Rinse in absolute alcohol. (3) Float face down in stain. (Ripe, concentrated alum hematoxylin—Galigher's formula recommended—will stain in 10 to IS minutes. Heidenhain's iron hematoxylin works exceptionally well in some cases.) Mordant 20% alum 5 to 10 minutes, briefly rinse, and stain comparable 5 to 10 minutes in 1 to 1.5% hematoxylin. (4) Allow to become blue in tap water (for hematoxylin stains). (5) Counter-stain if desired. (6) Dehydrate in absolute alcohol for not more than 10 minutes. (7) Dry for 15 to 20 minutes. (8) Trim block to 2-3 mm. and mount between two cover glasses by use of microflame. Attach mount to slide with balsam. For celloidin embedded materials: (1) Dehydrate block with 90% alcohol, phenol-toluene, finally pure toluene. (2) Rinse cut surface with 90% alcohol, then apply stain. (3) Wash, after hematoxylin stains, counterstain if desired. (4) Dehydrate surface, 90% alcohol, phenol toluene, pure toluene, and mount in medium dissolved in toluene.

Possible applications of surface staining technic are suggested and illustrated.     

A Tribasic Stain for Thin Sections of Plastic-Embedded, OsO4-Fixed Tissues

Thin (0.5-1 μ) sections of plastic-embedded, OsO₄-fixed tissues were attached to glass slides by heating to 70 C for 1 min. A saturated solution combining toluidine blue and malachite green was prepared in ethanol (8% of each dye) or water (4% of each dye). Methacrylate or epoxy sections were stained in the ethanol solution for 2-5 min. The water solution was more effective for some epoxy sections (10-80 min). Epoxy sections could be mordanted by 2% KMnO₄, in acetone (1 min) before use of the aqueous dye, reducing staining time to 5-10 min and improving contrast. Aqueous basic fuchsin (4%) was used as the counter-stain in all cases; staining time varied from 1-30 min depending upon the embedding medium and desired effects, methacrylate sections requiring the least time. In the completed stain, nuclei were blue to violet; erythrocytes and mitochondria, green; collagen and elastic tissue, magenta; and much and cartilage, bright cherry red. Sections were coated with an acrylic resin spray and examined or photographed with an oil-immersion lens.     

Human fibroblast culture on a crosslinked dermal porcine collagen matrix

The use of a novel porcine-derived collagen biomaterial as a dermal tissue engineering matrix was examined. The matrix is derived from porcine dermis, and is processed to retain the native collagen (Type 1) and elastin structure. Human primary fibroblasts were cultured on the matrix to examine its potential for creating a dermal replacement. Attachment of fibroblasts on the collagen was compared to tissue culture plastic and PET membranes. Cell proliferation was assessed using the MTT assay and DAPI staining. For seeding densities of 5×10⁴ and 1×10⁵ cells cm⁻², PET and plastic demonstrated >95% attachment of seeded numbers after 3 h. The collagen matrix reached levels >80% after 3–4 h with no influence of the seeding density. Matrix samples with perforating pores of 40 μm diameter were also studied. After 216 h culture in static culture, with media replacement every 3 days, the final cell numbers reached 2.1×10⁵ (perforated) and 2.0×10⁵ cells cm⁻² (unperforated). In comparison fibroblast culture in a perfusion bioreactor, with continuous media replacement, reached 2.3×10⁵ (unperforated) and 2.5×10⁵ cells cm⁻² (perforated) after 216 h.     

The Use of Ba(OH)2 in Methanol for Demonstration of the Distribution of Sucrose in Sugarbeet Roots

Sucrose in the tissues of the sugarbeet (Beta vulgaris L.) can be shown as follows. Fresh or stored roots are cut into pieces having a block face of about 1 × 2 cm, and sections of about 150 μ thickness prepared from these. The sections are rinsed 15-30 sec in iced distilled water, placed in Ba(OH)₂-saturated methanol for 3 min and then rinsed twice in methanol for 1 and 5 min respectively. They are then transferred to ethanol through a graded series consisting of 80, 60, 40, and 20% methanol in ethanol, 5 min in each, with evacuation as necessary to remove bubbles. Temporary mounting is in ethanol and examination made by incident light or darkfield illumination. Gradual replacement of ethanol with xylene permits mounting in a resinous medium. An opaque granular precipitate of barium saccharate shows the location of the sucrose within the cells.     

A performance comparison of choline biosensors: anodic or cathodic detections of H2O2 generated by enzyme immobilized on a conducting polymer

Amperometric choline biosensors were fabricated by the covalent immobilization of an enzyme of choline oxidase (ChO) and a bi-enzyme of ChO/horseradish peroxidase (ChO/HRP) onto poly-5,2′:5′,2″-terthiophene-3′-carboxylic acid (poly-TTCA) modified electrodes (CPMEs). A sensor modified with ChO utilized the oxidation process of enzymatically generated H₂O₂ in a choline solution at +0.6 V. The other one modified with ChO/HRP utilized the reduction process of H₂O₂ in a choline solution at −0.2 V. Experimental parameters affecting the sensitivity of sensors, such as pH, applied potential, and temperature were optimized. A performance comparison of two sensors showed that one based on ChO/HRP/CPME had a linear range from 1.0×10⁻⁶ to 8.0×10⁻⁵ M and the other based on ChO/CPME from 1.0×10⁻⁶ to 5.0×10⁻⁵ M. The detection limits for choline employing ChO/HRP/CPME and ChO/CPME were determined to be about 1.0×10⁻⁷ and 4.0×10⁻⁷ M, respectively. The response time of sensors was less than 5 s. Sensors showed good selectivity to interfering species. The long-term storage stability of the sensor based on ChO/HRP/CPME was longer than that based on ChO/CPME.