Characterization and valorization of biomass char: a comparison with biomass ash

Organic matter derived from living, or recently living plant and animal, which can be used as fuel is called as biomass. It includes wood and agricultural waste such as dead plant etc. In India, majority of population depends largely upon agriculture as their primary source of income. Following every harvest, a huge amount of biomass is generated. It is mostly discarded as "agro waste"; however, recently, several uses of biomass and its derivatives have been reported. Thermochemical processing of biomass in absence of oxygen produces biomass char and flue gases which are of economic importance. However, it is necessary to characterize the physical and chemical properties of these components so as to utilize their potential benefit to the fullest. In this study, six different biomass remains that include mustard plant, groundnut plant, cotton plant, wheat plant, pigeon peas, and groundnut shell were pyrolyzed at 650 °C, in vertical downdraft fixed-bed biomass reactor. The flue gases were characterized in detail by gas chromatography. X-ray fluorescence, proximate, and ultimate analyses were performed on all BMC (biomass char) samples, and properties such as porosity, particle density, bulk density, point of zero charge, surface pH, surface charges, water-absorption capacity, and BET surface area were determined. SEM and FTIR were also carried out on all BMC samples. Our results showed that the surface area of biomass char varies from 38 to 138 m²/g. The solution pH for all BMC exceeds 8.6, thus confirmed the alkaline nature. Comparison between combustion products produced in the presence (biomass ash) and absence of oxygen (biomass char) is presented. BMC finds applications in agriculture, soil neutralizer, adsorbent, and soil additive. They have high amount of carbon and can act as a rich carbon source for the soil. Flue gases released contain methane and hydrogen which can also improve economic value for the char formation process.

Characterization and valorization of biomass ashes

In India, farming is the primary source of income for many families. Following each harvest, a huge amount of biomass is generated. These are generally discarded as "agrowaste," but recent reports have indicated several beneficial uses for these biomasses and their ashes. However, before the utilization of biomass ashes (BMAs), their chemical and physical properties need to be investigated (characterized) so as to utilize their potential benefit to the fullest. In this paper, eight different biomass ashes (soybean plant ash, mustard plant ash, maize ash, groundnut plant ash, cotton plant ash, wheat plant ash, pigeon peas ash, and groundnut shell ash) were characterized, and their chemical properties are discussed. Surface chemical composition analysis, proximate analysis, and ultimate analysis were performed on all BMA samples, and properties such as porosity, particle density, bulk density, point of zero charge, BET surface area, water-absorption capacity, and bulk parameters such as surface pH and surface charges were determined. BMAs were characterized by SEM and FTIR. The surface areas of biomass ashes vary from 1.9 to 46 m²/g, and point of zero charge for all BMAs exceed 9.8, which confirmed the alkaline nature of these samples. Based on the chemical composition, BMAs are categorized into four types (S, C, K, and CK), and their utilization is proposed based on the type. BMAs find applications in agriculture and construction industries; glass, rubber, and zeolite manufacturing; and in adsorption (as a source of silica/zeolites). The paper also discusses the research challenges and opportunities in utilization of BMAs.

Mustard plant ash: a source of micronutrient and an adsorbent for removal of 2,4-dichlorophenoxyacetic acid

The work highlights the utilization of an agricultural waste mustard plant ash (MPA) as a soil additive and an adsorbent. MPA was characterized by X-ray fluorescence (XRF), energy-dispersive X-ray spectroscopy (EDX), proximate analysis, CHNS analysis, Brunauer-Emmett-Teller (BET) surface area analysis, zeta potential measurements, Fourier transform infrared (FTIR), scanning electron microscopy (SEM), and transmission electron microscopy (TEM). XRF analysis confirmed the presence of CaO (31.35 %), K₂O (18.55 %), and P₂O₅ (6.99 %), all of which act as micronutrients to plants. EDX also confirms high amount of elemental O, Ca, K, and P. The adsorptive ability of MPA was investigated using a commonly used herbicide, 2,4-dichlorophenoxyacetic acid (2,4-D), as a representative chemical. Batch adsorption experiments were conducted to study the effect of different operational parameters such as adsorbent dose, initial 2,4-D concentration, contact time, and temperature on the adsorption process. Data from experiments were fitted to various kinetic and isothermal models. The pseudo-second-order kinetic model was found to show the best fit (R ² > 0.99), with the highest k ₂ value of the order 10⁵. Based on the study results, dosage of MPA/hectare for different crops has been recommended for effective removal of 2,4-D. To our knowledge, this is the first study in which MPA has been characterized in detail and investigated for dual applications (as an adsorbent and as a soil additive).

Quantitative analysis of Pc 4 localization in mouse lymphoma (LY-R) cells via double-label confocal fluorescence microscopy

Photodynamic therapy (PDT) is a novel cancer therapy that uses light-activated drugs (photosensitizers) to destroy tumor tissue. Reactive oxygen species produced during PDT are thought to cause the destruction of tumor tissue. However, the precise mechanism of PDT is not completely understood. To provide insight into the in vitro mechanisms of PDT, we studied the subcellular localization of the photosensitizer HOSiPcOSi(CH3)2-(CH2)3N(CH3)2 (Pc 4) in mouse lymphoma (LY-R) cells using double-label confocal fluorescence microscopy. This technique allowed us to observe the relative distributions of Pc 4 and an organelle-specific dye within the same cell via two, spectrally distinct, fluorescence images. To quantify the localization of Pc 4 within different organelles, linear correlation coefficients from the fluorescence data of Pc 4 and the organelle-specific dyes were calculated. Using this measurement, the subcellular spatial distributions of Pc 4 could be successfully monitored over an 18 h period. At early times (0-1 h) after introduction of Pc 4 to LY-R cells, the dye was found in the mitochondria, lysosomes and Golgi apparatus, as well as other cytoplasmic membranes, but not in the plasma membrane or the nucleus. Over the next 2 h, there was some loss of Pc 4 from the lysosomes as shown by the correlation coefficients. After an additional incubation period of 2 h Pc 4 slowly increased its accumulation in the lysosomes. The highest correlation coefficient (0.65) was for Pc 4 and BODIPY-FL C5 ceramide, which targets the Golgi apparatus, and also binds to other cytoplasmic membranes. The correlation coefficient was also high (0.60) for Pc 4 and a mitochondria-targeting dye (Mitotracker Green FM). Both of these correlation coefficients were higher than that for Pc 4 with the lysosome-targeting dye (Lysotracker Green DND-26). The results suggest that Pc 4 binds preferentially and strongly to mitochondria and Golgi complexes.

Effects of motion, ambient light, and hypoperfusion on pulse oximeter function

STUDY OBJECTIVE

To compare the performance of five pulse oximeters during hypoperfusion, probe motion, and exposure to ambient light interference.

DESIGN

Prospective study.

SETTING

Laboratory facility at a university medical center.

PATIENTS

8 unanesthetized, ASA physical status I volunteers.

INTERVENTIONS

We evaluated five common pulse oximeters with respect to three scenarios: (1) an operating room light was shone on oximeter probes, (2) a motion generator was used to generate 2 Hz and 4 Hz hand motion, and (3) a pneumatic compression device overlying the brachial artery was used to simulate hypoperfusion. Electrocardiographic (ECG) and arterial blood gas values were considered gold standards for heart rate (HR) and oxygen saturation (SpO2) respectively. SpO2 nondisplay and values greater than 4% from simultaneous arterial SaO2-oximeter values were defined as errors. Nondisplay of HR, or HR greater than 5% from ECG values, were also considered errors.

MEASUREMENTS AND MAIN RESULTS

The Ohmeda and Nellcor N200 with finger probe had the highest total failure rates with respect to both SpO2 and HR due to ambient light interference (p < 0.05). The Nellcor N200 with finger probe and N200 with C lock were the most accurate with regard to SpO2 during 2 Hz and 4 Hz motion (p < 0.05). However, all oximeters failed dramatically during 4 Hz motion when measuring HR. In the hypoperfusion model, the Nellcor N200 with finger probe and the Nellcor C Lock oximeters performed significantly better than all others in terms of both HR and SpO2 (P < 0.05), while the Criticare oximeter failed 100% of the time.

CONCLUSION

There are significant differences in the accuracy of commercially available pulse oximeters during nonideal circumstances, with failure rates varying from approximately 5% to 50% depending on the oximeter and source of interference. Furthermore, no single oximeter performed the best under all conditions.

Pulse oximeter performance during desaturation and resaturation: a comparison of seven models

STUDY OBJECTIVE

To compare pulse oximeter performance during induced hypoxemia.

DESIGN

Prospective investigation in human volunteers.

SETTING

Laboratory facility at a university medical center.

PATIENTS

8 unanesthetized, healthy ASA physical status I volunteers.

INTERVENTIONS

We evaluated the accuracy and response times of seven popular pulse oximeters during induced hypoxemia. Arterial blood fractional oxygen saturation (SaO2) measurements were performed simultaneously and considered a gold standard.

MEASUREMENTS AND MAIN RESULTS

All oximeters were accurate (+/-2%) while subjects were breathing room air. During maximal hypoxemia (induced by breathing a FIO2 = 10% in nitrogen), large differences were noted between oxygen saturation as measured by pulse oximetry (SpO2) and SaO2 values, with pulse oximeters consistently underreporting SpO2 when actual SaO2 values were 75% or less. The Ohmeda 3740 (Ohmeda, Boulder, CO) using an ear probe was the first to detect desaturation (change in SpO2 > 3%) in 4 of 8 subjects (p < 0.05), and the Nellcor N200 reflectance oximeter (Nellcor, Inc., Pleasanton, CA) was first in 3 of 8 subjects (p < 0.05). During resaturation (after administering 100% oxygen), the Novametrix Oxypleth (Novametrix, Wallingford, CT) was significantly faster than other oximeters (p < 0.05) to return to baseline (SpO2 = 98%).

CONCLUSION

Most models of oximeters tested performed well when hemoglobin oxygen saturation was high, but all were inaccurate when SaO2 was approximately 75%. During induced hypoxemia, there were significant differences in the response times of oximeters tested, with no model demonstrably superior to others in all measures of performance.

Headache prevention following accidental dural puncture in obstetric patients

STUDY OBJECTIVE

To evaluate the efficacy of a prophylactic saline patch and a prophylactic blood patch in prevention of headache following accidental dural puncture in obstetric patients.

DESIGN

Prospective, randomized, single-blind study on dural puncture headache occurrence and cessation.

SETTING

Inpatient obstetric unit at a metropolitan medical center.

PATIENTS

Seventy-four inpatients who underwent vaginal delivery or cesarean section following accidental dural puncture during administration of epidural anesthesia for labor and delivery.

INTERVENTIONS

Group 1 (n = 24), the control group, received fluids and analgesics. Group 2 (n = 30) received prophylactic epidural saline (40 to 60 ml) through the epidural catheter following completion of the obstetric procedure. Group 3 (n = 20) received autologous blood (15 ml) via epidural catheter following completion of the obstetric procedure.

MEASUREMENTS AND MAIN RESULTS

In Group 1, 21 of 24 patients (87.5%) developed headaches, with conservative management. In Group 2, 20 of 30 patients (66.7%) developed headaches, and in Group 3, 1 of 20 patients (5%) developed a headache.

CONCLUSIONS

The results of this study suggest that the administration of a prophylactic epidural blood patch is highly effective in the prevention of headaches following dural puncture, with headache frequency reduced from 87.5% to 5%.

Interpleural block: a new technique for regional anaesthesia during percutaneous nephrostomy and nephrolithotomy

Interpleural block was used in four patients undergoing percutaneous nephrostomy, one of whom also underwent percutaneous nephrolithotomy. Interpleural block was achieved with the standard technique using 30 ml of 0.5 per cent bupivacaine. All patients tolerated the procedure well and remained haemodynamically stable during the operative procedure. Mean pain relief from initiation of interpleural block was ten hours (SD = 4.32). Interpleural block was an effective method of obtaining anaesthesia for percutaneous nephrostomy and nephrolithotomy in these four patients.