Iranian Journal of

Background and Objective: Clinics, laboratories and health care centers are considered as one of the main waste generating sources in solid waste management. The problems associated with the generated health-care waste in clinics, laboratories and health care centers have been rarely investigated in Iran. Therefore, the present study was developed to investigate the status of health care waste in clinics, laboratories and health care centers of Mahmoudabad, Mazandaran in 2017.
Methods and Materials: This cross-sectional study was conducted to determine the status of solid waste management in 117 medical centers in Mahmoudabad, Mazandaran, 2017. The solid waste data in terms of waste generation rate, storage, collection, and disposal were surveyed through interview and questionnaire that were validated by Iran’s ministry of health.
Results: The average health-care waste generation in medical centers in Mahmoudabad was found to be 248 g/day. The mean and standard deviation for environmental health criteria in all medical centers were 248.3 and 41.1, respectively. In addition, there was a statistically significant difference between the amount of waste generation in private and governmental medical centers (p=0.111).
Conclusion: The results obtained from the present research indicated that the medical waste management in Mahmoudabad, particularly in private centers, face serious problems. Improper waste collection technology, mixing municipal and medical waste, requirement for training the personnel in medical waste management and surveillance can be considered as important concerns in health-care waste management in Mahmoudabad.
 

Background and Objective: Scaling and corrosion both are destructive to materials (usually metals) in water supply systems. A dataset (from 2002 to 2013) of groundwater resources (including springs, qanats, deep wells and semi-deep wells) were examined for water tendency to corrosion or scaling in rural regions of Kashan, a city in Isfahan, central Iran.
Materials and Methods: Water quality parameters including pH, temperature, Ca (mg/L), CO₃^2- (mg/L), HCO₃^-(mg/L) and TDS (mg/L) were used to estimate water stability indices. Value of qualitative indices including Langelier (LSI), Ryznar (RSI), Puckorius (PSI) and trend of Calcium Carbonate Precipitation Potential (CCPP) as a quantitative index were calculated and analyzed for all water resources.
Results: Mean of LSI, RSI and PSI for all water resources were estimated to be 0.41±0.02, 6.39 ± 0.03, and 7.40±0.02, respectively. The CCPP value found to be 17.23±3.16, 15.66±1.38, 41.23±11.22, and 23.15±4.46 mg/L for springs, qanats, deep wells and semi-deep wells, respectively. The CCPP index was significantly increased from 2002 to 2013, with an average of 1.6 units per year.
Conclusion: A significant scaling tendency was observed. This tendency in decreasing order was observed in deep wells, semi-deep wells, springs and qanats. The estimated CaCO₃ scale weight per cubic meter of water was 21 g on average, which may be problematic for water distribution systems. Water withdrawal management and reduction in TDS of water resources, perhaps through decrease in agricultural drainage, can be effective to reduce the scaling tendency.   
 

Background and Objective: Hospital wastes with the content of infectious, pathologic, sharp, pharmaceupitical and genotoxic materials are classified as hazardous wastes. Of which, genotoxic residues wirh mutagenic and teratogenic effects are of most great concern on human health. Genetic wastes are referred to as cytotoxic, chemical, and radioactive drugs used to treat cancer or treat transplantation. The purpose of this study was to evaluate the management of hospital wastes in Mazandaran province with emphasis on genotoxic waste.
Materials and Methods: This descriptive cross-sectional study was carried out in 35 governmental and social hospitals in Mazandaran province to determine the satus of hospital waste with focus on geotoxic waste. The quanity, quality and management approaches of hospital and genotoxic wastes in the studied hospitals were surveyed with a validated questionnaire. Results obtained from the present study were analyzed with Excel software.
Results: The average waste per each hospital bed was estimated to be 3.51 kilograms. Of which, 2.2, 1.24, 1.9 kg were categorized as municipal, chemical, and genotoxic wastes, respectively. The average of the hospital waste management index in Mazandaran province was found to be about 84 out of 100, indicating good management of these wastes. The management of genotoxic waste in 7 specialized chemotherapy hospitals was estimated to be 64 out of 100, indicating the average state of genotoxic waste management for these hospitals. In 28 non-chemotherapy hospitals, the genotoxic waste management index was approximated 42 out of 100, indicating poor management of these wastes.
Conclusion: The main weaknesses in hospital waste management are associated with the management of chemical-pharmaceutical and genotoxic wastes. Accordingly, improvement the quality of genotoxic and chemical-pharmaceutical wastes should be concerned in the future planning.
 

Background and Objective: The purpose of this study is to identify and comprehensively evaluate international studies related to bioaugmentation and biostimulation methods for the remediation of soils contaminated with petroleum compounds.
Materials and Methods: This systematic review study was conducted in April 2022. The present systematic review study was conducted to address two main questions: 1) Is biostimulation an effective process in the bioremediation of soils contaminated with petroleum hydrocarbons; and 2) Is bioaugmentation an effective process for bioremediation of soils contaminated with petroleum hydrocarbons? Global electronic databases (PubMed, Web of Science, and Scopus) were used to identify relevant studies. After a comprehensive review of studies, 123 studies consistent with the purpose were selected.
Results: The results showed that biostimulation methods can have profound changes in bacterial, Archaebacteria, and soil fungal communities in terms of activity, frequency, and composition. In general, the nutrients and electron receptors added in the biostimulation process improve soil microbial activity, increasing the overall abundance of bacteria, and fungi and promoting selective replication of bacterial, archival, and fungal polyaromatic hydrocarbons (PHC) destroyers. The use of bioaugmentation technology in an environment contaminated with petroleum hydrocarbons has a positive effect on the refining process. However, it is necessary to precisely select the appropriate microbial strains. The most important factor in the removal of hydrocarbons in the soil is the selection of oil-decomposing microorganisms that can survive in high concentrations of pollutants.
Conclusion: Therefore, the result indicated that biostimulation and bioaugmentation can efficiently improve the THP removal efficiency in contaminated soil by considering the environmental conditions.