Science and Technology Issues in the 115th Congress

Science and technology (S&T) have a pervasive influence over a wide range of issues confronting the nation. Public and private research and development spur scientific and technological advancement. Such advances can drive economic growth, help address national priorities, and improve health and quality of life. The constantly changing nature and ubiquity of science and technology frequently create public policy issues of congressional interest. The federal government supports scientific and technological advancement directly by funding and performing research and development and indirectly by creating and maintaining policies that encourage private sector efforts. Additionally, the federal government establishes and enforces regulatory frameworks governing many aspects of S&T activities. This report briefly outlines an array of science and technology policy issues that may come before the 115th Congress. Given the rapid pace of S&T advancement and its importance in many diverse public policy issues, S&T-related issues not discussed in this report may come before the 115th Congress. The selected issues are grouped into 9 categories: - Overarching S&T Policy Issues, - Agriculture, - Biomedical Research and Development, - Defense, - Energy, - Environment and Natural Resources, - Homeland Security, - Information Technology, - Physical and Material Sciences, and - Space. Each of these categories includes concise analysis of multiple policy issues. The material presented in this report should be viewed as illustrative rather than comprehensive. Each section identifies CRS reports, when available, and the appropriate CRS experts to contact for further information and analysis

Biosecurity and biodefense

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Bamboo reinforced concrete: a critical review

© 2018, The Author(s). The use of small diameter whole-culm (bars) and/or split bamboo (a.k.a. splints or round strips) has often been proposed as an alternative to relatively expensive reinforcing steel in reinforced concrete. The motivation for such replacement is typically cost—bamboo is readily available in many tropical and sub-tropical locations, whereas steel reinforcement is relatively more expensive—and more recently, the drive to find more sustainable alternatives in the construction industry. This review addresses such ‘bamboo-reinforced concrete’ and assesses its structural and environmental performance as an alternative to steel reinforced concrete. A prototype three bay portal frame, that would not be uncommon in regions of the world where bamboo-reinforced concrete may be considered, is used to illustrate bamboo reinforced concrete design and as a basis for a life cycle assessment of the same. The authors conclude that, although bamboo is a material with extraordinary mechanical properties, its use in bamboo-reinforced concrete is an ill-considered concept, having significant durability, strength and stiffness issues, and does not meet the environmentally friendly credentials often attributed to it

Flow-independent nitric oxide exchange parameters in healthy adults.

Currently accepted techniques utilize the plateau concentration of nitric oxide (NO) at a constant exhalation flow rate to characterize NO exchange, which cannot sufficiently distinguish airway and alveolar sources. Using nonlinear least squares regression and a two-compartment model, we recently described a new technique (Tsoukias et al. J Appl Physiol 91: 477-487, 2001), which utilizes a preexpiratory breath hold followed by a decreasing flow rate maneuver, to estimate three flow-independent NO parameters: maximum flux of NO from the airways (J(NO,max), pl/s), diffusing capacity of NO in the airways (D(NO,air), pl x s(-1) x ppb(-1)), and steady-state alveolar concentration (C(alv,ss), ppb). In healthy adults (n = 10), the optimal breath-hold time was 20 s, and the mean (95% intramaneuver, intrasubject, and intrapopulation confidence interval) J(NO,max), D(NO,air), and C(alv,ss) are 640 (26, 20, and 15%) pl/s, 4.2 (168, 87, and 37%) pl x s(-1) x ppb(-1), and 2.5 (81, 59, and 21%) ppb, respectively. J(NO,max) can be estimated with the greatest certainty, and the variability of all the parameters within the population of healthy adults is significant. There is no correlation between the flow-independent NO parameters and forced vital capacity or the ratio of forced expiratory volume in 1 s to forced vital capacity. With the use of these parameters, the two-compartment model can accurately predict experimentally measured plateau NO concentrations at a constant flow rate. We conclude that this new technique is simple to perform and can simultaneously characterize airway and alveolar NO exchange in healthy adults with the use of a single breathing maneuver

Flow-independent nitric oxide exchange parameters in healthy adults.

Currently accepted techniques utilize the plateau concentration of nitric oxide (NO) at a constant exhalation flow rate to characterize NO exchange, which cannot sufficiently distinguish airway and alveolar sources. Using nonlinear least squares regression and a two-compartment model, we recently described a new technique (Tsoukias et al. J Appl Physiol 91: 477-487, 2001), which utilizes a preexpiratory breath hold followed by a decreasing flow rate maneuver, to estimate three flow-independent NO parameters: maximum flux of NO from the airways (J(NO,max), pl/s), diffusing capacity of NO in the airways (D(NO,air), pl x s(-1) x ppb(-1)), and steady-state alveolar concentration (C(alv,ss), ppb). In healthy adults (n = 10), the optimal breath-hold time was 20 s, and the mean (95% intramaneuver, intrasubject, and intrapopulation confidence interval) J(NO,max), D(NO,air), and C(alv,ss) are 640 (26, 20, and 15%) pl/s, 4.2 (168, 87, and 37%) pl x s(-1) x ppb(-1), and 2.5 (81, 59, and 21%) ppb, respectively. J(NO,max) can be estimated with the greatest certainty, and the variability of all the parameters within the population of healthy adults is significant. There is no correlation between the flow-independent NO parameters and forced vital capacity or the ratio of forced expiratory volume in 1 s to forced vital capacity. With the use of these parameters, the two-compartment model can accurately predict experimentally measured plateau NO concentrations at a constant flow rate. We conclude that this new technique is simple to perform and can simultaneously characterize airway and alveolar NO exchange in healthy adults with the use of a single breathing maneuver

Fiscal Year 2017

This report begins with a discussion of the overall level of the President's FY2017 R&D request, followed by analyses of the R&D funding request from a variety of perspectives and for selected multiagency R&D initiatives. It concludes with discussion and analysis of the R&D budget requests of selected federal departments and agencies that, collectively, account for nearly 99% of total federal R&D funding

Flow-independent nitric oxide exchange parameters in cystic fibrosis.

Exhaled nitric oxide (NO) remains a promising noninvasive index for monitoring inflammatory lung diseases; however, the plateau concentration (C(NO,plat)) is nonspecific and requires a constant exhalation flow rate. We utilized a new technique that employs a variable flow rate to estimate key flow-independent parameters characteristic of NO exchange in a group (n = 9) of 10 to 14 yr-old healthy children and children with cystic fibrosis (CF): maximum flux of NO from the airways (J(NO,max'), pl s(-1)), diffusing capacity of NO in the airways (D(NO,air'), pl s(-1) ppb(-1)), steady-state alveolar concentration (C(alv,ss'), ppb), and mean tissue concentration of NO in the airways (C(tiss,air'), ppb). We determined the following mean (+/- SD) values in the healthy children and patients with CF for J(NO,max'), D(NO,air'), C(alv,ss'), and C(tiss,air'), respectively: 784 +/- 465 and 607 +/- 648 pl s(-1); 4.82 +/- 3.07 and 17.6 +/- 12.1 pl s(-1) ppb(-1); 4.63 +/- 3.59 and 1.96 +/- 1.18 ppb; and 198 +/- 131 and 38 +/- 25 ppb. D(NO,air) is elevated (p = 0.007), and both C(alv,ss) and C(tiss,air) are reduced (p = 0.05 and 0.002, respectively) in CF. In contrast, C(NO,plat) for healthy control subjects and patients with CF are not statistically different at both exhalation flow rates of 50 ml/s (17.5 +/- 11.5 and 11.5 +/- 8.97) and at 250 ml/s (7.11 +/- 5.36 and 4.28 +/- 3.43). We conclude that D(NO,air'), C(tiss,air'), and C(alv,ss) may be useful noninvasive markers of CF

Flow-independent nitric oxide exchange parameters in cystic fibrosis.

Exhaled nitric oxide (NO) remains a promising noninvasive index for monitoring inflammatory lung diseases; however, the plateau concentration (C(NO,plat)) is nonspecific and requires a constant exhalation flow rate. We utilized a new technique that employs a variable flow rate to estimate key flow-independent parameters characteristic of NO exchange in a group (n = 9) of 10 to 14 yr-old healthy children and children with cystic fibrosis (CF): maximum flux of NO from the airways (J(NO,max'), pl s(-1)), diffusing capacity of NO in the airways (D(NO,air'), pl s(-1) ppb(-1)), steady-state alveolar concentration (C(alv,ss'), ppb), and mean tissue concentration of NO in the airways (C(tiss,air'), ppb). We determined the following mean (+/- SD) values in the healthy children and patients with CF for J(NO,max'), D(NO,air'), C(alv,ss'), and C(tiss,air'), respectively: 784 +/- 465 and 607 +/- 648 pl s(-1); 4.82 +/- 3.07 and 17.6 +/- 12.1 pl s(-1) ppb(-1); 4.63 +/- 3.59 and 1.96 +/- 1.18 ppb; and 198 +/- 131 and 38 +/- 25 ppb. D(NO,air) is elevated (p = 0.007), and both C(alv,ss) and C(tiss,air) are reduced (p = 0.05 and 0.002, respectively) in CF. In contrast, C(NO,plat) for healthy control subjects and patients with CF are not statistically different at both exhalation flow rates of 50 ml/s (17.5 +/- 11.5 and 11.5 +/- 8.97) and at 250 ml/s (7.11 +/- 5.36 and 4.28 +/- 3.43). We conclude that D(NO,air'), C(tiss,air'), and C(alv,ss) may be useful noninvasive markers of CF