园林植物嗅景对人体健康的影响

doi:10.11707/j.1001-7488.LYKX20220246

摘要/Abstract

摘要：

目的: 探究园林植物嗅景即植物气味及其引发的园林环境多维度交互感知对人体健康的影响，并深入分析园林植物相关的嗅觉、视觉及嗅视觉交互刺激对人体生理与心理反应的影响差异，为园林植物嗅景设计提供理论依据和新思路。方法: 采用同期随机对照的研究设计，以西北地区常见四类园林植物气味及其对应园景的全景影像为刺激材料，以312名大学生为研究对象，在虚拟仿真实验室内用NeuroSky脑波测试仪、OMRON上臂式电子血压计以及VISHEEW多参数生物反馈仪测定生理指标，采用状态焦虑量表以及嗅景情绪量表评估由嗅景引发的情绪以及对整体环境的感知程度。对于生理指标数据，采用单因素方差分析筛选出具显著差异的指标后，通过Spearman相关性分析检验各试验刺激因素与这些指标之间的相关性，进而运用多元线性回归方法分析各指标与不同刺激因素之间的关系，最后针对筛选出的指标数据两两比对进行单因素方差分析和LSD事后检验。心理指标中，对状态焦虑量表数据进行方差分析和LSD事后检验，针对嗅景情绪量表中各组形容词选项的平均分数据进行Wilcoxon秩和检验。结果: 生理测量结果显示1）在嗅觉刺激组中，青草、油松和月季组在刺激前后的α、β脑波振幅以及皮电（SC）均呈下降趋势，其中嗅闻松树气味使得α、β脑波振幅下降最大（松树气味组Δα =?24%，Δβ=?19.8%），而嗅闻月季气味后皮电值降幅最大（月季气味组ΔSC=?13.3%）。2）大多数试验组的视觉刺激引发α、β脑波振幅以及皮电显著升高，其中观赏月季景象使得α脑波振幅上升最大（月季视景组Δα=76.3%），观赏桂花景象使β脑波振幅和皮电均上升最大（桂花视景组Δβ=92.7%，ΔSC=90.8%）。3）月季和桂花的嗅视交互刺激引发α、β脑波振幅均显著升高，4种植物景观的嗅视交互刺激引发皮电均显著升高，其中边闻边看月季使α、β脑波振幅上升最大（月季嗅视组Δα=29.7%，Δβ=39.6%），边闻边看桂花使皮电升幅最高（桂花嗅视组ΔSC=22.6%）。心理测量结果显示，嗅视交互比单一嗅觉刺激更易增强受访者对环境的正向心理感知，如“吸引力”、“独特感”和“协调感”。结论: 与园林植物嗅景相关的嗅视交互作用可使人在一定程度上得到生理和心理的放松。嗅视交互刺激在中枢神经系统活动中表现出折中效应，在自主神经系统活动中表现出累加效应，并可普遍增强人们对环境的正向心理感知。未来园林植物嗅景设计应从多维度感知交互视角出发，充分发挥其健康效应。

关键词: 园林植物, 嗅景, 嗅视觉交互刺激, 中枢神经系统, 自主神经系统, 心理效应

Abstract:

Objective: This paper aims to explore the effects of garden plant smellscape which is odor and the multi-dimensional interactive perception of garden environment caused by smell on human health, by deeply analyzing the difference of effects of olfactory, visual and olfactory-visual interactive stimulation related to garden plants on human physiological and psychological responses, so as to provide theoretical basis and new ideas for garden plant smellscape design. Method: In a randomized controlled study, the odor of four common garden plants in northwest China and the panoramic images of their corresponding landscape were used as stimulus materials, and 312 college students were selected to be subjected the stimuli. NeuroSky brainwave tester, OMRON upper arm electronic sphygmomanometer and VISHEEW multiparameter biofeedback instrument were used to measure physiological indicators of the students in the virtual simulation laboratory. The emotions induced by smellscape and the perception of the overall environment were evaluated by state anxiety scale (S-AI) and smellscape emotion scale (SD). For physiological index data, One-way ANOVA was used to screen out indicators with significant differences. Spearman correlation analysis was used to test the correlation between each experimental stimulus factor and these indicators, and then multiple linear regression method was used to analyze the relationship between each indicator and different stimulus factors. Finally, one-way ANOVA and LSD postmortem test were conducted for the screened index data. For psychological indicators, ANOVA and LSD postmortem test were performed on the S-AI scale data, and Wilcoxon rank sum test was performed on the mean score data of each adjective option in SD. Result: The results of physiological measurement showed that: 1) In the olfactory stimulation group, before and after stimulation, the amplitude of α, β brainwave and skin electroencephalogram (SC) decreased significantly in the grass, Pinus tabuliformis and Rosa chinensis groups, and the amplitude of α and β brainwave decreased the most in the pine scent group (Δα=?24%, Δβ=?19.8%). The SC value decreased the most after smellingR. chinensis (ΔSC=?13.3%). 2) The amplitude of α, β brainwave and SC were significantly increased by visual stimulation in most experimental groups. The amplitude of α brainwave was increased the most by viewingR. chinensis (Δα=76.3%), and the amplitude of β brainwave and SC were increased the most by viewing Osmanthus fragrans (Δβ=92.7%, ΔSC=90.8%). 3) The amplitude of α and β brainwave induced by olfactory and visual interaction increased significantly in R. chinensis and O. fragrans, and SC induced by olfactory and visual interaction increased significantly in the 4 plant smellscape. The amplitude of α and β brainwave increased the most in R. chinensis olfactory and visual interaction group (Δα=29.7%, Δβ=39.6%). O. fragrans olfactory and visual interaction group (ΔSC=22.6%) had the highest increase in SC. The results of psychological measurement showed that olfactory-visual interaction was more likely to enhance participants' positive psychological perception of the environment, such as ‘attraction’, ‘uniqueness’ and ‘coordination’, than olfactory stimuli alone. Conclusion: The olfactory and visual interaction associated with garden plant smellscape can make people relax physically and psychologically to a certain extent. Olfactory and visual interaction shows a compromise effect in central nervous system and an accumulative effect in autonomic nervous system, and can generally enhance people's positive psychological perception of the environment. In the future, garden plant smellscape design should start from the perspective of multi-dimensional perception interaction and give full play to its health effect.

Key words: garden plant, smellscape, olfactory and visual interactive stimulus, central nervous system, autonomic nervous system, psychological effect

中图分类号:

S731.2

张新果,张启翔. 园林植物嗅景对人体健康的影响[J]. 林业科学, 2023, 59(4): 100-116.

Xinguo Zhang,Qixiang Zhang. Effects of Garden Plants Smellscape on Human Health[J]. Scientia Silvae Sinicae, 2023, 59(4): 100-116.

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生理指标 Physiological index	ΔSBP	ΔDBP	ΔP	ΔSC	Δα波 Δα brainwaves	Δβ波 Δβ brainwaves
相关系数 Correlation coefficient	0.037	0.032	?0.007	0.349^**	0.290^**	0.349^**
双侧检验显著性 Significance of two-side test	0.520	0.573	0.898	<0.001	<0.001	<0.001
样本数 Sample size	311	311	311	303	305	306

生理指标 Physiological index	ΔSBP	ΔDBP	ΔP	ΔSC	Δα波 Δα brainwaves	Δβ波 Δβ brainwaves
相关系数 Correlation coefficient	0.103	0.143^*	?0.114^*	0.288^**	0.297^**	0.286^**
双侧检验显著性 Significance of two-side test	0.070	0.012	0.045	<0.001	<0.001	<0.001
样本数 Sample size	311	311	311	303	305	306

因变量 dependent variable	系数Coefficient
因变量 dependent variable	R	R²	调整后的R² Adjusted R²
ΔSC	0.353a	0.125	0.119
Δα	0.303a	0.092	0.086
Δβ	0.327a	0.107	0.101

因变量 Dependent variable	项目 Item	非标准化系数 Unstandardized Coefficient	标准系数 Standardized Coefficient	t	显著性 Significance
因变量 Dependent variable	项目 Item	B	β	t	显著性 Significance
ΔSC	(常量Constant)	?0.206	—	?5.940	<0.001
	刺激方式 Stimulating pattern	0.073	0.275	4.831	<0.001
	植物气味 Plant smell	0.031	0.152	2.666	0.008
Δα	(常量Constant)	?0.242	—	?3.216	0.001
	刺激方式 Stimulating pattern	0.092	0.162	2.799	0.005
	植物气味 Plant smell	0.091	0.211	3.664	<0.001
Δβ	(常量constant)	?0.237	—	?3.040	0.003
	刺激方式 Stimulating pattern	0.124	0.210	3.685	<0.001
	植物气味 Plant smell	0.087	0.194	3.400	0.001

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